Ecology Basics
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MAGILL’S C H O I C E
Ecology Basics Volume 1 Acid deposition—Lic...
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Ecology Basics
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MAGILL’S C H O I C E
Ecology Basics Volume 1 Acid deposition—Lichens
edited by
The Editors of Salem Press
Salem Press, Inc. Pasadena, California Hackensack, New Jersey
Copyright © 2004, by Salem Press, Inc. All rights in this book are reserved. No part of this work may be used or reproduced in any manner whatsoever or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without written permission from the copyright owner except in the case of brief quotations embodied in critical articles and reviews. For information address the publisher, Salem Press, Inc., P.O. Box 50062, Pasadena, California 91115. ∞ The paper used in these volumes conforms to the American National Standard for Permanence of Paper for Printed Library Materials, Z39.48-1992 (R1997). Library of Congress Cataloging-in-Publication Data Ecology basics / edited by the editors of Salem Press. p. cm. — (Magill’s choice) Includes bibliographical references. ISBN 1-58765-174-2 (set : alk. paper) — ISBN 1-58765-175-0 (v. 1 : alk. paper) — ISBN 1-58765-176-9 (v. 2 : alk. paper) 1. Ecology—Encyclopedias. I. Salem Press. II. Series. QH540.4.E39 2003 577′.03—dc21 2003011370
First Printing
printed in the united states of america
Contents Publisher’s Note . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ix Contributors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xiii Complete List of Contents . . . . . . . . . . . . . . . . . . . . . . . . . xvii Acid deposition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Adaptations and their mechanisms . . . . . . . . . . . . . . . . . . . . . . 7 Adaptive radiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Allelopathy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Altruism . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Animal-plant interactions . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Balance of nature . . . . . Biodiversity . . . . . . . . Biogeography . . . . . . . Biological invasions . . . . Bioluminescence . . . . . Biomagnification . . . . . Biomass related to energy Biomes: determinants . . Biomes: types . . . . . . . Biopesticides . . . . . . . Biosphere concept . . . .
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28 32 37 40 43 47 50 55 59 65 69
Camouflage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72 Chaparral . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 Clines, hybrid zones, and introgression . . . . . . . . . . . . . . . . . . 80 Coevolution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 Colonization of the land . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 Communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 Communities: ecosystem interactions . . . . . . . . . . . . . . . . . . . 100 Communities: structure . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 Competition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 Conservation biology . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 Convergence and divergence . . . . . . . . . . . . . . . . . . . . . . . . 120 v
Ecology Basics Deep ecology . . . . . . . . . . . . . . . Defense mechanisms . . . . . . . . . . Deforestation . . . . . . . . . . . . . . Demographics . . . . . . . . . . . . . . Dendrochronology . . . . . . . . . . . Desertification . . . . . . . . . . . . . . Deserts . . . . . . . . . . . . . . . . . . Development and ecological strategies Displays . . . . . . . . . . . . . . . . .
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123 125 131 137 145 149 154 161 167
Ecology: definition . . . . . . . . . . . . Ecology: history . . . . . . . . . . . . . . Ecosystems: definition and history . . . Ecosystems: studies . . . . . . . . . . . . Endangered animal species . . . . . . . . Endangered plant species . . . . . . . . . Erosion and erosion control . . . . . . . . Ethology . . . . . . . . . . . . . . . . . . Eutrophication . . . . . . . . . . . . . . . Evolution: definition and theories . . . . Evolution: history . . . . . . . . . . . . . Evolution of plants and climates . . . . . Extinctions and evolutionary explosions
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171 179 184 191 196 205 211 215 222 227 236 241 246
Food chains and webs Forest fires . . . . . . Forest management . Forests . . . . . . . .
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255 258 263 269
Gene flow . . . . . . . . . . Genetic diversity . . . . . . . Genetic drift . . . . . . . . . Genetically modified foods . Geochemical cycles . . . . . Global warming . . . . . . . Grasslands and prairies . . . Grazing and overgrazing . . Greenhouse effect . . . . . .
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274 278 281 284 288 292 298 304 308
Habitats and biomes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 313 Habituation and sensitization . . . . . . . . . . . . . . . . . . . . . . . 319 vi
Contents Herbivores . . . . . . . . . . Hierarchies . . . . . . . . . . Human population growth . Hydrologic cycle . . . . . . .
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326 329 333 338
Insect societies . . . . . . . . Integrated pest management Invasive plants . . . . . . . . Isolating mechanisms . . . .
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343 351 354 358
Lakes and limnology . . . . . . . . . . . . . . . . . . . . . . . . . . . . 364 Landscape ecology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 374 Lichens . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 381
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Publisher’s Note
M
agill’s Choice: Ecology Basics offers 132 essays, each of which covers a fundamental ecological concept taught in biology, environmental science, and introductory ecology courses. Alphabetically arranged, these topics range from the level of individual organisms and their interactions with the environment through populations of organisms and communities of more than one species, to the level of ecosystems and global ecology. These two volumes provide coverage of ecology in its broadest scientific sense: not only according to Ernst Haeckel’s original definition—the interaction of organisms with their environment—but also in the now-conventional sense first expounded in 1954 by Herbert George Andrewartha and Louis Charles Birch as the processes that influence the “abundance and distribution” of organisms, and, further, in the sense of ecosystem ecology, introduced in 1971 by Eugene Odum. All levels taught in most general and introductory courses, as well as key environmental issues and ecological impacts of pollution, are considered here. Previously appearing in three Salem publications—Magill’s Encyclopedia of Science: Animal Life (2002), Magill’s Encyclopedia of Science: Plant Life (2003), and Earth Science (2001)—the essays begin by listing the subdiscipline of ecology into which the topic is generally categorized; where the topic is central to more than one subdiscipline, all are listed. There follows a brief synopsis defining the topic and its significance. The text of each essay, ranging from two to six pages, is subheaded to flag the core concepts addressed. Each essay ends with the signature of the academician who wrote it, a full set of cross-references to other essays in this publication that treat related concepts, and a list of sources for further study to assist students and general readers searching for fuller information. The subdisciplines into which the essays are classified are as follows: • Agricultural ecology: Also called “agroecology,” the study of agricultural ecosystems, their components (such as crop species), functions, interactions, and impact on natural ecosystems and abiotic factors such as atmospheric and water systems—often with an emphasis on the development of sustainable systems. • Aquatic and marine ecology: The study of the ecology of freshwater systems (rivers, lakes), estuaries, and marine environments (both coastal and open ocean), including the physical, chemical, and biological processes associated with them. ix
Ecology Basics • Behavioral ecology: The study of how individual organisms interact through behavior with other organisms and their environment to survive and reproduce, which has an impact on population. • Biomes: The primary, large-scale ecosystems of the world, largely identified with geographical regions and classified on the basis of precipitation, temperature, climate, soil types, flora, and fauna. • Chemical ecology: Concerns the biochemicals (or semiochemicals) that organisms produce and release, which have physiological and behavioral effects on other organisms. • Community ecology: The study of the impacts that populations of different species have on populations of other species with which they interact, be those interactions of plants with other plants, animals with other animals, or plants with animals. The emphasis is on how these populations of different species change, enhance, or delimit one another. Population ecology is related but is focused on growth and change within populations of a single species. • Ecoenergetics: The flow of energy through ecological systems at all levels, from individual organisms, populations, and communities to ecosystems and the global environment. Includes abiotic factors (such as geochemical cycles) as well as biotic factors. • Ecosystem ecology: The study of the flow of energy into, through, and out of large-scale systems, and how that flow influences all abiotic factors and living organisms in the ecosystem. • Ecotoxicology: The study of natural and human-made pollutants and their toxic effects on organisms, populations, communities, and ecosystems, as well as the ways these pollutants impact ecological processes to change ecosystems and their components. • Evolutionary ecology: The study of how evolutionary processes such as selection and adaptation influence the interactions of organisms with their environments and shape species and ecosystems. • Global ecology: The study of the impacts of such factors as global warming, pollution, and disease on organisms and ecosystems worldwide. Much of global ecology considers the ecological impacts of human-driven influences such as international travel, trade, the built environment, and the use of petrochemicals. • History of ecology: The development of the discipline of ecology. • Landscape ecology: The science of managing the habitat components of modified landscapes—a burgeoning field concerned with preserving the naturalness of modified landscapes while minimizing the negative impact of human intrusion in natural habitats within these landscapes. x
Publisher’s Note • Paleoecology: The study of past ecosystems and environments. • Physiological ecology: Sometimes called “autoecology,” “ecophysiology,” or “comparative physiology,” a type of ecology that focuses on individual organisms, examining how they function mechanically and physiologically in their environments and how such factors as temperature, seasons, soil, and nutrients affect survival and reproduction of those organisms. Unlike morphology or physiology, the emphasis is on linking individual organisms, via their performance attributes, to populations and communities. • Population ecology: The study of the growth and decline of groups of individuals of the same species, and how these fluctuations function in relation to other populations in the same ecosystem. Examines such factors as the availability of food and hence predation, herbivory, and mutualisms. Community ecology is closely related to population ecology but focuses on the interactions between populations of different species. • Restoration and conservation ecology: Restoration ecology is the study and implementation of ways to return degraded or deteriorating communities and ecosystems to their original condition. Restoration ecologists work to restore habitat and return endangered species to viable numbers; they do not seek to restore extinct species or recreate ancient habitats. Conservation ecology is the use of biological science to design and implement methods to ensure the survival of species, ecosystems, and ecological processes. Conservation biologists develop strategies to preserve biodiversity before it becomes degraded. • Soil ecology: The study of soil as an ecosystem, including the interactions of both abiotic and biotic components of soil: water, minerals, bacteria, fungi, plant matter, microbial organisms, and small animals such as insects and worms. Soil ecology extends beyond the physical borders of soil to include the impact of soil on aboveground lifeforms such as larger plants and animals, as well as processes (geochemical cycles, erosion, human agricultural practices) that impact soil. • Speciation: The study of the processes whereby new species arise. • Theoretical ecology: The study of the fundamental theories, concepts, and models of ecological relationships, from the simplest predator-prey, host-parasite models to population, community, ecosystem, global, and evolutionary models. For convenience, both volumes of Ecology Basics contain a full list of the contents. At the end of volume 2, several research tools are offered: a Glosxi
Ecology Basics sary, a list of Web Sites, a Categorized Index (by type of ecology), and a Subject Index. All essays were prepared by qualified academicians and experts, without whose invaluable contributions these volumes would not be possible. Their names and affiliations follow.
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Contributors Richard Adler University of Michigan, Dearborn
David L. Chesemore California State University, Fresno
Steve K. Alexander University of Mary Hardin-Baylor
Sneed B. Collard University of West Florida
Richard W. Arnseth Science Applications International
J. A. Cooper Independent Scholar
George K. Attwood Maharishi International University
Alan D. Copsey Central University of Iowa
David Landis Barnhill Guilford College
Mark S. Coyne University of Kentucky
Erika L. Barthelmess St. Lawrence University
Greg Cronin University of Colorado at Denver
Margaret F. Boorstein C. W. Post College of Long Island University
James F. Crow University of Wisconsin
P. E. Bostick Kennesaw State College
Gordon Neal Diem ADVANCE Education and Development Institute
Catherine M. Bristow Michigan State University
John P. DiVincenzo Middle Tennessee State University
William R. Bromer Pepperdine University
Allan P. Drew SUNY, College of Environmental Science and Forestry
Steven D. Carey University of Mobile
Frank N. Egerton University of Wisconsin, Parkside
Richard W. Cheney, Jr. Christopher Newport University
David K. Elliott Northern Arizona University
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Ecology Basics Jessica O. Ellison Clarkson University
David Wason Hollar, Jr. Rockingham Community College
Danilo D. Fernando SUNY, College of Environmental Science and Forestry
Robert Hordon Rutgers University Richard D. Howard Independent Scholar
James F. Fowler State Fair Community College
Jason A. Hubbart California State University, Fresno
Roberto Garza San Antonio College
Samuel F. Huffman University of Wisconsin, River Falls
Ray P. Gerber Saint Joseph’s College
Lawrence E. Hurd Washington and Lee University
D. R. Gossett Louisiana State University, Shreveport
Diane White Husic East Stroudsburg University
Jerry E. Green Miami University
Jeffrey A. Joens Florida International University
Linda Hart University of Wisconsin, Madison
Christopher Keating Angelo State University
Thomas E. Hemmerly Middle Tennessee State University
Kenneth M. Klemow Wilkes University
John S. Heywood Southwest Missouri State University
P. R. Lannert Independent Scholar
Joseph W. Hinton Independent Scholar
David M. Lawrence John Tyler Community College
Carl W. Hoagstrom Ohio Northern University
Walter Lener Nassau Community College
Virginia L. Hodges Northeast State Technical Community College
W. David Liddell Utah State University xiv
Contributors Robert Lovely University of Wisconsin, Madison
Edward N. Nelson Oral Roberts University
Yiqi Luo University of Oklahoma
Bryan Ness Pacific Union College
Michael L. McKinney University of Tennessee, Knoxville
John G. New Loyola University of Chicago
Kristie Macrakis Harvard University
Edward B. Nuhfer University of Wisconsin, Platteville
Paul Madden Hardin-Simmons University
Oghenekome U. Onokpise Florida A&M University
Nancy Farm Männikkö Independent Scholar
Robert W. Paul St. Mary’s College of Maryland
Linda Mealey College of St. Benedict
Rex D. Pieper New Mexico State University
John S. Mecham Texas Tech University
Noreen D. Poor University of South Florida
Randall L. Milstein Oregon State University
Robert Powell Avila College
Eli C. Minkoff Bates College
Donald R. Prothero Occidental College
Richard F. Modlin University of Alabama, Huntsville
Carol S. Radford Maryville University, St. Louis
Thomas C. Moon California University of Pennsylvania
P. S. Ramsey Independent Scholar
Randy Moore Wright State University
C. Mervyn Rasmussen Independent Scholar
Christina J. Moose Independent Scholar xv
Ecology Basics Ronald J. Raven State University of New York at Buffalo
Sanford S. Singer University of Dayton Elizabeth Slocum Independent Scholar
Darrell L. Ray University of Tennessee, Martin
Dwight G. Smith Southern Connecticut State University
David D. Reed Michigan Technological University
Roger Smith Independent Scholar
Gregory J. Retallack University of Oregon
Valerie M. Sponsel University of Texas, San Antonio
Mariana Louise Rhoades St. John Fisher College
Joan C. Stevenson Western Washington University
James L. Robinson University of Illinois at UrbanaChampaign
Dion Stewart Adams State College
David W. Rudge Western Michigan University
Toby R. Stewart Independent Scholar
James L. Sadd Occidental College
Marshall D. Sundberg Emporia State University
Lisa M. Sardinia Pacific University
Frederick M. Surowiec Independent Scholar
Samuel M. Scheiner Northern Illinois University
Leslie V. Tischauser Prairie State College
John Richard Schrock Emporia State University
Yujia Weng Northwest Plant Breeding Company
Donna Janet Schroeder College of St. Scholastica
Samuel I. Zeveloff Weber State College
Jon P. Shoemaker University of Kentucky
Ming Y. Zheng Gordon College xvi
Complete List of Contents Volume 1 Deforestation, 131 Demographics, 137 Dendrochronology, 145 Desertification, 149 Deserts, 154 Development and ecological strategies, 161 Displays, 167 Ecology: definition, 171 Ecology: history, 179 Ecosystems: definition and history, 184 Ecosystems: studies, 191 Endangered animal species, 196 Endangered plant species, 205 Erosion and erosion control, 211 Ethology, 215 Eutrophication, 222 Evolution: definition and theories, 227 Evolution: history, 236 Evolution of plants and climates, 241 Extinctions and evolutionary explosions, 246 Food chains and webs, 255 Forest fires, 258 Forest management, 263 Forests, 269 Gene flow, 274 Genetic diversity, 278 Genetic drift, 281 Genetically modified foods, 284
Acid deposition, 1 Adaptations and their mechanisms, 7 Adaptive radiation, 12 Allelopathy, 15 Altruism, 18 Animal-plant interactions, 24 Balance of nature, 28 Biodiversity, 32 Biogeography, 37 Biological invasions, 40 Bioluminescence, 43 Biomagnification, 47 Biomass related to energy, 50 Biomes: determinants, 55 Biomes: types, 59 Biopesticides, 65 Biosphere concept, 69 Camouflage, 72 Chaparral, 76 Clines, hybrid zones, and introgression, 80 Coevolution, 86 Colonization of the land, 90 Communication, 95 Communities: ecosystem interactions, 100 Communities: structure, 104 Competition, 111 Conservation biology, 119 Convergence and divergence, 120 Deep ecology, 123 Defense mechanisms, 125 xvii
Ecology Basics Geochemical cycles, 288 Global warming, 292 Grasslands and prairies, 298 Grazing and overgrazing, 304 Greenhouse effect, 308 Habitats and biomes, 313 Habituation and sensitization, 319 Herbivores, 326 Hierarchies, 329
Human population growth, 333 Hydrologic cycle, 338 Insect societies, 343 Integrated pest management, 351 Invasive plants, 354 Isolating mechanisms, 358 Lakes and limnology, 364 Landscape ecology, 374 Lichens, 381
Volume 2 Mammalian social systems, 385 Marine biomes, 391 Mediterranean scrub, 399 Metabolites, 402 Migration, 407 Mimicry, 415 Mountain ecosystems, 419 Multiple-use approach, 422 Mycorrhizae, 425 Natural selection, 428 Nonrandom mating, genetic drift, and mutation, 435 Nutrient cycles, 440 Ocean pollution and oil spills, 444 Old-growth forests, 452 Omnivores, 455 Ozone depletion and ozone holes, 457 Paleoecology, 464 Pesticides, 470 Pheromones, 476 Phytoplankton, 482 Poisonous animals, 486 Poisonous plants, 490 Pollination, 495 Pollution effects, 500
Population analysis, 507 Population fluctuations, 513 Population genetics, 520 Population growth, 528 Predation, 536 Punctuated equilibrium vs. gradualism, 543 Rain forests, 549 Rain forests and the atmosphere, 554 Rangeland, 560 Reefs, 564 Reforestation, 572 Reproductive strategies, 576 Restoration ecology, 583 Savannas and deciduous tropical forests, 586 Slash-and-burn agriculture, 590 Soil, 594 Soil contamination, 601 Speciation, 604 Species loss, 608 Succession, 612 Sustainable development, 618 Symbiosis, 621 Taiga, 629 Territoriality and aggression, 633 xviii
Complete List of Contents Trophic levels and ecological niches, 641 Tropisms, 650 Tundra and high-altitude biomes, 655 Urban and suburban wildlife, 659 Waste management, 667 Wetlands, 672
Wildlife management, 677 Zoos, 681 Glossary, 687 Web Sites, 729 Categorized Index, 735 Subject Index, 741
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ACID DEPOSITION Types of ecology: Aquatic and marine ecology; Ecotoxicology Electric utilities, industries, and automobiles emit sulfur dioxide and nitrogen oxides that are readily oxidized into sulfuric and nitric acids in the atmosphere. Long-range transport and dispersion of these air pollutants produce regional acid deposition. Acid deposition alters aquatic—and possibly forest—ecosystems and accelerates corrosion of buildings, monuments, and statuary.
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n 1872 Robert Angus Smith used the term “acid rain” in his book Air and Rain: The Beginnings of a General Climatology to describe precipitation affected by coal-burning industries. Today, “acid rain” refers to the deposition of acidic gases, particles, and precipitation (rain, fog, dew, snow, or sleet) on the surface of the earth. The normal acidity of rain is pH 5.6, which is caused by the formation of carbonic acid from water-dissolved carbon dioxide. The acidity of precipitation collected at monitoring stations around the world varies from pH 3.8 to 6.3 (pH 3.8 is three hundred times as acidic as pH 6.3). The acidity is created when sulfur dioxide and nitrogen oxides react with water and oxidants in the atmosphere to form watersoluble sulfuric and nitric acids. Ammonia, as well as soil constituents such as calcium and magnesium that are often present in suspended dust, neutralizes atmospheric acids, which helps explain the geographical variation of precipitation acidity. Increasing Acidity Between the mid-nineteenth century and World War II, the Industrial Revolution led to a tremendous increase in coal burning and metal ore processing in both Europe and North America. The combustion of coal, which contains an average of 1.5 percent sulfur by weight, and the smelting of metal sulfides released opaque plumes of smoke and sulfur dioxide from short chimneys into the atmosphere. Copper, nickel, and zinc smelters fumigated nearby landscapes with sulfur dioxide and heavy metals. One of the world’s largest nickel smelters, located in Sudbury, Ontario, Canada, began operation in 1890 and by 1960 was pouring 2.6 million tons of sulfur dioxide per year into the atmosphere. By 1970 the environmental damage extended to 72,000 hectares of injured vegetation, lakes, and soils surrounding the site; within this area 17,000 hectares were barren. The land was devastated not only by acid de1
Acid deposition
Activists blame coal-burning power plants and factory emissions for acid rain problems. After being emitted by large, stationary sources, especially those that have very high smokestacks, pollutants can travel thousands of kilometers in the atmosphere. Those that are transformed into sulfuric and nitric acid aerosols are incorporated into precipitation, which eventually makes contact with the earth’s surface. (PhotoDisc)
position but also by the accumulation of toxic metals in the soil, the clearcutting of forested areas for fuel, and soil erosion caused by wind, water, and frost heave. In urban areas, high concentrations of sulfur corroded metal and accelerated the erosion of stone structures. During the winter, the added emissions from home heating and stagnant weather conditions caused severe air pollution episodes characterized by sulfuric acid fogs and thick, black soot. In 1952 a four-day air pollution episode in London, England, killed an estimated four thousand people. After World War II, large coal-burning utilities in Western Europe and the United States built their plants with particulate control devices and tall stacks (higher than 100 meters) to improve the local air quality. Huge industrial facilities throughout Eastern Europe and the Soviet Union operated without air pollution controls for most of the twentieth century. The tall stacks increased the dispersion and transport of air pollutants from tens to hundreds of kilometers. Worldwide emissions of sulfur dioxide increased; in the United States emissions climbed from 18 million tons in 1940 to a peak of 28 million tons in 1970. Acid deposition evolved into an interstate and even an international problem. 2
Acid deposition In major cities, exhaust from automobiles combined with power plant and industrial emissions to create a choking, acrid smog of ozone, and nitric and organic acids formed by photochemical processes. The rapid deterioration of air quality in cities, with the attendant health and environmental consequences, spurred the passage of the U.S. Clean Air Act (CAA) of 1963, which was amended and expanded in 1970, 1977, and 1990. Each amendment to the CAA brought new requirements for air pollution controls. Effects on Aquatic Ecosystems The nature and extent of the environmental impact of acid deposition are in dispute. Landscapes or surface waters impoverished by limestone or acid-buffering soils are more sensitive to acid deposition. Regions that are both sensitive and exposed to acid deposition include the eastern United States, southeastern Canada, southern Sweden and Norway, central and Eastern Europe, the United Kingdom, southeastern China, and the northern tip of South America. Scientists hypothesize that within these regions acid rain disrupts aquatic ecosystems and contributes to forest decline. In southern Norway, for example, fish have been virtually extinct since the late 1970’s in four-fifths of the lakes and streams in an area of 2 mil-
Acid Precipitation pH Scale Seawater 8
Pure water 7
Natural background precipitation 6
5
Citric juices 4
3
Alkaline
2
pH
1
Acid Most surface fresh waters Increasing risk to organisms Acid precipitation, eastern U.S., Scandinavia Acid precipitation, western U.S.
Acidified lakes and streams, northeastern U.S., Scandinavia
Source: Adapted from John Harte, “Acid Rain,” in The Energy-Environment Connection, edited by Jack M. Hollander, 1992. Note: The acid precipitation pH ranges given correspond to volume-weighted annual averages of weekly samples.
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Acid deposition lion hectares. Records and long-term monitoring showed that the decline of fish populations began in the early twentieth century with dramatic losses in the 1950’s. A strong correlation has been found between fish extinction and lake acidity. Researchers have also found that the diversity of not only fish but also phytoplankton, zooplankton, invertebrates, and amphibian species diminishes by more than 50 percent as lake water pH drops from 6.0 to 5.0. Below pH 5.6, aluminum released from lake sediments or leached from the surrounding soils interferes with gas and ion exchange in fish gills and can be toxic to aquatic life. Below pH 4.0, no fish survive. In the United States, 11 percent of the lakes in the Adirondack Mountains in New York are too acidic to sustain fish life. Much controversy surrounds the claim that these lakes were acidified by plumes of air pollutants carried by prevailing winds from the Ohio River Valley. Like the lakes in Norway, the Adirondack lakes have low acid-neutralizing capacity. Fish declines that began in the early twentieth century and continued through the 1980’s corresponded to reductions in pH. Fish kills often followed spring snowmelt, which filled the waterways with acid accumulated in winter precipitation. Historical records, field observations, and laboratory experiments contradict arguments that overfishing, disease, or water pollution killed the fish. Effects on Forests and Cities In areas exposed to acid rain, dead and dying trees stand as symbols of environmental change. In Germany the term Waldsterben, or forest death, is used to describe the rapid declines of Norway spruce, Scotch pine, and silver fir trees in the early 1980’s, followed by beech and oak trees in the late 1980’s, especially at high elevations in the Black and Bavarian Forests. At higher altitudes, clouds frequently shroud mountain peaks, bathing the forest canopy in a mist of heavy metals, and sulfuric and nitric acids. Under drought conditions, invisible plumes of ozone from sources hundreds of kilometers distant intercept the mountain slopes. Several forests within the United States are likewise affected, including the forests of ponderosa pine in the San Bernardino Mountains of California, balsam fir in the Smokey Mountains of North Carolina and Tennessee, and red spruce in the Green and White Mountains of New England. After more than one decade of intensive field and laboratory investigations of forest decline in North America and Europe, the link between dead trees and acid deposition remained little more than circumstantial. Laboratory experiments often showed that acid rain had no effect, or even a fertilizing effect, on trees. Changes in foliage color, size, and shape; destruction 4
Acid deposition of fine roots and associated fungi; and stunted growth are symptoms of tree stress. Many researchers attribute these symptoms and forest decline to the interactions of acid precipitation, ozone, excessive nitrogen deposition, land management practices, climate change, drought, and pestilence. Ambient air concentrations of sulfur dioxide and nitrogen oxides are typically higher in major cities, a result of the high density of emission sources. The acids they form accelerate the weathering of exposed stone, brick, concrete, glass, metal, and paint. For example, the calcite in limestone and marble reacts with water and sulfuric acid to form gypsum (calcium sulfate). The gypsum washes off stone with rain or, if eaves protect the stone, accumulates as a soot-darkened crust. The acid-induced weathering obscures the details of elaborate carvings on medieval cathedrals, ancient Greek columns, and Mayan ruins at alarming rates. Graffiti, pigeon excrement, and the growth of bacteria and fungi on rock surfaces may compound the damage. Prevention Efforts In the United States, the Acidic Deposition Control Program, Title IV of the Clean Air Act amendments of 1990, directed the Environmental Protection Agency (EPA) to reduce the adverse effects of acid rain. Public law mandated that the United States achieve 40 percent and 10 percent annual reductions in sulfur dioxide and nitrogen dioxide emissions, respectively, by the year 2000 from a 1980 base. The National Acid Precipitation Assessment Program coordinates interagency acid deposition monitoring and research, and assesses the cost, benefits, and effectiveness of acid deposition control strategies. This echoes the 1985 30 Percent Protocol of the Convention on Long-Range Transboundary Air Pollution. Twenty-one nations signed the protocol, thereby agreeing to reduce sulfur dioxide emissions 30 percent from 1980 levels by 1993. Strategies to reduce acid deposition in the United States target large electric utilities responsible for 70 percent of the sulfur dioxide and 30 percent of the nitrogen oxide emissions. Utilities participate in a novel marketbased emission allowance trading and banking system that permits great flexibility in controlling sulfur dioxide emissions. For example, a utility may choose to remove sulfur from coal by cleaning it, burn a cleaner fuel such as natural gas, or install a gas desulfurization system to reduce emissions. The $6 billion international Clean Coal Technology Demonstration Program, funded by governments and private industries, continues to develop technologies—such as catalytic conversion of nitrogen oxides to inert nitrogen—to radically decrease emissions of acid gases from coal-fired power plants. 5
Acid deposition Computer models of acid deposition in the northeastern United States predicted that a 50 percent reduction in sulfur dioxide emissions would decrease sulfur deposition by 44 to 48 percent. Between 1980 and 1996, U.S. electric utilities lowered annual emissions of sulfur dioxide by 30 percent from 17.5 million tons and nitrogen oxides by 14 percent from 7 million tons. Average ambient air concentrations of sulfur dioxide decreased 37 percent and nitrogen oxide concentrations 10 percent between 1987 and 1996. However, a similar trend in sulfate and nitrate deposition has not been observed. Noreen D. Poor See also: Lakes and limnology; Marine biomes; Ocean pollution and oil spills; Reefs. Sources for Further Study Adriano, D. C., and A. H. Johnson, eds. Biological and Ecological Effects. Vol. 2 in Acidic Precipitation. New York: Springer-Verlag, 1989. Ahrens, C. Donald. Meteorology Today. 6th ed. Pacific Grove, Calif.: Brooks/ Cole, 2000. Canter, Larry W. Acid Rain and Dry Deposition. Chelsea, Mich.: Lewis, 1989. Ellerman, A. Denny, et al. Markets for Clean Air: The U.S. Acid Rain Program. New York, N.Y.: Cambridge University Press, 2000. Illustrated. Gunn, John M., ed. Restoration and Recovery of an Industrial Region: Progress in Restoring the Smelter-Damaged Landscape near Sudbury, Canada. New York : Springer-Verlag, 1995. Lutgens, Frederick K., and Edward J. Tarbuck. The Atmosphere. 8th ed. Upper Saddle River, N.J.: Prentice Hall, 2001. U.S. Geological Survey. Acid Rain and Our Nation’s Capital. Author, 1997.
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ADAPTATIONS AND THEIR MECHANISMS Types of ecology: Evolutionary ecology; Physiological ecology Adaptations are structures, physiological mechanisms, or behaviors that are shaped by the environment and enable organisms to cope with specific environmental conditions. Studying adaptations helps scientists understand how organisms live with environmental constraints and allows them to examine the mechanisms of evolution.
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hy so many species exist is one of the most intriguing questions of ecology. The study of adaptations offers an explanation. Because there are many ways to cope with the environment, and because natural selection has guided the course of evolutionary change for billions of years, the vast variety of species existing on the earth today is simply an extremely complicated variation on the theme of survival. Many of the features that are most interesting and beautiful in biology are adaptations. Adaptations are the result of long evolutionary processes in which succeeding generations of organisms become better able to live in their environments. Specialized structures, physiological processes, and behaviors are all adaptations when they allow organisms to cope successfully with the special features of their environments. Adaptations ensure that individuals in populations will reproduce and leave well-adapted offspring, thus ensuring the survival of the species. Mutation and Natural Selection Adaptations arise through mutations—heritable changes in an organism’s genetic material. These rare events are usually harmful, but occasionally they give specific survival advantages to the mutated organism and its offspring. When certain individuals in a population possess advantageous mutations, they are better able to cope with their specific environmental conditions and, as a result, will contribute more offspring to future generations compared with those individuals in the population that lack the mutation. Over time, the number of individuals that have the advantageous mutation will increase in the population at the expense of those that do not have it. Individuals with an advantageous mutation are said to have a higher “fitness” than those without it, because they tend to have comparatively higher survival and reproductive rates. This is natural selection. 7
Adaptations and their mechanisms Over very long periods of time, evolution by natural selection results in increasingly better adaptations to environmental circumstances. Natural selection is the primary mechanism of evolutionary change, and it is the force that either favors or selects against mutations. Although natural selection acts on individuals, a population gradually changes as those with adaptations become better represented in the total population. Predaceous fish, for example, which rely on speed to pursue and overtake prey, would benefit from specific adaptations that would increase their swimming speed. Therefore, mutations causing a sleeker and more hydrodynamically efficient form would be beneficial to the fish predator. Such changes would be adaptations if they resulted in improved predation success, diet, and reproductive success, compared with slower members of the population. Natural selection would favor the mutations because they confer specific survival advantages to those that carry the mutations and impose limitations on those lacking these advantages. Thus, those individuals with special adaptations for speed would have a competitive advantage over slower-swimming individuals. These attributes would be passed to their more numerous offspring and, in evolutionary time, speed and hydrodynamic efficiency would increase in the population. General vs. Specific Adapations Adaptations can be general or highly specific. General adaptations define broad groups of organisms whose general lifestyle is similar. For example, mammals are homeothermic, provide care for their young, and have many other adaptations in common. At the species level, however, adaptations are more specific and give narrow definition to those organisms that are more closely related to one another. Slight variations in a single characteristic, such as bill size in the seed-eating Galápagos finches, are adaptive in that they enhance the survival of several closely related species. An understanding of how adaptations function to make species distinct also furthers the knowledge of how species are related to one another. Although natural selection serves as the instrument of change in shaping organisms to very specific environmental features, highly specific adaptations may ultimately be a disadvantage. Adaptations that are specialized may not allow sufficient flexibility (generalization) for survival in changing environmental conditions. The degree of adaptative specialization is ultimately controlled by the nature of the environment. Environments, such as the tropics, that have predictable, uniform climates and have had long, uninterrupted periods of climatic stability are biologically complex and have high species diversity. Scientists generally believe that this diversity results, in part, from complex competition for resources and 8
Adaptations and their mechanisms from intense predator-prey interactions. Because of these factors, many narrowly specialized adaptations have evolved when environmental stability and predictability prevail. By contrast, harsh physical environments with unpredictable or erratic climates seem to favor organisms with general adaptations, or adaptations that allow flexibility. Regardless of the environment type, organisms with both general and specific adaptations exist because both types of adaptation enhance survivorship under different environmental circumstances. Structural Adaptations Structural adaptations are parts of organisms that enhance their survival ability. Camouflage, enabling organisms to hide from predators or their prey; specialized mouth parts that allow organisms to feed on specific food sources; forms of appendages, such as legs, fins, or webbed toes, that allow efficient movement; protective spines that make it difficult for the organism to be eaten—these are all structural adaptations. These adaptations enhance survival because they assist individuals in dealing with the rigors of the physical environment, obtaining nourishment, competing with others, or hiding from or confusing predators. Metabolic and Physiological Adaptations Metabolism is the sum of all chemical reactions taking place in an organism, whereas physiology consists of the processes involved in an organism carrying out its function. Physiological adaptations are changes in the metabolism or physiology of organisms, giving them specific advantages for a given set of environmental circumstances. Because organisms must cope with the rigors of their physical environments, physiological adaptations for temperature regulation, water conservation, varying metabolic rate, and dormancy or hibernation allow organisms to adjust to the physical environment or respond to changing environmental conditions. Desert environments, for example, pose a special set of problems for organisms. Hot, dry environments require physiological mechanisms that enable organisms to conserve water and resist prolonged periods of high temperature. Highly efficient kidneys and other excretory organs that assist organisms in retaining water are physiological adaptations related to the metabolisms of desert organisms. The kangaroo rat is a desert rodent extremely well adapted to its habitat. Kangaroo rats do not drink, but rather can obtain all of their water from the seeds they eat. They produce highly concentrated urine and feces with very low water content. Adaptation to a specific temperature range is also an important physiological adaptation. Organisms cannot live in environments with tempera9
Adaptations and their mechanisms tures beyond their range of thermal tolerance, but some organisms are adapted to warmer and others to colder environments. Metabolic response to temperature is quite variable among animals, but most animals are either homeothermic (warm-blooded) or poikilothermic (cold-blooded). Homeotherms maintain constant body temperatures at specific temperature ranges. Although a homeotherm’s metabolic heat production is constant when the organism is at rest and when environmental temperature is constant, strenuous exercise produces excess heat that must be dissipated into the environment, or overheating and death will result. Physiological adaptations that enable homeotherms to rid their bodies of heat are the ability to increase blood flow to the skin’s surface, sweating, and panting, all of which promote heat loss to the atmosphere. Behavioral Adaptations Behavioral adaptations allow organisms to respond appropriately to various environmental stimuli. Actions taken in response to various stimuli are adaptive if they enhance survivorship. Migrations are behavioral adaptations because they ensure adequate food supplies or the avoidance of adverse environmental conditions. Courtship rituals that help in species recognition prior to mating, reflex and startle reactions allowing for quick retreats from danger, and social behavior that fosters specialization and cooperation for group survival are behavioral adaptations. Coevolution Because organisms must also respond and adapt to an environment filled with other organisms—including potential predators and competitors— adaptations that minimize the negative effects of biological interactions are favored by natural selection. Many times the interaction between species is so close that each species strongly influences the others in the interaction and serves as the selective force causing change. Under these circumstances, species evolve together in a process called coevolution. The adaptations resulting from coevolution have a common survival value to all the species involved in the interaction. The coevolution of flowers and their pollinators is a classic example of these tight associations and their resulting adaptations. The Peppered Moth A classic example of recent evolutionary change and adaptation comes from England. The peppered moth with a mottled gray color, is well adapted to resting quietly on pale tree bark, with which it blends nicely. This adaptive coloration (camouflage) enhanced the moth’s survival be10
Adaptations and their mechanisms cause the moths could remain largely undetected by predators during daylight hours. Between 1850 and 1950, however, industrialization near urban centers blackened tree trunks with soot, making the gray form disadvantageous, as it stood out on the contrasting background. During this period, the gray moths began to disappear from industrial areas, but a black-colored variant, previously rare, became increasingly common in the population. These circumstances made it possible for scientists to test whether the peppered moth’s camouflage was adaptive. In a simple experiment, moths were raised in the laboratory, and equal numbers of gray and black moths were released in both industrial and unpolluted rural areas. Sometime later, only half of the gray-colored moths could be recovered from the industrial sites, while only half of the black forms could be recovered from the rural sites, compared with the total number released. These results enabled the scientists to conclude that increased predation on the gray moths in industrial areas led to a greater fitness of the black moths, so the frequency of black moths increased in the population. The reverse was true at the rural sites. This is the first welldocumented case of natural selection causing evolutionary change, and it illustrates the adaptive significance of camouflage. Robert W. Paul See also: Adaptive radiation; Biodiversity; Biogeography; Camouflage; Clines, hybrid zones, and introgression; Coevolution; Defense mechanisms; Evolution: history; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Species loss; Trophic levels and ecological niches. Sources for Further Study Birkhead, Mike, and Tim Birkhead. The Survival Factor. New York: Facts on File, 1990. Brandon, Robert N. Adaptation and Environment. Princeton, N.J.: Princeton University Press, 1990. Gould, Stephen J. Ever Since Darwin. New York: W. W. Norton, 1977. Ricklefs, Robert E. Ecology. 4th ed. New York: W. H. Freeman, 1999. Rose, Michael R., and George V. Lauder, eds. Adaptation. San Diego, Calif.: Academic Press, 1996. Weibel, Ewald R. Symmorphosis: On Form and Function in Shaping Life. Cambridge, Mass.: Harvard University Press, 2000. Whitfield, Philip. From So Simple a Beginning: The Book of Evolution. New York: Macmillan, 1995. 11
ADAPTIVE RADIATION Types of ecology: Evolutionary ecology; Population ecology; Speciation In adaptive radiation, numerous species evolve from a common ancestor introduced into an environment with diverse ecological niches. The progeny evolve genetically into customized variations of themselves, each adapting to survive in a particular niche.
I
n 1898 Henry F. Osborn identified and developed the concept of adaptive radiation, whereby different forms of a species evolve, quickly in evolutionary terms, from a common ancestor. According to the principles of natural selection, organisms that are the best adapted (most fit) to compete will live to reproduce and pass their successful traits on to their offspring. The process of adaptive radiation illustrates one way in which natural selection can operate when members of one population of a species are cut off from another or migrate to a different environment that is isolated from the first. Such isolation can occur from one patch of plantings to another, from one mountaintop or hillside to another, from pond to pond, or from island to island. Faced with different environments, the group will diverge from the original population and in time become different enough to form a new species. Divergent Populations and Speciation In a divergent population, the relative numbers of one form of allele (characteristic) decrease, while the relative numbers of a different allele increase. New environmental pressures will select for favorable alleles that may not have been favored in the old environment. Over successive generations, therefore, a new gene created by random mutation may replace the original form of the gene if, for example, the trait encoded by that gene allows the divergent group to cope better with environmental factors, such as food sources, predators, or temperature. The result in the long term is that molecular material that forms genes, deoxyribonucleic acid (DNA), changes sufficiently through the growth of divergent populations to allow new generations to become significantly different from the original population. In time, the new population is unable to reproduce with members of the original population and becomes a new species. Adaptive Radiation of Animals Adaptive radiation occurs dramatically when a species migrates from one 12
Adaptive radiation landmass to another. This may occur between islands or between continents and islands. A classic example of adaptive radiation is the evolution of finches noted by Charles Darwin during his trips to the Galápagos Islands off the west coast of South America. Several species of plants and animals had migrated to these islands from the South American mainland by means of flight, wind, ocean debris, or other means of transport. Finches from the mainland—perhaps aided by winds—settled on fifteen of the islands in the Galápagos group and began to adapt to the various unoccupied ecological niches on those islands, which differed. Over several generations, natural selection favored a variety of finch species with beaks adapted for the different types of foods available on the different islands. As a result, several species of different finches evolved, roughly simultaneously, on these islands. A more recent example of adaptive radiation in its early stages has taken place in an original population of brown bears. The brown bear can be found throughout the Northern Hemisphere, ranging from the deciduous forests up into the tundra. During one of the glacier periods, a small population of the brown bear was separated from the main group; according to fossil evidence, this small population, under selection pressure from the Arctic environment, evolved into the polar bear. Although brown bears are classified as carnivores, their diets are mostly vegetarian, with occasional fish and small animals as supplements. On the other hand, the polar bear is mostly carnivorous. Besides its white coat, the polar bear is different from the brown bear in many ways, including its streamlined head and shoulders and the stiff bristles that cover the soles of its feet, which provide traction and insulation, enabling it to walk on ice. Adaptive Radiation of Plants Although plants seem unable to “migrate” as birds and other animals do, adaptive radiation occurs in the plant world as well. In the Hawaiian Islands, for example, twenty-eight species of the Asteraceae family are known together as the Hawaiian silversword alliance. The entire group appears to be traceable to one ancestor, thought to have arrived on the island of Kauai from western North America. The silverswords—which compose three genera, Argyroxiphium, Dubautia, and Wilkesia—have since evolved into twenty-eight species, and this speciation came about due to major ecological shifts. These plants are therefore prime examples of adaptive radiation. Within the silversword alliance, different species have adapted to widely varying ecosystems found throughout the islands. Argyroxiphium sandwicense, for example, is endemic to the island of Maui and grows at high elevations from 6,890 to 9,843 feet (2,100-3,000 meters) on the dry, al13
Adaptive radiation pine slopes of the volcano Haleakala. This species has succulent leaves covered with silver hairs. It is thought that the hairs lessen the pace of evaporative moisture loss and protect the leaves from the sun. In contrast, species of the genus Dubautia that grow in wet, shady forests have large leaves that lack hairs. Despite their “customized” physiologies, the silverswords that have evolved in Hawaii are all closely related to one another, so much so that any two can hybridize. Studies of the silverswords have provided what geneticist Michael Purugganan called a “genetic snapshot of plant evolution.” Jon P. Shoemaker, updated by Bryan Ness See also: Adaptations and their mechanisms; Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Coevolution; Competition; Convergence and divergence; Evolution: definition and theories; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Trophic levels and ecological niches. Sources for Further Study Givnish, Thomas J., and Kenneth J. Sytsma, eds. Molecular Evolution and Adaptive Radiation. New York: Cambridge University Press, 2000. Robichaux, Robert, et al. “’Radiating’ Plants.” Endangered Species Bulletin Update, March/April, 1999, S4-S5. Schluter, Dolph. The Ecology of Adaptive Radiation. Oxford, England: Oxford University Press, 2000.
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ALLELOPATHY Types of ecology: Chemical ecology; Community ecology Allelopathy refers to all the biochemical interactions between species, including microorganisms.
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or an allelopathic interaction to occur, chemicals must be released into the environment by one organism that will affect the growth of another. In this way allelopathy differs from competition, which involves removal of some factor from the environment that is shared with other organisms. Allelopathy was recognized as early as Theophrastus (300 b.c.e.), who pointed out that chick pea plants destroy weeds growing around them. Methods of Action A variety of different allelochemicals are produced by plants, usually as secondary metabolites that do not have a specific function in the growth and development of the host plant but that do affect the growth of other plants. Originally plant physiologists thought these secondary products were simply metabolic wastes that plants had to store because they do not have an excretory system as animals do. Their various functions are now beginning to be understood. One class of allelochemicals, coumarins, block or slow cell division in the affected plant, particularly in root cells. In this way growth of competing plants is inhibited, and seed germination can be prevented. Several kinds of allelochemicals, including flavonoids, phenolics, and tannins, suppress or alter hormone production or activity in competing plants. Other chemicals, including terpenes and certain antibiotics, alter membrane permeability of host cells, making them either leaky or impermeable. In some cases, membrane uptake can be enhanced, particularly for micronutrients in low concentration in the soil. Finally, a variety of allelochemicals have both positive and negative effects on metabolic activity of the affected plant. Allelopathy in Agriculture Most of the negative effects of weeds on crop plants have been attributed to competition; however, experiments using weed extracts have demonstrated that many weeds produce allelochemicals. Similarly, some crop plants are allelopathic to others and themselves, including wheat, corn, 15
Allelopathy
Some plant species, including peach trees, release chemicals into the soil that inhibit the growth of other plants that might otherwise compete with them. (PhotoDisc)
and rice. In these cases the residues of one year’s crop can interfere with crop growth in subsequent years. This is increasingly important for farmers to consider who are incorporating low-tillage methods to reduce soil erosion. To minimize these effects, some of the traditional techniques of cover cropping, companion cropping, and crop rotation must be employed. Known allelopaths are also beginning to be used as biological control agents to manage invasive and weedy plant species. Allelopathy in Nature Several tree species, including black walnut, black locust, and various pines, are known to produce allelochemicals that inhibit the growth of understory species. In some cases this is a result of drip from the foliage or leachate from fallen leaves and fruit. In other cases, roots secrete allelochemicals that kill seedlings of other plants. Bracken fern (Pteridium aquilinum) is known to affect the growth of many other plants. Marshall D. Sundberg See also: Animal-plant interactions; Biological invasions; Coevolution; Communities: ecosystem interactions; Competition; Defense mechanisms; 16
Allelopathy Invasive plants; Metabolites; Poisonous plants; Trophic levels and ecological niches. Sources for Further Study Moore, Randy, W. Dennis Clark, and Darrell S. Vodopich. Botany. 2d ed. New York: McGraw-Hill, 1998. Rice, Elroy L. Allelopathy. 2d ed. Orlando, Fla.: Academic Press, 1984.
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ALTRUISM Type of ecology: Behavioral ecology Altruistic behavior involves an individual’s sacrifice of self in order to help others. In some animals, altruism appears to be genetically determined.
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hose who study animal behavior (ethology) have observed that on occasion individuals act altruistically. In other words, they appear voluntarily to put the needs of their group or of another individual ahead of their own needs. According to some scientists, there are examples in nature where a particular species might not have survived had there not been sacrifice by some on behalf of the many. One important question is whether this so-called altruism has been a matter of voluntary choice or whether it has occurred as a part of the selection process, making it, therefore, an involuntary response. Group Formation Of interest to a wide group, including psychologists, sociologists, philosophers, and political scientists, are the questions of whether altruism is desirable behavior—perhaps even to the exclusion of egoism—and whether altruism may be necessary for human survival. Some wonder whether such behavior is necessary, whether it can be learned, and whether humans will voluntarily choose to learn it. Biologists and geneticists have been left the problem of determining, if possible, whether the tendency for altruism is inherited or learned behavior. Unfortunately for scientists, the study of human beings in social groups in the wild is virtually impossible. However, the study of animal behavior, primarily in native habitats, has provided some insight, although it must be recognized that different species have solved problems of survival in different ways. Animals of the same species are bound to consort, if only for mating purposes. Most species are, in fact, found to live in groups, not only for purposes of reproduction but also because sources of food attract individuals to the same places and because congregation provides better protection from predators. It is common in nature for groups to form because their individual members have the same physical needs, and such groups may stay together as long as the needs of those individuals can be met. This does not necessarily mean that there exists in the group any loyalty or even any recognition of individuals as members of the group. In more highly developed societies, however, groups such as families or tribes develop. 18
Altruism Offspring and Reproduction In animal life, two or more adults and their offspring often form close bonds and tend to exclude those who are not related. Each recognizes the others as being members, and membership is restricted to those who are among the founders or who are born into the smaller group and who conform in recognizable ways to the norms of the group. Hierarchy or rank is recognized, and often there is a division of labor within the group. It has been demonstrated that species that spend a large amount of time providing for their young tend to have developed higher social orders. Humans, for example, must care for their young much longer, before they are able to become independent, than must many of the lower forms of animal life. Humans are aware of a bond that almost always exists between parent and child and of the spirit of mutual support and a cooperation that may exist even in the extended family. Cooperative behavior within such a familial group may be considered to benefit all members. Because such behavior is not consistent, however—there are times when such bonds do not exist and when families are not cooperative—such behavior cannot necessarily be attributed to predisposition. Some have argued that in primitive animal societies, so-called altruism may have evolved of necessity in order to achieve reproductive success, but that in human society there may be no evolutionary explanation for the phenomenon. Indeed, it could be argued that pure altruism, for humans, might be self-defeating and therefore unlikely to have developed as an inherited trait. Evidence has been gathered in the study of some Hymenoptera (the order of insects that includes bees, wasps, ants, sawflies, and other colonyforming insects) that certain members of the population forage for the group while others lay eggs and remain at the nest to guard them. Where such behavior has evolved, through the necessity of feeding and protecting those that will propagate their kind, the foragers may be labeled altruistic: They have sacrificed their own reproductive possibilities for survival of the group. Some have questioned whether this phenomenon can truly be labeled altruism, however, because the donor appears to be “programmed” to perform such behaviors rather than having a choice not to perform the behaviors (conscious purpose is very difficult to assess in animals). Moreover, some researchers wonder how the traits that favor altruistic behavior can survive and become dominant in a group if those having the traits deemed desirable are not allowed to reproduce. With the use of mathematical models, it has been demonstrated that such traits can be preserved only within the family unit. Among close relatives, the traits appear with enough strength that they will be reproduced in a greater concentration, thereby compensating for 19
Altruism the loss suffered by the sacrifice of the donors. This phenomenon has been referred to as kin selection, because it occurs in groups that have strong recognition of membership—to the extent that there exists aggressive defense against intruders, even of the same species. Discrimination against outsiders is an important facet of altruism of this type. The willingness of an individual to provide for others at the expense of its own interests diminishes as the degree of relatedness decreases. Reciprocal Sacrifice Most parental behavior would not be labeled altruistic, since it is in the interest of the parent to care for the offspring in order to ensure the survival of the parent’s genes. Of perhaps more interest than what happens among closely related members of a group and even between parent and offspring is the question of what motivates sacrifice on the part of an individual when no close relationship with the recipient exists—for example, a male animal coming to the rescue of an unrelated male animal who is being attacked by a third male of the same species. One theory maintains that these acts of personal sacrifice are performed on the chance that reciprocal sacrifice may occur at some future time. Whether this type of altruism can occur through natural selection, which acts through individuals, is an interesting question. Models have shown that in a population where individuals are likely to encounter and recognize one another on a frequent basis, it is possible that reciprocal exchanges can take place. Individual A might be the donor on the first encounter, individual B on the second. This theory requires that the two must have a high probability of subsequent encounters and that the tendency for altruism must already have been established through kin selection. Because animals are usually suspicious of strangers on first encounter, it is necessary to speculate that in its beginning, altruism was a selected-for trait in very small groups where strangers were not only nonhostile but also likely to be relatives and likely to be met again. This type of behavior, in which individuals act in a manner not to their own advantage and not in order that their own genes or the genes of relatives will survive, is performed, in theory, with some expectation of imagined reciprocal gain. How this type of behavior has come about, however, is a matter requiring further study. Cultural Influences Another question concerns how much culture is an influence on the development of a hereditary tendency toward altruism. Some have suggested that after generations and generations of cultural emphasis on the need for 20
Altruism altruism, it might come to have a genetic basis. There is little hard evidence that this would occur. On the other hand, humans have had a very rapid cultural evolution, and it possible that they may have had strong genetic propensities for altruism which have been culturally overlaid. Some argue that biology and culture evolve simultaneously—that the culture is formed as a result of the imposition of genetic factors while, at the same time, genetic traits are evolving in response to cultural change. In order to understand the source of altruism in humankind, one must study such behavior in the context of many factors in human development—biological as well as social, cultural, economic, and ecologic. Studying Altruistic Behavior Those investigating the sources of altruism usually begin with a thorough understanding of whatever organism is the subject of the study. When the insect or animal cannot be studied in the wild, the ethologist tries to simulate the important features of the natural habitat in a captive environment, at least in the beginning. Models are devised, based on observable data; formulas are employed; and projections are made, which provide a basis for speculative argument when absolutes cannot be assured. By observing, it is possible to determine whether various evidences of altruism exist within a population. Altruism may be manifested in as simple a way as the sharing of food when there is a scarcity. In some populations, one might observe a division of labor in which some forfeit their reproductive possibilities in order to care for the offspring of others. This phenomenon introduces the question of how altruism can survive in a population in which the genetic traits favoring the behavior are most evident in the individuals that do not reproduce themselves. It has been shown that the tendency for altruism can be perpetuated only within the family unit where the same genetic tendency exists to some degree in members that engage in reproductive activity; this can be demonstrated by a mathematical formula. Each individual bears the inheritance coefficient or relatedness coefficient r. Offspring share with each parent an average of half of the genetic traits of each (r = 1 2). Offspring share with each grandparent one-fourth of the genetic traits of each of the older generation (r = 1 4); the same coefficient exists with cousins. Were the altruists not to reproduce, it would be required, in order for the trait to be passed on, that the reproductive chances of their siblings more than double or that the reproductive chances of their cousins more than quadruple. For the sacrifice to be of value, the genetic relationship must be close, according to the demonstration. The case has been made that in societies having evolved according to this principle, 21
Altruism there is a diminishing willingness to put the interests of others ahead of one’s own as the degree of kinship decreases. In societies where males are produced from unfertilized eggs and females from fertilized ones, female offspring of a mated pair have a high relatedness coefficient (r = 3 4). The altruists among the female siblings will benefit more, regarding their genetic potential, by caring for their sisters than for their own offspring, and it can again be observed that sacrifice is more likely to be made on behalf of the member that is more closely related. Voluntary vs. Involuntary Altruism If altruism exists in nature, and if it has come about through natural selection, then one can argue that it must be a behavior with value. When applying the human connotation to the term altruism, however, one must consider the role of choice in the manifestation of the behavior. Humans claim to admire acts of unselfishness that are seemingly done with no expectation of reward. The admiration would diminish or become nonexistent, however, if there were to be proof that the act was performed because of some primitive biological predisposition rather than because of a decision on the part of the donor. Therefore, it is necessary to make the distinction, when discussing the importance of altruism, as to whether one is referring to the acts of human beings that are performed in the face of emergency or tragedy, where a sacrifice is made as a matter of choice, or whether the intent is to consider altruism as it occurs in other creatures and seems to be involuntary. In the case of nonhuman forms, altruism as an act of voluntary sacrifice is infrequent—if indeed it exists at all. Altruism, however, as an act which is dictated by genetics, is observable, and it has been shown to have been necessary for the survival of certain species. Where animal societies have formed in which some members of the society have spent their lives caring for the offspring of others or performing other sacrificial behavior which benefits the group, there can be little doubt that such altruism has been dictated by nature for its own unique purposes. Moreover, the fact that voluntary self-sacrifice on the part of human beings does exist does not automatically make it desirable human behavior any more than aggressive behavior is automatically undesirable. The case can be made that both types of behavior are important. Perhaps the larger question is when and under what circumstances certain types of human behavior should be acceptable or desirable for the individual and for the group, and, even more important, who is qualified to decide what type of behavior is appropriate. P. R. Lannert 22
Altruism See also: Communication; Defense mechanisms; Displays; Ethology; Hierarchies; Insect societies; Mammalian social systems; Mimicry; Pheromones; Population genetics; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study Boorman, Scott A., and Paul R. Levitt. The Genetics of Altruism. New York: Academic Press, 1980. Bradie, Michael. The Secret Chain: Evolution and Ethics. Albany: State University of New York Press, 1994. Wright, Robert. Nonzero: The Logic of Human Destiny. New York: Pantheon Books, 2000. Zahn-Waxler, Carolyn, E. Mark Cummings, and Ronald Iannotti, eds. Altruism and Aggression: Biological and Social Origins. New York: Cambridge University Press, 1986.
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ANIMAL-PLANT INTERACTIONS Types of ecology: Community ecology The ways in which certain animals and plants interact have evolved in some cases to make them interdependent for nutrition, respiration, reproduction, or other aspects of survival.
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he realm of ecology involves a systematic analysis of plant-animal interactions through the considerations of nutrient flow in food chains and food webs, exchange of such important gases as oxygen and carbon dioxide between plants and animals, and strategies of mutual survival between plant and animal species through the processes of pollination and seed dispersal. Having the unique ability, by photosynthesis, to take carbon dioxide and incorporate it into organic molecules, green plants are classified as ecological producers. Animals are classified as consumers, taking the products of photosynthesis and chemically breaking them down at the cellular level to produce energy for life activities. Carbon dioxide is a waste product of this process. Given their respective status as producers and consumers, plants and animals have over the ages formed many ecological relationships. Mutualism Mutualism is an ecological interaction in which two different species of organisms beneficially reside together in close association, usually revolving around nutritional needs. One such example is a small aquatic flatworm that absorbs microscopic green algae into its tissues. The benefit to the animal is one of added food supply. The mutual adaptation is so complete that the flatworm does not actively feed as an adult. The algae, in turn, receive adequate supplies of nitrogen and carbon dioxide and are literally transported throughout tidal flats in marine habitats as the flatworm migrates, thus exposing the algae to increased sunlight. This type of mutualism, which verges on parasitism, is called symbiosis. Coevolution Coevolution is an evolutionary process wherein two organisms interact so closely that thy evolve together in response to shared or antagonistic selection pressure. A classic example of coevolution involves the yucca plant and a species of small, white moth (Tegitecula). The female moth collects pollen grains from the stamen of one flower on the plant and transports 24
Animal-plant interactions these pollen loads to the pistil of another flower, thereby ensuring crosspollination and fertilization. During this process, the moth will lay her own fertilized eggs in the flowers’ undeveloped seed pods. The developing moth larvae have a secure residence for growth and a steady food supply. These larvae will rarely consume all the developing seeds; thus, both species (plant and animal) benefit. Although this example represents a mutually positive relationship between plants and animals, other interactions are more antagonistic. Predator-prey relationships between plants and animals are common. Insects and larger herbivores consume large amounts of plant material. In response to this selection pressure, many plants have evolved secondary metabolites that make their tissues unpalatable, distasteful, or even poisonous. In response, herbivores have evolved ways to neutralize these plant defenses. Mimicry In mimicry, an animal or plant has evolved structures or behavior patterns that allow it to mimic either its surroundings or another organism as a defensive or offensive strategy. Certain types of insects, such as the leafhopper, walking stick, praying mantis, and katydid (a type of grasshopper), often duplicate plant structures in environments ranging from tropical rain forests to northern coniferous forests. Mimicry of their plant hosts affords these insects protection from their own predators as well as camouflage that enables them to capture their own prey readily. Certain species of ambush bugs and crab spiders have evolved coloration patterns that allow them to hide within flower heads of such common plants as goldenrod, enabling them to ambush the insects that visit these flowers. Nonsymbiotic Mutualism In nonsymbiotic mutualism, plants and animals coevolve morphological structures and behavior patterns by which they benefit each other but without living physically together. This type of mutualism can be demonstrated in the often unusual shapes, patterns, and colorations that more advanced flowering plants have developed to attract various insects, birds, and mammals for pollination and seed dispersal purposes. Accessory structures, called fruits, form around seeds and are usually tasty and brightly marked to attract animals for seed dispersal. Although the fruits themselves become biological bribes for animals to consume, often the seeds within these fruits are not easily digested and thus pass through the animals’ digestive tracts unharmed, sometimes great distances from the parent plant. Some seeds must pass through the digestive plant of an ani25
Animal-plant interactions mal to stimulate germination. Other types of seed dispersal mechanisms involve the evolution of hooks, barbs, and sticky substances on seeds that enable them to be easily transported by animal fur, feet, feathers, or beaks. Such strategies of dispersal reduce competition between the parent plant and its offspring. Pollinators Because structural specialization increases the possibility that a flower’s pollen will be transferred to a plant of the same species, many plants have evolved a vast array of scents, colors, and nutritional products to attract pollinators. Not only does pollen include the plant’s sperm cells; it also represents a food reward. Another source of animal nutrition is a substance called nectar, a sugar-rich fluid produced in specialized structures called nectaries within the flower or on adjacent stems and leaves. Assorted waxes and oils are also produced by plants to ensure plant-animal interactions. As species of bees, flies, wasps, butterflies, and hawkmoths are attracted to flower heads for these nutritional rewards, they unwittingly become agents of pollination by transferring pollen from stamens to pistils. Some flowers have evolved distinctive, unpleasant odors reminiscent of rotting flesh or feces, thereby attracting carrion beetles and flesh flies in search of places to reproduce and deposit their own fertilized eggs. As these animals copulate, they often become agents of pollination for the plant itself. Some tropical plants, such as orchids, even mimic a female bee, wasp, or beetle, so that the insect’s male counterpart will attempt to mate with them, thereby encouraging precise pollination. Among birds, hummingbirds are the best examples of plant pollinators. Various types of flowers with bright, red colors, tubular shapes, and strong, sweet odors have evolved in tropical and temperate regions to take advantage of hummingbirds’ long beaks and tongues as an aid to pollination. Because most mammals, such as small rodents and bats, do not detect colors as well as bees and butterflies do, some flowers instead focus upon the production of strong, fermenting, or fruitlike odors and abundant pollen rich in protein. In certain environments, bats and mice that are primarily nocturnal have replaced day-flying insects and birds as pollinators. Thomas C. Moon, updated by Bryan Ness See also: Allelopathy; Coevolution; Communities: ecosystem interactions; Communities: structure; Competition; Defense mechanisms; Food chains and webs; Herbivores; Hierarchies; Lichens; Mycorrhizae; Omnivores; Poisonous plants; Pollination; Predation; Symbiosis; Trophic levels and ecological niches. 26
Animal-plant interactions Sources for Further Study Abrahamson, Warren G., and Arthur E. Weis. Evolutionary Ecology Across Three Trophic Levels: Goldenrods, Gallmakers, and Natural Enemies. Princeton, N.J.: Princeton University Press, 1997. Barth, Friedrich G. Insects and Flowers: The Biology of a Partnership. Princeton, N.J.: Princeton University Press, 1991. Buchmann, Stephen L., and Gary Paul Nabhan. The Forgotten Pollinators. Washington, D.C.: Island Press/Shearwater Books, 1997. Dickerman, Carolyn. “Pollination: Strategies for Survival.” Ward’s Natural Science Bulletin, Summer, 1986, 1-4. Howe, Henry F., and Lynne C. Westley. Ecological Relationships of Plants and Animals. New York: Oxford University Press, 1990. John, D. M., S. J. Hawkins, and J. H. Price, eds. Plant-Animal Interactions in the Marine Benthos. Oxford, England: Clarendon Press, 1992. Lanner, Ronald M. Made for Each Other: A Symbiosis of Birds and Pines. New York: Oxford University Press, 1996. Meeuse, Bastian, and Sean Morris. The Sex Life of Flowers. New York: Facts on File, 1984. Price, Peter W., G. Wilson Fernandes, Thomas H. Lewinsohn, and Woodruff W. Benson, eds. Plant-Animal Interactions: Evolutionary Ecology in Tropical and Temperate Regions. New York: John Wiley & Sons, 1991. Rudman, William B. “Solar-Powered Animals.” Natural History 96 (October, 1987): 50-53.
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BALANCE OF NATURE Types of ecology: Ecoenergetics; Theoretical ecology The ecological concept of the balance of nature—a view that proposes that nature, in its undisturbed state, is constant—has never been legitimized in science as either a hypothesis or a theory. However, it laid the groundwork for the science of ecology and persists as a designation for a healthy environment.
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he notion of the “balance of nature” has a deep history that dates back to ancient times and has persisted into modern times. During the scientific revolution in the seventeenth century, John Graunt, a merchant, analyzed London’s baptismal and death records in 1662 and discovered the balance in the sex ratio and the regularity of most causes of death (excluding epidemics). England’s chief justice, Sir Matthew Hale, was interested in Graunt’s discoveries, but he nevertheless decided that the human population, in contrast to animal populations, must have steadily increased throughout history. He surveyed the known causes of animal mortality and in 1677 published the earliest explicit account of the balance of nature. English scientist Robert Hooke studied fossils and in 1665 concluded that they represented the remains of plants and animals, some of which were probably extinct. However, a clergyman-naturalist, John Ray, replied that the extinction of species would contradict the wisdom of the ages, by which he seems to have meant the balance of nature. Ray also studied the hydrologic cycle, the geochemical cycle of water. Antoni van Leeuwenhoek, one of the first investigators to make biological studies with a microscope, discovered that parasites are more prevalent than anyone had suspected and that they are often detrimental or even fatal to their hosts. Before that, it was commonly assumed that the relationship between host and parasite was mutually beneficial. Richard Bradley, a botanist and popularizer of natural history, pointed out in 1718 that each species of plant has its own kind of insect and that there are even different insects that eat the leaves and bark of a tree. His book A Philosophical Account of the Works of Nature (1721) explored aspects of the balance of nature more thoroughly than had been done before. Ray’s and Bradley’s books may have inspired the comment in Alexander Pope’s Essay on Man (1733) that all species are so closely interdependent that the extinction of one would lead to the destruction of all living nature. 28
Balance of nature Toward a Science of Ecology Swedish naturalist Carolus Linnaeus was an important protoecologist. His essay Oeconomia Naturae (1749; The Economy of Nature, 1749) attempted to organize the aspect of natural history dealing with the balance of nature, but he realized that one must study not only ways that plants and animals interact but also their habitats. He knew that while balance had to exist, there occurred over time a succession of plants, beginning with a bare field and ending with a forest. In Politia Naturae (1760; Governing Nature, 1760) he discussed the checks on populations that prevent some species from becoming so numerous that they eliminate others. He noticed the competition among different species of plants in a meadow and concluded that feeding insects kept them in check. French naturalist Comte de Buffon developed a dynamic perspective on the balance of nature from his studies on rodents and their predators. Rodents can increase in numbers to plague proportions, but then predators and climate reduce their numbers. Buffon also suspected that humans had exterminated some large mammals, such as mammoths and mastodons. Later another Frenchman, Jean-Baptiste Lamarck, published his book on evolution called Philosophie zoologique (1809; Zoological Philosophy, 1914), which cast doubt on extinction by arguing that fossils only represent early forms of living species: Mammoths and mastodons evolved into African and Indian elephants. In developing this idea, he minimized the importance of competition in nature. An English opponent, the geologist Charles Lyell, argued in 1833 that species do become extinct, primarily because of competition among species. Charles Darwin was inspired by his own investigations during a long voyage around the world and by his reading of the works of Linnaeus and Lyell. Darwin’s revolutionary book, On the Origin of Species by Means of Natural Selection (1859), argued an intermediate position between Lamarck and Lyell: Species do evolve into different species, but in the process, some species do indeed become extinct. Darwin’s theory of evolution might have brought an end to the balanceof-nature concept, but it did not. Instead, American zoologist Stephen A. Forbes developed an evolutionary concept of the balance of nature in his essay, “The Lake as a Microcosm” (1887). Although the reproductive rate of aquatic species is enormous and the struggle for existence among them is severe, “the little community secluded here is as prosperous as if its state were one of profound and perpetual peace.” He emphasized the stabilizing effects of natural selection. The Science of Ecology The science of ecology became formally organized between the 1890’s and 29
Balance of nature the 1910’s. One of its important organizing concepts was that of “biotic communities.” An American plant ecologist, Frederic E. Clements, wrote a large monograph titled Plant Succession (1916), in which he drew a morphological and developmental analogy between organisms and plant communities. Both the individual and the community have a life history during which each changes its anatomy and physiology. This superorganismic concept was an extreme version of the balance of nature that seemed plausible as long as one believed that a biotic community was a real entity rather than a convenient approximation of what one sees in a pond, a meadow, or a forest. However, the studies of Henry A. Gleason in 1917 and later indicated that plant species merely compete with one another in similar environments; he concluded that Clements’s superorganism was poetry, not science. While the balance-of-nature concept was giving way to ecological hypotheses and theories, Rachel Carson decided that she could not argue her case in Silent Spring (1962) without it. She admitted, “The balance of nature is not a status quo; it is fluid, ever shifting, in a constant state of adjustment.” Nevertheless, to her the concept represented a healthy environment, which humans could upset. Her usage of the phrase has persisted within the environmental movement. In 1972 English medical chemist James E. Lovelock developed a new balance-of-nature idea, which he calls Gaia, named for a Greek earth goddess. His reasoning owed virtually nothing to previous balance-of-nature notions that focused upon the interactions of plants and animals. His concept emphasized the chemical cycles that flow from the earth to the waters, atmosphere, and living organisms. He soon had the assistance of a zoologist named Lynn Margulis. Their studies convinced them that biogeochemical cycles are not random, but exhibit homeostasis, just as some animals exhibit homeostasis in body heat and blood concentrations of various substances. They believe that living beings, rather than inanimate forces, mainly control the earth’s environment. In 1988 three scientific organizations sponsored a conference of 150 scientists from all over the world to evaluate their ideas. Although science more or less understands how homeostasis works when a brain within an animal controls it, no one has succeeded in satisfactorily explaining how homeostasis can work in a world “system” that lacks a brain. The Gaia hypothesis is as untestable as were earlier balance-of-nature concepts. Frank N. Egerton See also: Animal-plant interactions; Biomass related to energy; Biosphere concept; Deep ecology; Ecology: definition; Ecosystems: definition and 30
Balance of nature history; Evolution: history; Food chains and webs; Geochemical cycles; Hydrologic cycle; Nutrient cycles; Trophic levels and ecological niches. Sources for Further Study Arthur, Wallace. The Green Machine: Ecology and the Balance of Nature. Cambridge, Mass.: Blackwell, 1990. Egerton, Frank N. “Changing Concepts of the Balance of Nature.” Quarterly Review of Biology (June, 1973). Kirchner, James W. “The Gaia Hypotheses: Are They Testable? Are They Useful?” In Scientists on Gaia, edited by Stephen H. Schneider and Penelope J. Boston. Cambridge, Mass.: MIT Press, 1991. Milne, Lorus Johnson. The Balance of Nature. New York: Knopf, 1960.
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BIODIVERSITY Types of ecology: Community ecology; Ecosystem ecology; Global ecology; Population ecology; Restoration and conservation ecology The Wildlife Society has defined biodiversity as “the richness, abundance, and variability of plant and animal species and communities and the ecological process that link them with one another and with soil, air, and water.”
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any kinds of specialists—including organismic biologists, population and evolutionary biologists, geneticists, and ecologists— investigate biological processes that are encompassed by the concept of biodiversity. Conservation biologists are concerned with the totality of biodiversity, including the process of speciation that forms new species, the measurement of biodiversity, and factors involved in the extinction process. However, the primary thrust of their efforts is the development of strategies to preserve biodiversity. The biodiversity paradigm connects classical taxonomic and morphological studies of organisms with modern techniques employed by those working at the molecular level. It is generally accepted that biodiversity can be approached at three levels of organization, commonly identified as species diversity, ecosystem diversity, and genetic diversity. Some also recognize biological phenomena diversity. Species Diversity No one knows how many species inhabit the earth. Estimates range from five million to several times that number. Each species consists of individuals that are somewhat similar and capable of interbreeding with other members of their species but are not usually able to interbreed with individuals of other species. The species that occupy a particular ecosystem are a subset of the species as a whole. Ecosystems are generally considered to be local units of nature; ponds, forests, and prairies are common examples. Conservation biologists measure the species diversity of a given ecosystem by first conducting a careful, quantitative inventory. From such data, scientists may determine the “richness” of the ecosystem, which is simply a reflection of the number of species present. Thus, an island with three hundred species would be 50 percent richer than another with only two hundred species. Some ecosystems, especially tropical rain forests and coral reefs, are much richer than others. Among the least rich are tundra regions and deserts. 32
Biodiversity A second aspect of species diversity is “evenness,” defined as the degree to which each of the various elements are present in similar percentages of the total species. As an example, consider two forests, each of which has a total of twenty species of trees. Suppose that the first forest has a few tree species represented by rather high percentages and the remainder by low percentages. The second forest, with its species more evenly distributed, would rate higher on a evenness scale. Species diversity, therefore, is a value that combines measures of both species richness and species evenness. Values obtained from a diversity index are used in comparing species diversity among ecosystems of both the same and different types. They also have implications for the preservation of ecosystems; other things being equal, it would be preferable to preserve ecosystems with a high diversity index, thus protecting a larger number of species. Species Diversity and Geographical Areas Considerable effort has been expended to predict species diversity as determined by the nature of the area involved. For example, island biogeography theory suggests that islands that are larger, nearer to other islands or continents, and have a more heterogeneous landscape would be expected to have a higher species diversity than those possessing alternate traits. Such predictions apply not only to literal islands but also to other discontinuous ecosystems. Examples would be the ecosystems of isolated mountaintops in alpine tundra or those of ponds several miles apart. The application of island biogeography theory to designing nature preserves was proposed by Jared Diamond in 1975. His suggestion began the “single larger or several smaller,” or SLOSS, area controversy. Although island biogeography theory would, in many instances, suggest selecting one large area for a nature preserve, it is often the case that several smaller areas, if carefully selected, could preserve more species. The species diversity of a particular ecosystem is subject to change over time. Pollution, deforestation, and other types of habitat degradation invariably reduce diversity. Conversely, during the extended process of ecological succession that follows disturbances, species diversity typically increases until a permanent, climax ecosystem with a large index of diversity results. It is generally assumed by ecologists that more diverse ecosystems are more stable than are those with less diversity. Certainly, the more species present, the greater the opportunity for various interactions, both with other species and with the environment. Examples of interspecific reactions include mutualism, predation, and parasitism. Such interactions apparently help to integrate a community into a whole, thus increasing its stability. 33
Biodiversity Ecosystem Diversity Ecology can be defined as the study of ecosystems. From a conservation standpoint, ecosystems are important because they sustain their particular assemblage of living species. Conservation biologists also consider ecosystems to have an intrinsic value beyond the species they harbor. Therefore, it would be ideal if representative global ecosystems could be preserved. However, this is far from realization. Just deciding where to draw the line between interfacing ecosystems can be a problem. For example, the water level of a stream running through a forest is subject to seasonal fluctuation, causing a transitional zone characterized by the biota from both adjoining ecosystems. Such ubiquitous zones negate the view that ecosystems are discrete units with easily recognized boundaries. The protection of diverse ecosystems is of utmost importance to the maintenance of biodiversity. However, ecosystems throughout the world are threatened by global warming, air and water pollution, acid deposition, ozone depletion, and other destructive forces. At the local level, deforestation, thermal pollution, urbanization, and poor agricultural practices are among the problems affecting ecosystems and therefore reducing biodiversity. Both global and local environmental problems are amplified by rapidly increasing world population pressures. In the process of determining which ecosystems are most in need of protection, it has become apparent to many scientists that a system for naming and classifying ecosystems is highly desirable, if not imperative. Efforts are being made to establish a system similar to the hierarchical system applied to species that was developed by Swedish botanist Carl Linnaeus during the eighteenth century. However, a classification system for ecosystems is far from complete. Freshwater, marine, and terrestrial ecosystems are recognized as main categories, with each further divided into particular types. Though tentative, this has made possible the identification and preservation of a wide range of representative, threatened ecosystems. In 1995 conservation biologist Reed F. Noss of Oregon State University and his colleagues identified more than 126 types of ecosystems in the United States that are threatened or critically endangered. The following list illustrates their diversity: southern Appalachian spruce-fir forests; eastern grasslands, savannas, and barrens; California native grasslands; Hawaiian dry forests; caves and Karst systems; old-growth forests of the Pacific Northwest; and southern forested wetlands. Not all ecosystems can be saved. Establishing priorities involves many considerations, some of which are economic and political. Ideally, choices would be made on merit: rarity, size, number of endangered species they include, and other objective, scientific criteria. 34
Biodiversity Genetic Diversity Most of the variation among individuals of the same species is caused by the different genotypes (combinations of genes) that they possess. Such genetic diversity is readily apparent in cultivated or domesticated species such as cats, dogs, and corn, but also exists, though usually to a lesser degree, in wild species. Genetic diversity can be measured only by exacting molecular laboratory procedures. The tests detect the amount of variation in the deoxyribonucleic acid (DNA) or isoenzymes (chemically distinct enzymes) possessed by various individuals of the species in question. A significant degree of genetic diversity within a population or species confers a great advantage. This diversity is the raw material that allows evolutionary processes to occur. When a local population becomes too small, it is subject to a serious decline in vigor from increased inbreeding. This leads, in turn, to a downward, self-perpetuating spiral in genetic diversity and further reduction in population size. Extinction may be imminent. In the grand scheme of nature, this is a catastrophic event; never again will that particular genome (set of genes) exist anywhere on the earth. Extinction is the process by which global biodiversity is reduced. Biological Phenomena Diversity Biological phenomena diversity refers to the numerous unique biological events that occur in natural areas throughout the world. Examples include the congregation of thousands of monarch butterflies on tree limbs at Point Pelee in Ontario, Canada, as they await favorable conditions before continuing their migration, or the return of hundreds of loggerhead sea turtles each April to Padre Island in the Gulf of Mexico in order to lay their eggs. Conservation Biology Although biologists have been concerned with protecting plant and animal species for decades, only recently has conservation biology emerged as an identifiable discipline. Conceived in a perceived crisis of biological extinctions, conservation biology differs from related disciplines, such as ecology, because of its advocative nature and its insistence on maintaining biodiversity as intrinsically good. Conservation biology is a value-laden science, and some critics consider it akin to a religion with an accepted dogma. The prospect of preserving global ecosystems and the life processes they make possible, all necessary for maintaining global diversity, is not promising. Western culture does not give environmental concerns a high priority. For those who do, there is more often a concern over issues relating to immediate health effects than concern over the loss of biodiversity. 35
Biodiversity Only when education in basic biology and ecology at all levels is extended to include an awareness of the importance of biodiversity will there develop the necessary impetus to save ecosystems and all their inhabitants, including humans. Thomas E. Hemmerly See also: Animal-plant interactions; Biogeography; Biomes: determinants; Biomes: types; Biosphere concept; Communities: ecosystem interactions; Communities: structure; Conservation biology; Ecosystems: definition and history; Ecosystems: studies; Endangered animal species; Endangered plant species; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Habitats and biomes; Restoration ecology; Species loss; Zoos. Sources for Further Study Baskin, Y. “Ecologists Dare to Ask: How Much Does Diversity Matter?” Science 264 (April 8, 1994): 202-203. Burton, John, ed. The Atlas of Endangered Species. 2d ed. New York: Macmillan, 1999. Cracraft, Joel, and Francesca T. Grifo, eds. The Living Planet in Crisis: Biodiversity Science and Policy. Foreword by Edward O. Wilson. New York: Columbia University Press, 1999. DiSilvestro, Roger L. The Endangered Kingdom: The Struggle to Save America’s Wildlife. New York: John Wiley & Sons, 1989. Ehrlich, Paul, and Anne Ehrlich. Extinction: The Causes and Consequences of the Disappearance of Species. New York: Random House, 1981. National Research Council. Science and the Endangered Species Act. Washington, D.C.: National Academy Press, 1995. New, T. R. An Introduction to Invertebrate Conservation. New York: Oxford University Press, 1995. Raven, Peter H., and George B. Johnson. Biology. 4th ed. Boston: McGrawHill, 1996. Reaka-Kudla, Marjorie L., Don E. Wilson, and Edward O. Wilson, eds. Biodiversity II: Understanding and Protecting Our Biological Resources. Washington, D.C.: Joseph Henry Press, 1997. Ricketts, Taylor H., et al. Terrestrial Ecoregions of North America: A Conservation Assessment. Washington, D.C.: Island Press, 1999. Stefoff, Rebecca. Extinction. New York: Chelsea House, 1992. Tudge, Colin. The Variety of Life: The Meaning of Biodiversity. New York: Oxford University Press, 2000. Wilson, Edward O., ed. Biodiversity. Washington, D.C.: National Academy Press, 1988. 36
BIOGEOGRAPHY Types of ecology: Community ecology; Population ecology To understand the underlying geography of plant and animal distributions, biogeographers integrate considerations of historical and current events and conditions.
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iogeography is the science that seeks to understand spatial patterns of biodiversity. By examining past and present distributions, biogeographers attempt to explain why certain groups of organisms occur where they do, what enables them to live there, -and what factors prevent them from moving or living elsewhere. To address these issues, biogeographic investigations must consider the effects of climate, topography, and other kinds of organisms, as well as historical events such as tectonic effects and glaciation. Such historical considerations are frequently important and conditions are constantly changing, so a group’s closest relatives and their distribution must be taken into account in order to accommodate evolutionary events. Because biogeography is such a broad discipline, individuals can rarely address an entire spectrum of relevant questions. Consequently, most biogeographers become specialists. For example, phytogeographers study plant distributions and zoogeographers examine those of animals. Historical biogeographers reconstruct origins, dispersal events, and extinctions through time. Ecological biogeographers concentrate on interactions between organisms and their environments to explain distribution patterns, and paleoecologists try to bridge the gap between historical and current conditions. Also related to the breadth of the discipline is the necessity for biogeographers to be conversant in one or more related fields. A broad knowledge of biology is obviously fundamental, as is an understanding of physical geography, but geology, paleontology, and climatology, among others, may be equally important. Trends in Biogeography Several consistent trends have emerged from biogeographic studies. Communities in isolated regions (especially large islands that have not been in contact with continents for long periods of time) tend to be unlike those found anywhere else. More types of organisms are found in tropical than in temperate or arctic regions. Fewer types of organisms are found on oceanic islands, although the organisms that are present may be found in phe37
Biogeography nomenal densities. On the other hand, some inconsistencies are striking. For example, some groups of related organisms are found throughout the world whereas other groups have very restricted ranges. Generally speaking, groups of organisms that are broadly distributed are either very old (their ancestors were in place before the continents drifted apart) or very mobile. Mobile organisms may be able to disperse actively, that is, on their own power (some species of birds and large marine mammals are good examples), whereas others are dispersed passively. Seeds of many plants, microscopic planktonic organisms, and insects are often transported by wind, currents, or other organisms. Limits to the dispersal of organisms are myriad. Size limits the ability to be blown by the wind; for example, dandelion thistles are more readily dispersed by even mild breezes than walnuts. If water is a factor, buoyancy is critical. Coconuts are found on tropical shorelines around the world in large part because they do not sink, nor are their hard shells easily penetrated by salt water. Physical barriers often limit dispersal. Deserts effectively block organisms that require moisture, land halts movement of aquatic forms, and mountains prevent the passage of plants and animals that cannot tolerate the conditions associated with high elevations. Some barriers even appear to be “psychological”; birds that could easily fly cross a stream or lake, for example, often will not. Island Biogeography In 1967, Robert H. MacArthur and Edward O. Wilson published a classic volume titled The Theory of Island Biogeography. Although islands have figured prominently in modern biology (Charles Darwin and Alfred Russel Wallace both relied heavily on evidence from islands when formulating their theories of natural selection), only during the last third of the twentieth century was island biogeography recognized as a distinct discipline. Many of the principles that form the foundation of biogeography emanated from studies of islands. Among these are relationships between biodiversity and island size, ecological heterogeneity, and proximity to continents; between isolation and endemism (species evolving in a given area and found nowhere else in the world); and between island size and location and rates of immigration, colonization, and extinction. In addition, island biogeographers frequently have been at the center of debates arguing the relevance of dispersal versus vicariance. Central to these disputes is whether disjunct distributions of organisms are attributable to movement over barriers (dispersal) or to the creation of a barrier that separated a previously contiguous range (vicariance). Although both have undoubtedly played important roles, the debate rages over which was primarily respon38
Biogeography sible for the current distributions of many faunas, both on islands surrounded by water or on terrestrial “islands” surrounded by other inhospitable habitats. Robert Powell See also: Adaptations and their mechanisms; Adaptive radiation; Biodiversity; Biological invasions; Clines, hybrid zones, and introgression; Communities: ecosystem interactions; Communities: structure; Evolution: definition and theories; Food chains and webs; Gene flow; Genetic diversity; Genetic drift; Isolating mechanisms; Landscape ecology; Migration; Nonrandom mating, genetic drift, and mutation; Population genetics; Speciation; Species loss. Sources for Further Study Cox, C. Barry, and Peter D. Moore. Biogeography: An Ecological and Evolutionary Approach. 6th ed. Malden, Mass.: Blackwell Science, 2000. Groombridge, Brian, and M. K. Jenkins, eds. Global Biodiversity: Earth’s Living Resources in the Twenty-first Century. Cambridge, England: World Conservation Monitoring Centre, 2000. Myers, Alan A., and Paul S. Giller, eds. Analytical Biogeography: An Integrated Approach to the Study of Animal and Plant Distributions. New York: Chapman & Hall, 1988. Whittaker, Robert J. Island Biogeography: Ecology, Evolution, and Conservation. New York: Oxford University Press, 1998. Wilson, Edward O., ed. Biodiversity. Washington, D.C.: National Academic Press, 1988.
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BIOLOGICAL INVASIONS Types of ecology: Community ecology; Ecosystem ecology; Ecotoxicology Biological invasions are the entry of a type of organism into an ecosystem outside its historic range. In a biological invasion, the “invading” organism may be an infectious virus, a bacterium, a plant, an insect, or an animal.
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pecies introduced to an area from somewhere else are referred to as alien or exotic species or as invaders. Because an exotic species is not native to the new area, it is often unsuccessful in establishing a viable population and disappears. The fossil record, as well as historical documentation, indicates that this is the fate of many species in new environments as they move from their native habitats. Occasionally, however, an invading species finds the new environment to its liking. In this case, the invader may become so successful in exploiting its new habitat that it can completely alter the ecological balance of an ecosystem, decreasing biodiversity and altering the local biological hierarchy. Because of this ability to alter ecosystems, exotic invaders are considered major agents in driving native species to extinction. Biological invasions by notorious species constitute a significant component of earth’s history. In general, large-scale climatic changes and geological crises are at the origin of massive exchanges of flora and fauna. On a geologic time scale, migrations of invading species from one continent to another are true evolutionary processes, just as speciation and extinction are. On a smaller scale, physical barriers such as oceans, mountains, and deserts can be overcome by many organisms as their populations expand. Organisms can be carried by water in rivers or ocean currents, transported by wind, or carried by other species as they migrate seasonally or to escape environmental pressures. Humans have transplanted plants since the beginning of plant cultivation in pre-Columbian times. The geological and historical records of the earth suggest that biological invasions contribute substantially to an increase in the rate of extinction within ecosystems. Invasive Plants In modern times, most people are not aware of the distinction between native plants and exotic species growing in their region. Recent increases in intercontinental invasion rates by exotic species, brought about primarily by human activity, create important ecological problems for the recipient 40
Biological invasions lands. Invasive plants in North America include eucalyptus trees, morning glory, and pampas grass. It would seem logical to assume that invading species might add to the biodiversity of a region, but many invaders have the opposite effect. In all ecosystems the new species are often opportunistic, driving out native species by competing with them for resources. For example, Pueraria lobata, or kudzu, is a vine native to Japan. Introduced in the United States at the 1876 Philadelphia Exposition, kudzu was planted to control erosion on hillsides and for livestock forage. By the end of the twentieth century, it could be found from Connecticut to Missouri, extending south to Texas and Florida. Kudzu covers everything in its path and grows as much as 1 foot (0.3 meter) per day. Similarly, English ivy (Hedera helix), a native of Eurasia, is considered a serious problem in West Coast states. It forms “ivy deserts” in forests and crowds out native trees and shrubs that make up essential wildlife habitat. The invasion of an ecosystem by an exotic species can effectively alter ecosystem processes. An invading species does not simply consume or compete with native species but can actually change the rules of existence within the ecosystem by altering processes such as primary productivity, decomposition, hydrology, geomorphology, nutrient cycling, and natural disturbance regimes. Invasive Insects and Microorganisms The invasion of native forests alone by nonnative insects and microorganisms has been devastating on many continents. The white pine blister rust and the balsam woolly adelgid have invaded both commercial and preserved forest lands in North America. Both exotics were brought to North America in the late 1800’s on nursery stock from Europe. The balsam woolly adelgid attacks fir trees and causes their death within two to seven years from chemical damage and by feeding on the tree’s vascular tissue. The adelgid has killed nearly every adult cone-bearing fir tree in the southern Appalachian Mountains. The white pine blister rust attacks five-needle pines; in the western United States fewer than 10 pine trees in 100,000 are resistant. Because white pine seeds are an essential food source for bears and other animals, the loss of the trees is having severe consequences across the food chain. Since the 1800’s the deciduous trees of eastern North America have been attacked numerous times by waves of invading exotic species and diseases. One of the most notable invaders is the gypsy moth, which consumes a variety of tree species. Other invaders have virtually eliminated the once-dominant American chestnut and the American elm. Tree species 41
Biological invasions that continue to decline because of new invaders include the American beech, mountain ash, white birch, butternut, sugar maple, flowering dogwood, and eastern hemlock. It is widely accepted that the invasion of exotic species is the single greatest threat to the diversity of deciduous forests in North America. Effects on Humans and Humans as Invaders Some introduced exotic species are beneficial to humanity. It would be impossible to support the present world human population entirely on species native to their regions. Humans, the ultimate biological invaders, have been responsible for the extinction of many species and will continue to be in the future. At the beginning of the twenty-first century, the United States was spending $4 billion annually to eradicate invasive plant species, a figure that does not take into account loss of biodiversity or wildlife habitat. Randall L. Milstein, updated by Elizabeth Slocum See also: Biodiversity; Biogeography; Biomagnification; Communities: ecosystem interactions; Deforestation; Endangered animal species; Endangered plant species; Eutrophication; Invasive plants; Succession. Sources for Further Study Bright, Chris. Life out of Bounds: Bioinvasion in a Borderless World. New York: Norton, 1998. Cox, George W. Alien Species in North America and Hawaii: Impacts on Natural Ecosystems. Washington, D.C.: Island Press, 1999. Crosby, Alfred. Ecological Imperialism: The Biological Expansion of Europe, 900-1900. New York: Cambridge University Press, 1994. Drake, J. A., et al. Biological Invasions: A Global Perspective. New York: Wiley, 1989. Hengeveld, Rob. Dynamics of Biological Invasions. New York: Chapman and Hall, 1989.
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BIOLUMINESCENCE Types of ecology: Chemical ecology; Physiological ecology Bioluminescence is visible light emitted from living organisms. Half of the orders of animals include luminescent species. These organisms are widespread, occurring in marine, terrestrial, and freshwater habitats. Bioluminescence is used for defense, predation, and communication.
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ioluminescence is the visible light produced by luminous animals, plants, fungi, protists, and bacteria that results from a biochemical reaction with oxygen. Unlike incandescent light from electric light bulbs, bioluminescence is produced without accompanying heat. Bioluminescence was first described in 500 b.c.e., but the chemical mechanism of bioluminescence was not elucidated until the beginning of the twentieth century. The ability to luminesce appears to have arisen as many as thirty times during evolution. The chemical systems used by luminescent organisms are similar but not exactly the same. Most organisms use a luciferin/ luciferase system. The luciferin molecules are oxidized through catalysis by an oxidase enzyme (luciferase). The oxidized form of luciferin is in an excited electronic state that relaxes to the ground state through light emission. Types of Bioluminescence Animals may produce light in one of three ways. The bioluminescence may be intracellular: Chemical reactions within specialized cells result in the emission of visible light. These specialized cells are often found within photophores. These light-producing organs may be arranged in symmetrical rows along the animal’s body, in a single unit overhanging the mouth, or in patches under the eyes, and are connected to the nervous system. Alternatively, the bioluminescence may be extracellular: The animals secrete chemicals that react in their surroundings to produce light. The third option involves a symbiotic relationship between an animal and bioluminescent bacteria. Several species of fish and squid harbor bioluminescent bacteria in specialized light organs. The symbiotic relationship is specific: Each type of fish or squid associates with a certain type of bacteria. The bacteria-filled organ is continuously luminous. The animal regulates the emission of light either by melanophores scattered over the surface of the organ or by a black membrane that may be mechanically drawn over the organ. 43
Bioluminescence
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Although bioluminescence is widespread in animals, its occurrence is sporadic. Most of the bioluminescent animal species are invertebrates. Among the vertebrates, only fish exhibit bioluminescence; there are no known luminous amphibians, reptiles, birds, or mammals. Although bioluminescence is found in terrestrial and freshwater environments, the majority of luminous organisms are marine. Scientists estimate that 96 percent of all creatures in the deep sea possess some form of light generation. Functions of Bioluminescence There appear to be three main uses of bioluminescence: finding or attracting prey, defense against predators, and communication. Although visible light penetrates into the ocean to one thousand meters at most, most fish living below one thousand meters possess eyes or other photoreceptors. Many deep-sea fish have dangling luminous light organs to attract prey. Terrestrial flies have also exploited bioluminescence for predation. The glow of glowworms (fly larvae) living in caves serves to attract insect prey, which get snared in the glowworms’ sticky mucous threads. Fungus gnats (carnivorous flies) attract small arthropods through light emission and capture the prey in webs of mucus and silk. 44
Bioluminescence Bioluminescence can serve as a decoy or camouflage. For example, jellyfish, such as comb jellies, produce bright flashes to startle a predator, while siphonophores can release thousands of glowing particles into the water as a mimic of small plankton to confuse the predator. Other jellyfish produce a glowing slime that can stick to a potential predator and make it vulnerable to its predators. Many squid and some fish possess photophores that project light downward, regardless of the orientation of the animal’s body. The emitted light matches that of ambient light when viewed from below, rendering the squid invisible to both predators and prey. The best-known example of bioluminescence used as communication is in fireflies, the common name for any of a large family of luminescent beetles. Luminescent glands are located on the undersides of the rear abdominal segments. There is an exchange of flashes between males and females. Females respond to the flashes of flying males, with the result that the male eventually approaches the female for the purpose of mating. To avoid confusion between members of different types of fireflies, the signals of each species are coded in a unique temporal sequence of flashing, the timing of which is controlled by the abundant nerves in the insect’s light-making organ. Females of one genus of fireflies (Photuris) take advantage of this by mimicking the response of females of another genus (Photinus) to lure Photinus males that the Photuris females then kill and eat. Some marine animals also utilize bioluminescence for communication. For example, lantern fish and hatchetfish (the most abundant vertebrate on earth) possess distinct arrangements of light organs on their bodies that can serve as species- and sex-recognition patterns; female fire worms release luminescent chemicals into the water during mating, beginning one hour after sundown on the three nights following the full moon; and deepsea dragonfish emit red light that is undetectable except by other dragonfish. Lisa M. Sardinia See also: Adaptations and their mechanisms; Camouflage; Communication; Defense mechanisms; Marine biomes; Metabolites; Mimicry; Pheromones; Poisonous animals; Poisonous plants; Pollination; Predation; Tropisms. Sources for Further Study Presnall, Judith Janda. Animals That Glow. Salem, Mass.: Franklin Watts, 1993. Robison, Bruce H. “Light in the Ocean’s Midwaters: Bioluminescent Marine Animals.” Scientific American 273 (July, 1995): 60-64. 45
Bioluminescence Silverstein, Alvin, and Virginia Silverstein. Nature’s Living Lights: Fireflies and Other Bioluminescent Creatures. Boston: Little, Brown, 1988. Toner, Mike. “When Squid Shine and Mushrooms Glow, Fish Twinkle, and Worms Turn into Stars.” International Wildlife 24 (May/June, 1994): 3037. Tweit, Susan J. “Dance of the Fireflies.” Audubon 101 (July/August, 1999): 26-30.
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BIOMAGNIFICATION Type of ecology: Ecotoxicology Biomagnification is the accumulation of toxic contaminants in the environment as they move up through the food chain. As members of each level of the food chain are progressively eaten by those organisms found in higher levels of the chain, the concentration of toxic chemicals within the tissues of the higher organisms increases.
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ot all chemicals, potentially toxic or not, are equally likely to undergo biomagnification. However, molecules susceptible to biomagnification have certain characteristics in common. They are resistant to natural microbial degradation and therefore persist in the environment. They are also lipophilic, tending to accumulate in the fatty tissue of organisms. In addition, the chemical must be biologically active in order to have an effect on the organism in which it is found. Such compounds are likely to be absorbed from food or water in the environment and stored within the membranes or fatty tissues. Pesticides The process usually begins with the spraying of pesticides for the purpose of controlling insect populations. Industrial contamination, including the release of heavy metals, can be an additional cause of such pollution. Biomagnification results when these chemicals contaminate the water supply and are absorbed into the lipid membranes of microbial organisms. This process, often referred to as bioaccumulation, results in the initial concentration of the chemical in an organism in a form that is not naturally excreted with normal waste material. Levels of the chemical may reach anywhere from one to three times that found in the surrounding environment. Since the nature of the chemical is such that it is neither degraded nor excreted, it remains within the organism. As organisms on the bottom of the food chain are eaten and digested by members of the next level in the chain, the concentration of the accumulated material significantly increases; at each subsequent level, the concentration may reach one order of magnitude (a tenfold increase) higher. Consequently, the levels of the pollutant at the top of the environmental food chain for the ecosystem in question—such as fish, carnivorous birds, or humans—may be as much as one million times more concentrated than the original, presumably safe, levels in the environment. 47
Biomagnification DDT For example, studies of dichloro-diphenyl-trichloroethane (DDT) levels in the 1960’s found that zooplankton at the bottom of the food chain had accumulated nearly one thousand times the level of the pollutant in the surrounding water. Ingestion of the plankton by fish resulted in concentration by another factor of several hundred. By the time the fish were eaten by predatory birds, the level of DDT was concentrated by a factor of more than two hundred thousand. DDT is characteristic of most pollutants subject to potential biomagnification. It is relatively stable in the environment, persisting for decades. It is soluble in lipids and readily incorporated into the membranes of organisms. Since pesticides are, by their nature, biologically active compounds, which reflects their ability to control insects, they are of particular concern if subject to biomagnification. DDT remains the classical example of how bioaccumulation and biomagnification may have an effect on the environment. Initially introduced as a pesticide for control of insects and insect-borne disease, DDT was not thought to be particularly toxic. However, biomagnification of the chemical was found to result in the deaths of birds and other wildlife. In addition, DDT contamination was found to result in formation of thin egg shells that greatly reduced the birthrate among birds. Before the use of DDT was banned in the 1960’s, the population levels of predatory birds such as eagles and falcons had fallen to a fraction of the levels found prior to use of the insecticide. Though it was unclear whether there was any direct effect on the human population in the United States, the discovery of elevated levels of DDT in human tissue contributed to the decision to ban the use of the chemical. Other Toxic Pesticides While DDT represents the classic example of biomagnification of a toxic chemical, it is by no means the only representative of potential environmental pollutants. Other pesticides with similar characteristics include pesticides such as aldrin, chlordane, parathion, and toxaphene. In addition, cyanide, polychlorinated biphenyls (PCBs), and heavy metals—such as selenium, mercury, copper, lead, and zinc—have also been found to concentrate within the food chain. Some heavy metals are inherently toxic or may undergo microbial modification to increase their toxic potential. For example, mercury does not naturally accumulate in membranes and was therefore not originally viewed as a significant danger to the environment. However, some microorganisms are capable of adding a methyl group to the metal and produc48
Biomagnification ing methyl mercury, a highly toxic material that does accumulate in fatty tissue and membranes. Prevention Several procedures have been adopted since the 1960’s to prevent the biomagnification of toxic materials. In addition to outright bans, pesticides are often modified to prevent their accumulation in the environment. Most synthetic pesticides contain chemical structures that are easily degraded by microorganisms found in the environment. Ideally, the pesticide should survive no longer than a single growing season before being rendered harmless by the environmental flora. Often such chemical changes require only simple modification of the basic structure. Richard Adler See also: Acid deposition; Biological invasions; Biopesticides; Endangered animal species; Food chains and webs; Genetically modified foods; Integrated pest management; Ocean pollution and oil spills; Pesticides; Phytoplankton; Pollution effects; Waste management. Sources for Further Study Atlas, Ronald, and Richard Bartha. Microbial Ecology: Fundamentals and Applications. Redwood City, Calif.: Benjamin/Cummings, 1993. Carson, Rachel. Silent Spring. Boston: Houghton Mifflin, 1962. Colborn, Theo, Dianne Dumanoski, and John Peterson Myers. Our Stolen Future: Are We Threatening Our Fertility, Intelligence, and Survival? A Scientific Detective Story. New York: Dutton, 1996.
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BIOMASS RELATED TO ENERGY Type of ecology: Ecoenergetics The relationship between the accumulation of living matter resulting from the primary production of plants or the secondary production of animals (biomass) and the energy potentially available to other organisms in an ecosystem forms the basis of the study of biomass related to energy.
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iomass is the amount of organic matter, such as animal and plant tissue, found at a particular time and place. The rate of accumulation of biomass is termed productivity. Primary production is the rate at which plants produce new organic matter through photosynthesis. Secondary production is the rate at which animals produce their organic matter by feeding on other organisms. Biomass is an instantaneous measure of the amount of organic matter, while primary and secondary production give measures of the rates at which biomass increases. Plant and animal biomass consists mostly of carbon-rich molecules, such as sugars, starches, proteins, and lipids, and other substances, such as minerals, bone, and shell. The carbon-rich organic molecules are not only the building blocks of life but also the energy-rich molecules used by organisms to fuel their activities. Primary Production: Photosynthesis Ultimately, all energy used by organisms to produce the building blocks of life and to drive life processes originated as solar energy captured by plants. Only a small fraction, less than 2 percent, of the total solar light energy received by a plant is absorbed and transformed by photosynthesis into energy-containing organic molecules. The rest of the sun’s energy passes out of the plant as heat. The rate at which plants capture light energy and transform it into chemical energy is called primary production. Because plants do not rely on other organisms to provide their energy needs, they are referred to as primary producers, or autotrophs (meaning “self-feeding”). In addition to light energy, plants must absorb water, carbon dioxide gas, and simple nutrients, such as nitrate and phosphate, to produce various organic molecules during photosynthesis. Oxygen gas is also produced. Sugars are the first energy-containing organic molecules produced in photosynthesis, and they can be changed to other, more complex, molecules, such as starches, proteins, and fats. The energy in the sugar mole50
Biomass related to energy cules can be used immediately by the plants to maintain their own respiration needs, stored as starches and fats, or can be converted to new plant tissue. It is the stored organic matter plus new tissue that contributes to the growth of plants and to biomass. Because the energy-containing products of photosynthesis can be used either immediately in respiration or in the formation of new plant biomass, two types of primary production can be distinguished. Gross production refers to the total amount of energy produced by photosynthesis. It includes both the energy used by the plant for respiration and the energy that goes into new biomass. Net production refers only to the amount of energy that accumulates as new biomass. It is only the energy in net production that is potentially available to animal consumers as food. The rate of primary production varies directly with the rate of photosynthesis; therefore, factors in the environment that affect the rate of photosynthesis affect the rate of primary production. These factors most often
Transformation of Sunlight into Biochemical Energy
Light energy from the sun Chloroplasts in plant cells convert light, water, and carbon dioxide into carbohydrates via photosynthesis Oxygen, as a by-product of photosynthesis, is released Respiration by-products are carbon dioxide, water, and energy dissipated as heat Mitochondria in plant cells perform cellular respiration
Respiration results in energy storage in ATP molecules
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Biomass related to energy include light intensity, temperature, nutrient concentrations, and moisture conditions. Each species of plant has a specific combination of these factors that promotes maximum rates of primary production. If one or more of these factors is in excess or is in short supply, then the rate of primary production is slowed. On land, the rate of primary production by plants is determined largely by light, temperature, and rainfall. The favorable combination of intense sunlight for twelve hours per day, warm temperatures throughout the year, and considerable rainfall make the tropical rain forests the most productive ecosystem on land. In contrast, Arctic tundra vegetation is exposed to reduced light intensity, very cold winters, and cool summers. Primary production there is very low. In deserts, the lack of water severely limits primary production even though light and temperature are otherwise favorable. In aquatic habitats, rates of primary production by algae, such as phytoplankton, are determined by nutrient concentration and light intensity. As sunlight penetrates water, it is quickly absorbed by the water molecules and by small suspended particles. Thus, all primary production occurs near the surface, as long as nutrients are available. Although the waters of the open ocean are very clear, and sunlight can penetrate to great depths, the scarcity of nutrients reduces the rate of primary production to less than one-tenth that of coastal bays. Secondary Production The energy and material needs of some organisms are met by consuming the organic materials produced by others. These consumer organisms are called heterotrophs; there are two types. Those that obtain their food from other living organisms are called consumers and include all animals. Those that obtain their energy from dead organisms are called decomposers and include mostly the fungi and bacteria. The energy available to each type of consumer becomes progressively less at each level of the food chain. Each consumer level uses most of its food energy, about 90 percent, to fuel its respiratory activities. In this energy-releasing process, most of the food energy is actually converted to heat and is lost to the environment. Only 10 percent or less of the original food energy is used to form new biomass. It is only this small amount of energy that is available for the next consumer level. The result is that food chains are limited in their number of links or levels by the reduced amount of energy available at each higher level. Generally, the greater the amount of primary production, the larger the number of consumer organisms and the longer the food chain. Most food 52
Biomass related to energy chains consist of three levels; rarely are there examples of up to five levels. It should be noted that the food chain concept is a simplified view of a more complex network of energy pathways, known as food webs, that occur in nature. Another outcome of the reduction in energy flow up the food chain is a progressive decrease in production and biomass. The most productive level, and the one with the greatest biomass, is therefore the primary producers, or plants. Human Threats to Primary Production The total natural primary production of the earth is limited, and human efforts to increase total world primary production much beyond its present levels may be futile. One reason for this is that much of the earth’s surface lacks optimal conditions for plant growth. The open ocean, which covers about 71 percent of the earth’s surface, has very little plant growth. On land, the Arctic, subarctic, and Antarctic regions are very unproductive most of the year. Human attempts to increase primary production in the form of food or fuel crops usually involve changing the characteristics of the land, converting forests into croplands, for example, and adding large quantities of nutrients and water. It has been estimated that humans are currently utilizing most of the easily workable croplands and that the development of additional lands for agriculture would require major changes to currently unworkable habitats, changes that would be expensive and demand much fuel energy. The study of production processes is vitally important in understanding the ecology of natural ecosystems. Such information is necessary to manage and conserve habitats and their organisms in the face of human pressures. These processes provide insight into the general health of ecosystems. Pollutants, such as acid rain or industrial toxic wastes, are known to reduce the primary and secondary productivity of forests and lakes. Throughout the world, humans are reducing the biomass of the world’s primary producers through deforestation. This is particularly true in the tropics, where high population pressures have necessitated that land be cleared for agriculture and development. There is a worldwide demand for lumber. One obvious consequence is the dramatic reduction in the primary and secondary production of these areas. The clear-cutting (removal of all the trees) of tropical forests allows unprotected soils to wash away quickly during the heavy tropical rains. It will take hundreds of years for new soils to develop and for the forest to return—if it can return at all. Deforestation is also harmful in that tropical forests form a major part of the world’s life-support system. For millions of years these forests have buffered the earth’s atmosphere by producing the oxygen gas needed by 53
Biomass related to energy animals and by removing carbon dioxide and other toxic gases. The low level of carbon dioxide in the atmosphere is believed to have moderated the earth’s temperature, counteracting the so-called greenhouse effect. It is therefore of great importance to understand and preserve these forests and other primary producers of the world. Ray P. Gerber See also: Balance of nature; Communities: structure; Deforestation; Ecology: definition; Ecosystems: studies; Food chains and webs; Geochemical cycles; Herbivores; Hydrologic cycle; Nutrient cycles; Omnivores; Phytoplankton; Predation; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Brower, James E., and Jerrold H. Zar. Field and Laboratory Methods for General Ecology. 4th ed. Boston, Mass.: WCB McGraw-Hill, 1998. Nybakken, James W. Marine Biology: An Ecological Approach. 5th ed. Menlo Park, Calif.: Benjamin Cummings, 2001. Odum, Howard T. Ecological and General Systems: An Introduction to Systems Ecology. Rev. ed. Niwot: University Press of Colorado, 1994. Pasztor, Janos, and Lars A. Kristoferson, eds. Bioenergy and the Environment. Boulder, Colo.: Westview Press, 1990. Ricklefs, Robert E. Ecology. 4th ed. New York: W. H. Freeman, 1999. Smith, Robert L. Ecology and Field Biology. 5th ed. Menlo Park, Calif.: Addison Wesley Longman, 1996.
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BIOMES: DETERMINANTS Types of ecology: Biomes; Ecosystem ecology; Global ecology; Theoretical ecology Biomes are large-scale ecological communities of both plants and animals, determined primarily by geography and climate. Worldwide, there are six major types of biomes on land: forest, grassland, woodland, shrubland, semidesert scrub, and desert.
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ne who travels latitudinally from the equator to the Arctic will cross tropical forests, deserts, grasslands, temperate forests, coniferous forest, tundra, and ice fields. Those major types of natural vegetation at regional scales are called biomes. A biome occurs wherever a particular set of climatic and edaphic (soil-related) conditions prevail with similar physiognomy. For example, prairies and other grasslands in the North American Middle West and West form a biome of temperate grasslands, where moderately dry climate prevails. Tropical rain forests in the humid tropical areas of South and Central America, Africa, and Southeast Asia create a biome where rainfall is abundant and well-distributed through the year. In general, biomes are delineated by both physiognomy and environment. There are six major physiognomic types on land: forest, grassland, woodland, shrubland, semidesert scrub, and desert. Each of the six types occurs in a wide range of environments. Therefore, more than one biome may be defined within each physiognomic type according to major differences in climate. Tropical forests, temperate deciduous forest, and coniferous forests are, for example, separate biomes, although forests dominate all of them. On the other hand, some biome types, such as the tundra, are dominated by a range of physiognomic types and are in one prevailing environmental region. Classification of Biomes There are many ways to classify biomes. One system, which designates a small number of broadly defined biomes, divides global vegetation into nine major terrestrial biomes: tundra, taiga, temperate forest, temperate rain forest, tropical rain forest, savanna, temperate grasslands, chaparral, and desert. Other systems more narrowly define biomes, designating a larger total number. In those cases, some of the broadly defined biomes are divided into two or more biomes. For example, the biome called temperate forest in a broad classification may be separated into temperature decidu55
Biomes: determinants
Biomes and Their Features
1 2
Biome
Annual Mean Rainfall1 Climate and Temperature2
Desert
250 mm or less
Arid, with extremes of heat and cold
Grasslands
250-750 mm
Cold winters, warm summers; dry periods
Mediterranean scrub
Low to moderate
Cool winters, hot summers; latitudes 30° to 45°; includes chaparral, maquis
Rain forest (tropical) 2,500-4,500 mm
20-30°
Savanna, deciduous 1,500-2,500 mm tropics
Hot summers; 3-6 months dry; seasonal fires
Taiga (boreal forest)
1,000 mm
Cold, long winters; mild, short summers; seasonal fires
Tundra
Very low year-round Very cold (3° or less); soil characerized by permafrost; Arctic tundra occurs in Arctic Circle; alpine tundra in other high elevations
In millimeters Degrees Celsius
ous forest and temperate evergreen forest in a fine classification. The biome of desert in the broad classification may be broken into warm semidesert, cool semidesert, Arctic-alpine semidesert, Arctic-pine desert, and true desert in the fine classification. Description of Biome Distributions Naturalists, geographers, and ecologists have tried to correlate world major types of biomes to climatic patterns in both descriptive and quantitative approaches. For example, in northern North America, the tundra and boreal forests are two broad belts of vegetation that stretch from east to west. The distribution of the two biomes is primarily influenced by temperature. South of those two belts are biome types that are mostly controlled by pre56
Biomes: determinants cipitation and evaporation. From east to west in North America, available moisture decreases, influencing biome distribution. Humid regions along the East Coast support forest biomes, including temperate coniferous forests and temperate deciduous forest. West of the eastern forests is a biome type of grasslands, including tall-grass prairie and short-grass steppe. In this zone, there is less precipitation than evaporation. The ratio of precipitation to evaporation is about 0.6 to 0.8 in the land that supports a tall-grass prairie and 0.2 to 0.4 farther west, where a short-grass steppe is supported. Beyond the short-grass steppe are shrubland and the deserts of the West. Western Northern America is a mountainous country in which vegetation zones reflect climatic changes on an altitudinal gradient. The vegetation in the lowlands is characteristic of the regions (short-grass steppe in the east side of Rocky Mountains, sagebrush cold semideserts in the Great Basin between the Rocky Mountains and the Sierra Nevada, and grasslands in California’s Central Valley west of the Sierra Nevada). Above the base regions, the vegetation changes from shrub, woodland, or deciduous forest to montane coniferous forests or alpine tundra. In Central America, from Mexico to Panama where precipitation becomes ample and temperatures are high, tropical rain forests and tropical seasonal forests occur. Similar distributions of biomes along latitude and altitude can be found in South America, Africa, and Eurasia. In general, the climate-induced patterns of vegetation are influenced by latitude; the location of regions within a continent, which affects the amount of moisture they receive; and altitude, in which mountains modify the climate patterns. In addition, other factors, such as fire and human disturbance, may influence distributions of biomes. For example, most grasslands require periodic fires for maintenance, renewal, and elimination of incoming woody growth. Grasslands at one time covered about 42 percent of the land surface of the world. Humans have converted much of that area into croplands. Quantitative Relationships Descriptive relationships can provide pictures of world vegetation distributions along latitudinal and altitudinal gradients of temperature and moisture. Ecologists in the past several decades have also sought quantitative relationships between distributions of biomes and environmental factors. For example, when R. H. Whittaker plotted various types of biomes on gradients of mean annual temperature and mean annual precipitation in 1975, a global pattern emerged relating biomes to climatic variables. It was shown that tropical rain-forest biomes are distributed in regions with annual mean precipitation of 2,500 to 4,500 millimeters and annual mean temperatures of 20 to 30 degrees Celsius. Tropical seasonal forest and sa57
Biomes: determinants vannas also occur in warm regions with precipitation of 1,500-2,500 millimeters and 500-1,500 millimeters per year, respectively. Temperate forests occupy regions with annual temperature of 5 to 20 degrees Celsius and precipitation exceeding 1,000 millimeters per year. This thermal zone can support temperate rain forest when annual precipitation is more than 2,500 millimeters and temperate grassland when annual precipitation is below 750 millimeters. Temperate woodland occurs between temperate forests and grasslands. Tundra and taiga are distributed in regions with annual mean temperature below 3 degrees Celsius, whereas deserts occupy areas with annual precipitation below 250 millimeters. These relationships between climatic variables and biomes provide a reasonable approximation of global vegetation patterns. Many types of biomes intergrade with one another. Soil, exposure to fire, and regional climate can influence distributions of biomes in a given area. Yiqi Luo See also: Biomes: types; Chaparral; Deserts; Forests; Grasslands and prairies; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes; Wetlands. Sources for Further Study Archibold, O. W. Ecology of World Vegetation. London: Chapman & Hall, 1995. Smith, R. L., and T. M. Smith. Ecology and Field Biology. 6th ed. San Francisco: Benjamin Cummings, 2001. Whittaker, R. H. Communities and Ecosystems. 2d ed. New York: Macmillan, 1975.
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BIOMES: TYPES Types of ecology: Biomes; Ecosystem ecology; Global ecology; Theoretical ecology Biomes are classified by geography, climate, temperature, precipitation, soil types, and typical aggregates of flora and fauna. Although classification systems vary, most agree that there are half a dozen major world biomes, which can be further classified into minor biomes.
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emperature, precipitation, soil, and length of day affect the survival and distribution of biome species. Species diversity within a biome may increase its stability and capability to deliver natural services, including enhancing the quality of the atmosphere, forming and protecting the soil, controlling pests, and providing clean water, fuel, food, and drugs. Major biomes include the temperate, tropical, and boreal forests; tundra; deserts; grasslands; chaparral; and oceans. Temperate Forests The temperate forest biome occupies the so-called temperate zones in the midlatitudes (from about 30 to 60 degrees north and south of the equator). Temperate forests are found mainly in Europe, eastern North America, and eastern China, and in narrow zones on the coasts of Australia, New Zealand, Tasmania, and the Pacific coasts of North and South America. Their climates are characterized by high rainfall and temperatures that vary from cold to mild. Temperate forests contain primarily deciduous trees—including maple, oak, hickory, and beechwood—and, secondarily, evergreen trees—including pine, spruce, fir, and hemlock. Evergreen forests in some parts of the Southern Hemisphere contain eucalyptus trees. The root systems of forest trees help keep the soil rich. The soil quality and color are due to the action of earthworms. Where these forests are frequently logged, soil runoff pollutes streams, which reduces spawning habitat for fish. Raccoons, opossums, bats, and squirrels are found in the trees. Deer and black bears roam forest floors. During winter, small animals such as marmots and squirrels burrow in the ground. Tropical Forests Tropical forests exist in frost-free areas between the Tropic of Cancer and the Tropic of Capricorn. Temperatures range from warm to hot year-round. 59
Biomes: types These forests are found in northern Australia, the East Indies, Southeast Asia, equatorial Africa, and parts of Central America and northern South America. Tropical forests have high biological diversity and contain about 15 percent of the world’s plant species. Animal life lives at each layer of tropical forests. Nuts and fruits on the trees provide food for birds, monkeys, squirrels, and bats. Monkeys and sloths feed on tree leaves. Roots, seeds, leaves, and fruit on the forest floor feed larger animals. Tropical forest trees produce rubber and hardwood, such as mahogany and rosewood. Deforestation for agriculture and pastures has caused reduction in plant and animal diversity in these forests. Boreal Forests The boreal forest is a circumpolar Northern Hemisphere biome spread across Russia, Scandinavia, Canada, and Alaska. The region is very cold. Evergreen trees such as white spruce and black spruce dominate this zone, which also contains larch, balsam, pine, fir, and some deciduous hardwoods such as birch and aspen. The acidic needles from the evergreens make the leaf litter that is changed into soil humus. The acidic soil limits the plants that develop.
Biomes of the World
Tr o p i c o f Cancer
Tr o p i c o f Capricorn
60
Desert
Tropical Rain Forest
Temperate Grassland
Taiga
Monsoon
Savanna
Temperate Forest
Tundra
Mediterranean
Mountain
Polar
Biomes: types Animals in boreal forests include deer, bears, and wolves. Birds in this zone include redtailed hawks, sapsuckers, grouse, and nuthatches. Relatively few animals emigrate from this habitat during winter. Conifer seeds are the basic winter food.
Terrestrial Biomes (percentages) Deciduous forest 7% Other 15% Rain Forest 12%
Tundra Coniferous Desert forest 29% About 5 percent of the earth’s 12% surface is covered with Arctic tundra, and 3 percent with alGrassland Tundra 12% pine tundra. The Arctic tundra 13% is the area of Europe, Asia, and North America north of the boreal coniferous forest zone, where the soils remain frozen most of the year. Arctic tundra has a permanent frozen subsoil, called permafrost. Deep snow and low temperatures slow the soil-forming process. The area is bounded by a 50 degrees Fahrenheit (122 degrees Celsius) circumpolar isotherm, known as the summer isotherm. The cold temperature north of this line prevents normal tree growth. The tundra landscape is covered by mosses, lichens, and low shrubs, which are eaten by caribou, reindeer, and musk oxen. Wolves eat these herbivores. Bears, foxes, and lemmings also live there. The most common Arctic bird is the old squaw duck. Ptarmigans and eider ducks are also very common. Geese, falcons, and loons are some of the nesting birds of the area. The alpine tundra, which exists at high altitude in all latitudes, is acted upon by winds, cold temperatures, and snow. The plant growth is mostly cushion- and mat-forming plants. Deserts The desert biome covers about one-seventh of the earth’s surface. Deserts typically receive no more than 10 inches (25 centimeters) of rainfall per year, and evaporation generally exceeds rainfall. Deserts are found around the Tropic of Cancer and the Tropic of Capricorn. As warm air rises over the equator, it cools and loses its water content. The dry air descends in the two subtropical zones on each side of the equator; as it warms, it picks up moisture, resulting in drying the land. 61
Biomes: types Rainfall is a key agent in shaping the desert. The lack of sufficient plant cover contributes to soil erosion during wind- and rainstorms. Some desert plants—for example, the mesquite tree, which has roots that grow 40 feet (13 meters) deep—obtain water from deep below the earth’s surface. Other plants, such as the barrel cactus, store large amounts of water in their leaves, roots, or stems. Some plants slow the loss of water by having tiny leaves or shedding their leaves. Desert plants have very short growth periods, because they cannot grow during the long drought periods. Grasslands Grasslands cover about one-quarter of the earth’s surface and can be found between forests and deserts. Treeless grasslands exist in parts of central North America, Central America, and eastern South America that have between 10 and 40 inches (250-1,000 millimeters) of erratic rainfall per year. The climate has a high rate of evaporation and periodic major droughts. Grasslands are subject to fire. Some grassland plants survive droughts by growing deep roots, while others survive by being dormant. Grass seeds feed the lizards and rodents that become the food for hawks and eagles. Large animals in this biome include bison, coyotes, mule deer, and wolves. The grasslands produce more food than any other biome. Overgrazing, inefficient agricultural practices, and mining destroy the natural stability and fertility of these lands, resulting in reduced carrying capacity, water pollution, and soil erosion. Diverse natural grasslands appear to be more capable of surviving drought than are simplified manipulated grass systems. This may be due to slower soil mineralization and nitrogen turnover of plant residues in the simplified system. Savannas are open grasslands containing deciduous trees and shrubs. They are near the equator and are associated with deserts. Grasses there grow in clumps and do not form a continuous layer. Chaparral The chaparral, or Mediterranean, biome is found in the Mediterranean Basin, California, parts of Australia, middle Chile, and the Cape Province of South America. This region has a climate of wet winters and summer drought. The plants have tough, leathery leaves and may have thorns. Regional fires clear the area of dense and dead vegetation. The seeds from some plants, such as the California manzanita and South African fire lily, are protected by the soil during a fire and later germinate and rapidly grow to form new plants. Vegetation dwarfing occurs as a result of the severe summer drought and extreme climate changes. 62
Biomes: types Oceans The ocean biome covers more than 70 percent of the earth’s surface and includes 90 percent of its volume. Oceans have four zones. The intertidal zone is shallow and lies at the land’s edge. The continental shelf, which begins where the intertidal zone ends, is a plain that slopes gently seaward. The neritic zone (continental slope) begins at a depth of about 600 feet (180 meters), where the gradual slant of the continental shelf becomes a sharp tilt toward the ocean floor, plunging about 12,000 feet (3,660 meters) to the ocean bottom. This abyssal zone is so deep that it does not have light. Plankton are animals that float in the ocean. They include algae and copepods, which are microscopic crustaceans. Jellyfish and animal larva are also considered plankton. The nekton are animals that move freely through the water by means of their muscles. These include fish, whales, and squid. The benthos are animals that are attached to or crawl along the ocean’s floor. Clams are examples of benthos. Bacteria decompose the dead organic materials on the ocean floor. The circulation of materials from the ocean’s floor to the surface is caused by winds and water temperature. Runoff from the land contains pollutants such as pesticides, nitrogen fertilizers, and animal wastes. Rivers carry loose soil to the ocean, where it builds up the bottom areas. Overfishing has caused fisheries to collapse in every world sector. Human Impact on Biomes Human interaction with biomes has increased biological invasions, reduced species biodiversity, changed the quality of land and water resources, and caused the proliferation of toxic compounds. Managed care of biomes may not be capable of undoing these problems. Ronald J. Raven See also: Biomes: determinants; Chaparral; Deserts; Forests; Grasslands and prairies; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes; Wetlands. Sources for Further Study Food and Agriculture Organization of the United Nations. State of the World’s Forests, 2001. Rome: Author, 2001. Gawthorp, Daniel, and David Suzuki. Vanishing Halo: Saving the Boreal Forest. Seattle: Mountaineers, 1999. 63
Biomes: types Linsenmair, K. E., ed. Tropical Forest Canopies: Ecology and Management. London: Kluwer Academic, 2001. Prager, Ellen J., with Cynthia A. Earle. The Oceans. New York: McGrawHill, 2000. Solbrig, Otto Thomas, E. Medina, and J. F. Silva, eds. Biodiversity and Savanna Ecosystem Processes: A Global Perspective. New York: Springer, 1996.
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BIOPESTICIDES Types of ecology: Agricultural ecology; Ecotoxicology Biopesticides are biological agents, such as viruses, bacteria, fungi, mites, and other organisms used to control insect and weed pests in an environmentally and ecologically friendly manner.
B
iopesticides allow biologically based, rather than chemically based, control of pests. Pests are any unwanted animal, plant, or microorganism. When the environment provides no natural resistance to a pest and when no natural antagonists are present, pests can run rampant. For example, spread of the fungus Endothia parasitica, which entered New York in 1904, caused the nearly complete destruction of the American chestnut tree because no natural control was present. Viruses, bacteria, fungi, protozoa, mites, insects, and flowers have all been used as biopesticides. Advantages and Disadvantages Many plants and animals are protected from pests by passive means. For example, plant rotation is a traditional method of insect and disease protection that is achieved by removing the host plant long enough to reduce a region’s pathogen and pest populations. Biopesticides have several significant advantages over commercial pesticides. They appear to be ecologically safer than commercial pesticides because they do not accumulate in the food chain. Some biopesticides provide persistent control, as more than a single mutation is required to adapt to them and because they can become an integral part of a pest’s life cycle. In addition, biopesticides have slight effects on ecological balances because they do not affect nontarget species. Finally, biopesticides are compatible with other control agents. The major drawbacks to using biopesticides are the time required for them to kill their targets and the inefficiency with which they work. Also, if the organism being used as a biopesticide is a nonnative species, it may cause unforeseen damage to the local ecosystem. Viruses and Bacteria Viruses have been developed against insect pests such as Lepidoptera (butterflies and moths), Hymenoptera (bees, wasps, and ants), and Dipterans (flies). Gypsy moths and tent caterpillars, for example, periodically suffer from epidemic virus infestations, which could be exploited and encouraged. 65
Biopesticides Many commensal microorganisms (microorganisms that live on or in other organisms causing no direct benefit or harm) that occur on plant roots and leaves can passively protect plants against microbial pests by competitive exclusion (that is, simply crowding them out). Bacillus cereus has been used as an inoculum on soybean seeds to prevent infection by fungal pathogens in the genus Cercospora. Some microorganisms used as biopesticides produce antibiotics, but the major mechanism in most cases seems to be competitive exclusion. For example, Agrobacterium radiobacter antagonizes Agrobacterium tumefaciens, which causes the disease crown gall. Species of two bacterial genera–Bacillus and Streptomyces—when added as biopesticides to soil, help control the damping-off disease of cucumbers, peas, and lettuce caused by Rhizoctonia solani. Bacillus subtilis added to plant tissue also controls stem rot and wilt rot caused by species of the fungus Fusarium. Mycobacteria species produce cellulose-degrading enzymes, and their addition to young seedlings helps control fungal infection by species of Pythium, Rhizoctonia, and Fusarium. Species of Bacillus and Pseudomonas produce enzymes that dissolve fungal cell walls. Bacillus thuringiensis Toxins The best examples of microbial insecticides are Bacillus thuringiensis (B.t.) toxins, which were first used in 1901. They have had widespread commercial production and use since the 1960’s and have been successfully tested on 140 insects, including mosquitoes. Insecticidal endotoxins are produced by B.t. during sporulation, and exotoxins are contained in crystalline parasporal protein bodies. These protein crystals are insoluble in water but readily dissolve in an insect’s gut. Once dissolved, the proteolytic enzymes paralyze the gut. Spores that have been consumed germinate and kill the insect. Bacillus popilliae is a related bacterium that produces an insecticidal spore that has been used to control Japanese beetles, a corn pest. The gene for the B.t. toxin has also been inserted into the genomes of cotton and corn, producing genetically modified, or GM, plants that produce their own B.t. toxin. GM cotton and B.t. corn both express the gene in their roots, which provides them with protection from root worms. Ecologists and environmentalists have expressed concern that constantly exposing pests to B.t. will cause insects to develop resistance to the toxin. In such a scenario, the effectiveness of traditionally applied B.t. would decrease. Fungi and Protozoa Saprophytic fungi can compete with pathogenic fungi. There are several examples of fungi used as biopesticides, such as Gliocladium virens, Tri66
Biopesticides choderma hamatum, Trichoderma harzianum, Trichoderma viride, and Talaromyces flavus. For example, Trichoderma species compete with pathogenic species of Verticillium and Fusarium. Peniophora gigantea antagonizes the pine pathogen Heterobasidion annosum by three mechanisms: It prevents the pathogen from colonizing stumps and traveling down into the root zone, it prevents the pathogen from traveling between infected and uninfected trees along interconnected roots, and it prevents the pathogen from growing up to stump surfaces and sporulating. Nematodes are pests that interfere with commercial button mushroom (Agaricus bisporus) production. Several types of nematode-trapping fungi can be used as biopesticides to trap, kill, and digest the nematode pests. The fungi produce constricting and nonconstricting rings, sticky appendages, and spores, which attach to the nematodes. The most common of the nematode-trapping fungi are Arthrobotrys oligospora, Arthrobotrys conoides, Dactylaria candida, and Meria coniospora. Protozoa have occasionally been used as biopesticide agents, but their use has suffered because of slow growth and the complex culture conditions associated with their commercial production. Mites, Insects, and Flowers Well-known “terminator” bugs include praying mantis and ladybugs as well as decollate snails, which eat the common brown garden snail. Fleas, grubs, beetles, and grasshoppers often have natural nematode species that prey on them, which can be used as biocontrol agents. Predaceous mites are used as a biopesticide to protect cotton from other insect pests such as the boll weevil. Parasitic wasps of the genus Encarsia, especially E. formosa, prey on whiteflies, as does Delphastus pusillus, a small, black ladybird beetle. Dalmatian and Persian insect powders contain pyrethrins, which are toxic insecticidal compounds produced in chrysanthemum flowers. Synthetic versions of these naturally occurring compounds are found in products used to control head lice. Mark S. Coyne, updated by Elizabeth Slocum See also: Biomagnification; Food chains and webs; Genetically modified foods; Integrated pest management; Multiple-use approach; Pesticides; Pollution effects; Soil; Soil contamination. Sources for Further Study Carozzi, Nadine, and Michael Koziel, eds. Advances in Insect Control: The Role of Transgenic Plants. Bristol, Pa.: Taylor & Francis, 1997. 67
Biopesticides Deacon, J. W. Microbial Control of Plant Pests and Diseases. Washington, D.C.: American Society for Microbiology, 1983. Hall, Franklin R., and Julius J. Menn, eds. Biopesticides: Use and Delivery. Totowa, N.J.: Humana Press, 1999. Hokkanen, Heikki M. T., and James M. Lynch, eds. Biological Control: Benefits and Risks. New York: Cambridge University Press, 1995.
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BIOSPHERE CONCEPT Types of ecology: Global ecology; Theoretical ecology The term “biosphere” was coined in the nineteenth century by Austrian geologist Eduard Suess in reference to the 20-kilometer-thick zone extending from the floor of the oceans to the top of mountains, within which all life on earth exists. Thought to be more than 3.5 billion years old, the biosphere supports nearly one dozen biomes, regions of climatic conditions within which distinct biotic communities reside.
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ompounds of hydrogen, oxygen, carbon, nitrogen, potassium, and sulfur are cycled among the four major spheres, one of which is the biosphere, to make the materials that are essential to the existence of life. The other spheres are the lithosphere, the outer part of the earth; the atmosphere, the whole mass of air surrounding the earth; and the hydrosphere, the aqueous vapor of the atmosphere, sometimes defined as including the earth’s bodies of water. The Water Cycle The most critical of these compounds is water, and its movement among the spheres is called the hydrologic cycle. Dissolved water in the atmosphere condenses to form clouds, rain, and snow. The annual precipitation for any region is one of the major factors in determining the terrestrial biome that can exist. The precipitation takes various paths leading to the formation of lakes and rivers. These flowing waters interact with the lithosphere (the outer part of the earth’s crust) to dissolve chemicals as they flow to the oceans. Evaporation of water from the oceans then supplies most of the moisture in the atmosphere. This cycle continually moves water among the various terrestrial and oceanic biomes. Solar Energy The biosphere is also dependent upon the energy that is transferred from the various spheres. Solar energy is the basis for almost all life. Light enters the biosphere as the essential energy source for photosynthesis. Plants take in carbon dioxide, water, and light energy, which is converted via photosynthesis into chemical energy in the form of sugars and other organic molecules. Oxygen is generated as a by-product. Most animal life reverses 69
Biosphere concept
This composite image of the earth’s biosphere shows the planet’s heaviest vegetative biomass in the dark sections, known to be rain forests. The combination of intense sunlight for twelve hours per day, warm temperatures throughout the year, and considerable rainfall make tropical rain forests the most productive ecosystems on land. (NASA)
this process during respiration, as chemical energy is released to do work by the oxidation of organic molecules to produce carbon dioxide and water. Incoming solar energy also interacts dramatically with the water cycle and the worldwide distribution of biomes. Because of the earth’s curvature, the equatorial regions receive a greater amount of solar heat than the polar regions. Convective movements in the atmosphere—such as winds, high- and low-pressure systems, and weather fronts—and the hydrosphere—such as water currents—are generated during the redistribution of this heat. The weather patterns and climates of earth are a response to these energy shifts. Earth’s various climates are defined by the mean annual temperature and the mean annual precipitation. Toby R. Stewart and Dion Stewart See also: Biodiversity; Biomes: determinants; Biomes: types; Ecology: definition; Ecosystems: definition and history; Ecosystems: studies; Geochemical cycles; Global warming; Greenhouse effect; Habitats and biomes; Hydrologic cycle; Ozone depletion and ozone holes; Rain forests and the atmosphere. 70
Biosphere concept Sources for Further Study McNeely, Jeffrey A. Conserving the World’s Biological Diversity. Washington, D.C.: International Union for Conservation of Nature and Natural Resources, 1990. Smith, Vaclav. Cycles of Life: Civilization and the Biosphere. New York: W. H. Freeman, 2000. Vernadskii, V. I. The Biosphere. Translated by Mark A. S. McMenamin. New York: Copernicus, 1998. Weiner, Jonathon. The Next One Hundred Years: Shaping the Fate of Our Living Earth. New York: Bantam Books, 1991. Wilson, Edward O., ed. Biodiversity. Washington, D.C.: National Academy Press, 1988.
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CAMOUFLAGE Type of ecology: Physiological ecology Both predatory and prey species use camouflage to minimize the chance that their presence will be detected. Although camouflage is often thought of as being exclusively a visual phenomenon, for it to work, it must occur in all sensory modalities.
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rypsis is the art of remaining hidden. Camouflage is usually thought of as color matching: a green aphid, for example, is likely to go unnoticed while feeding on a green leaf. Background matching, or cryptic coloration, is indeed the most common form of camouflage, but most crypsis involves far more than matching a single color. Very small animals such as aphids can get away with using a single camouflage color because they are much smaller than the plants on which they spend their entire lives: They need to match only one thing. Most animals, however—even most insects—are significantly larger than aphids and are likely to spend time in more than one place. Their camouflage must be more sophisticated if it is to be useful. Disruptive Coloration If a large organism is to remain undetected, it must be camouflaged with respect to an entire scene. One way to do this is with the use of disruptive coloration, that is, the use of stripes, spots, or patches of color for camouflage. Disruptive coloration can involve large color patches, as on a pinto pony, a tabby cat, or a diamond-backed rattlesnake, or may involve tiny variations of color on each scale, feather, or hair. Many brownish or grayish mammals actually have what is called agouti coloring, with three different colors appearing on each hair. The irregular borders of multiple color patches on an animal’s body help to obscure its outline against an irregular and multicolored background, just like the blotchy greens and browns on military uniforms. An animal that has a mix of browns in its fur, feathers, skin or scales, for example, will blend into a forest or even an open desert or tundra much better than one that is a single solid color. Even the black-and-white stripes of zebras, which seem so striking, act as a form of disruptive coloration: From far away, and especially to an animal such as a lion, which does not have good color vision, the stripes of zebras help them blend into the tall, wavy grasses of the savannah. Countershading is another form of crypsis, involving differently colored patches. Countershaded animals appear dark when viewed from 72
Camouflage above and light when viewed from underneath. Animals with countershading include orca whales with their black backs and white bellies, penguins, blue jays, bullfrogs, and weasels. Countershading works and is found as camouflage in so many kinds of animals because no matter where one lives—a desert, a forest, a meadow, or an ocean—the sun shines from above. When looking up toward the sun and sky, dark things stand out and light colors blend in; when looking down toward the ground or the ocean floor, light colors stand out and dark colors blend in. Predators that are countershaded can thus approach their prey with equal stealth from either above or below; likewise, prey species that are countershaded will be equally hard to find whether a predator is searching from on high or from underneath. Countershading and other forms of disruptive coloration can occur in the same organism, so that dark spots, blotches, or stripes appear on top while paler ones appear below. Mimicry Another way of remaining undetected in a complex scene is by using protective mimicry, the ability to mimic an inanimate object in both color and form. Some insects look like thorns on plant stems; others look like leaves or twigs or flowers. Some insects, frogs, and fish look like rocks, lichens, or corals. Sea lions, sea dragons, and even eels can look like floating kelp or other forms of seaweed.
Zebras’ stripes not only help them blend into their grassland habitats but also make it difficult for predators to pick out a single individual for attack. (Digital Stock) 73
Camouflage Some animals may not look much like the objects around them but will disguise themselves by attaching pieces of plants or sand or other debris to their body. Some caterpillars use silk to tie bits of flowers and leaves to their bodies; others use saliva as a glue. Some crabs glue broken bits of shell and coral to their exoskeletons. By using local materials to camouflage itself, an animal can ensure that it matches the background and can even change its disguise as it moves from one area into another. Transparency Being transparent is another way to match whatever background happens to be present. Many marine invertebrates such as worms, jellyfish, and shrimp, are completely transparent. Complete transparency is less common among land animals, but some land invertebrates have transparent body parts, such as their wings, allowing them to break up the outline of their body and blend into whatever happens to be in the immediate background. Predation and Prey Behavior is an important factor in the success or lack of success of any form of crypsis. For example, not even disruptive camouflage can hide something that is moving quickly with respect to its background. Predatory species that rely on speed or stamina to outrun, outswim, or outfly their prey therefore have little use for camouflage. On the other hand, so-called sitand-wait predators (such as boa constrictors or praying mantises) must be virtually perfectly camouflaged in order to remain undetected while their prey approach to within grabbing distance. In between are the stealth hunters, which sneak up on their prey before making a final high-speed attack; such animals must be camouflaged and slow-moving when out of attack range but do not have to be camouflaged or slow when at close range. Like predators, prey species that rely on rapid escape maneuvers do not often exhibit camouflage coloration, while prey species that cannot rely on efficient escape tactics must, instead, rely on camouflage to avoid being seen in the first place. Prey species that can move quickly but not as quickly as their predators must detect their predators before their predators detect them, and then they must remain absolutely still until the danger is passed. Life Stages Some species use different strategies as they go through different stages in life. In many altricial species (species with dependent young that require extended parental care of the offspring), the eggs and/or young are camouflaged, even though the adults are not; the temporary spots on deer 74
Camouflage fawns and mountain lion cubs are examples. In other species, nesting or brooding females may be camouflaged while the adult males retain their gaudy plumage or attention-getting behaviors; the changing seasonal patterns of color and behavior of ducks and songbirds provide examples here. Some species may be toxic and gaudy during one stage of life, yet tasty and cryptic during another. Multisensory Camouflage Finally, although camouflage is usually thought of as a visual phenomenon, crypsis is important in every sensory modality. If a prey animal is virtually invisible to its predators but puts out a sound, a scent, or a vibration that makes it easy to locate, visual crypsis alone is useless. For successful protection, prey species must be cryptic in whatever sensory modalities their predators use for hunting. Likewise, for successful hunting, predatory species must be cryptic in whatever sensory modalities their prey use to detect danger. For most species of both predator and prey, this means being camouflaged or blending into the background in several sensory modalities all at once. Linda Mealey See also: Adaptations and their mechanisms; Bioluminescence; Defense mechanisms; Displays; Metabolites; Mimicry; Pollination. Sources for Further Study Dettner, K., and C. Liepert “Chemical Mimicry and Camouflage.” Annual Review of Entomology 39 (1994): 129-154. Ortolani, Alessia. “Spots, Stripes, Tail Tips, and Dark Eyes: Predicting the Function of Carnivore Colour Patterns Using the Comparative Method.” Biological Journal of the Linnean Society 67, no. 4 (August, 1999): 433-476. Owen, Denis. Camouflage and Mimicry. Chicago: University of Chicago Press, 1980. Ramachandran, V. S., et.al. “Rapid Adaptive Camouflage in Tropical Flounders.” Nature 379, no. 6568 (1996): 815-818. Wicksten, Mary K. “Decorator Crabs.” Scientific American 242, no. 2 (February, 1980): 146-154.
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CHAPARRAL Types of ecology: Biomes; Ecosystem ecology Chaparral is the name of a major ecosystem (or biome) found in areas with moist, cool to cold winters and long, dry hot summers (Mediterranean climate).
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haparral ecosystems with different names occur in the Mediterranean, South Africa, Chile, Australia, and Mexico. The word “chaparral” is a colloquial adaptation of the original Mexican name, chaparro. Chaparral communities in other parts of the world have the same basic characteristics and very similar adaptations; this article focuses on the chaparral of California and the American Southwest. Chaparral is an interesting and unique ecosystem. It is an elfin (stunted) forest dependent on a fire ecology, and its adaptations to a harsh and variable climate are remarkable. The chaparral’s geology, latitude, altitude, and climate are all related and have played a role in its formation.
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Chaparral Location In California, the chaparral is located mainly along the central and southern coastal areas, primarily between elevations of 500 and 2,500 feet. It is also found in some areas of the Sierra Nevada foothills, one hundred miles or more inland, and in the lower elevations of some other interior mountains. The geology of most of the areas where this ecosystem occurs is believed to have started with massive upheavals from half a million to ten thousand years ago. The most common substrate was granite. Relentless disintegration resulted in rocky and sandy debris which would allow increasing amounts of plant life to grow. As the organic matter became more abundant, its debris (leaves, twigs, and decaying dead plants) became more and more mixed into the materials of the granite decomposition. This resulted in a rich, sandy loam. Chaparral Flora Because of the cool, moist winters and dry, hot summers, plants evolved to survive these marked changes. In most of the chaparral, there are quite extreme diurnal temperature changes, with fluctuations of fifty to sixty degrees or more. Compounding these harsh conditions are frequent strong, dry winds, often reaching forty miles per hour. The plants that have become the residents of the chaparral are mainly shrubby, small-leaved evergreens with leathery, thick stems. Shrubs predominate, but there are also small trees and in many areas abundant wildflowers. All plants are adapted to conserve water. There is little humus in the soil, which is relatively nutrient-poor. The sandy nature of the soil and the variable periods of dry and sudden rain can cause a quick runoff. The predominant plants are between three and nine feet in height, with some trees being taller. They hug close to the ground to provide shade. The ratio of the surface area of the leaves and stems to their body mass is reduced, and they tend to have thick, heat-resistant surfaces. Some of the plants are capable of turning their leaves so the edges face the sun, which cuts down the warming effect on their surfaces. All these mechanisms greatly reduce evaporative water loss. Most of the bushes and trees also have unusually long tap roots. A three-foot plant might have a tap root that goes ten or more feet below the surface, enabling it to get more water and nutrients. The most common plant in the chaparral is the greasewood-chamise bush (Adenostoma fasciculatum). Others that predominate are the christmasberry-toyon bush (Photinia arbutifolia), the scrub oak (Quercus dumosa), the yucca (Yucca whipplei), and the hoary manzanita (Arctostaphylos canescens). 77
Chaparral The chamise is characterized by numerous small, club-shaped leaves with a waxy substance that protects them from drying. When there is a fire, the chamise burns with an intense heat and creates a very black smoke (hence the name “greasewood”). The Role of Fire The role of fire in the maintenance and regeneration of the chaparral is of paramount importance. The hot, dry summer weather, often fanned by winds, makes the chaparral very prone to fires. Because of the high fuel content in the dense plants, with their waxy and oily components, these fires are very intense and can spread rapidly. Fire is necessary to clear excess growth and allow new seeds to germinate. Indeed, several of the key species need fire to release their seeds or they will not germinate. The amount and distribution of the canopy fuel can have a marked effect on regrowth and even spatial variation. Naturally recurring fires are usually good for germination. However, unusually intense fires, often from years of fire suppression, may do harm by damaging the plants severely. In much of the chaparral, human interference has caused this suppression, creating a difficult paradox, since many people now reside in the chaparral and chaparral fires can spread very rapidly, especially with strong winds. Conversely, in some areas where fire has been controlled, the chaparral has been retreating. A good example of this retreat has occurred on the southern slopes of Mount Tamalpais, a mountain just north of San Francisco. Chaparral Fauna A wide variety of reptiles, birds, and mammals make the chaparral their home. They have developed adaptations to survive and thrive in this harsh environment. Several species of skinks, lizards, and a variety of snakes, including gopher snakes, the California king snake, and both the red diamond and western rattlesnakes are residents. There are dozens of birds, from several species of hummingbirds to the large birds: the turkey vulture, barn owl, roadrunner, and golden eagle. There are many species of rodents, including kangaroo rats, chipmunks and gophers. The variety of medium to large mammals of common interest is impressive and includes the coyote, gray fox, badger, lynx, bobcat, mountain lion, and mule deer. C. Mervyn Rasmussen See also: Biomes: determinants; Biomes: types; Deserts; Forests; Grasslands and prairies; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; 78
Chaparral Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes; Wetlands. Sources for Further Study Brown, O. E., and R. A. Minnich. “Fire and Changes in the Creosote Bush Scrub of the Western Sonoran Desert, California.” American Midland Naturalist 116, no. 2 (1986): 411-422. Collis, P. H., ed. Dictionary of Ecology and the Environment. 3d ed. Chicago: Fitzroy Dearborn, 1998. Head, W. S. The California Chaparral: An Elfin Forest. 1972. Reprint. Happy Camp, Calif.: Naturegraph, 1998. Jasson-Holt, Sophie. Unfold the Chaparral. San Francisco: San Francisco State University Chapbook, 1996. Odion, Dennis C., and Frank W. Davis. “Fire, Soil Heating, and the Formation of Vegetation Patterns in Chaparral.” Ecological Monographs 70, no. 1 (2000): 149-169.
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CLINES, HYBRID ZONES, AND INTROGRESSION Types of ecology: Population ecology; Speciation A cline is a genetic variation in the characteristics of populations of the same species that results from a variation in the geographical area that it occupies. Hybrid zones are areas with populations of a species composed of individuals with characteristics of one or more species that have interbred. Introgression is speciation that occurs when the genes of one species are incorporated into the gene pool of another as the result of successful hybridization.
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ene flow among populations tends to increase the similarity of characters among all the demes (local populations) of a species. Natural selection has the opposite effect: It tends to make every deme uniquely specialized for its specific habitat. Clines are one possible result of these two opposing forces; a cline is a phenomenon in which a genetic variation occurs that is caused by a difference in geographical habitat. Each species is continuously adjusting its gene pool to ensure that the species survives in the face of an environment that is continuously changing. Comparing the characteristics of the demes of a single species usually will reveal that they are not identical. The greater the distance between the demes, the greater the differences between them will be. The grass frogs in Wisconsin differ from the grass frogs in Texas more than they differ from those in Michigan. On the average, the song sparrows of Alaska are heavier and have darker coloration than those in California. These phenomena, in which a single character shows a gradient of change across a geographical area, are called clines. North-South Clines Many birds and mammals exhibit north-south clines in average body size and weight, being larger and heavier in the colder climate farther north and smaller and lighter in warmer climates to the south. In the same way, many mammalian species show north-south clines in the sizes of body extremities such as tails and ears, these parts being smaller in northern demes and larger in southern demes. Increase in average body size with increasing cold is such a common observation that it has been codified as Bergmann’s rule. The tendency toward shorter and smaller extremities in colder climates and longer and larger ones in warmer climates is known as 80
Clines, hybrid zones, and introgression Allen’s rule. The trend toward lighter colors in southern climates and darker shades in northern climates has been designated Gloger’s rule. The zebra, for example, shows a cline in the amount of striping on the legs. The northernmost races are fully leg-striped, and the striping diminishes toward the southern latitudes of Africa; this appears to be an example of Gloger’s rule. Another example of a cline, which does not fit any of the biogeographical rules mentioned, is the number of eggs laid per reproductive effort (the clutch size) by the European robin: This number is larger in northern Europe than it is for the same species in northern Africa. Other birds, such as the crossbill and raven, which have wide distribution in the Holarctic realm, show a clutch-size cline that reveals a larger clutch size in lower latitudes. The manifestation of such clines in clutch size is a consequence of the interplay of two different reproductive strategies that may give a species a competitive advantage in a given environment. The stability of the environment is what elicits the appropriate strategy. In unstable environments, such as those in the temperate zone, where there may occur sudden variations in weather and extremes between seasons, a species needs to reproduce rapidly and build its numbers quickly to take advantage of the favorable warm seasons to ensure survival of the species during the harsh, unfavorable conditions of winter. This strategy is known as r strategy (r stands for the rate of increase). In the tropics, the climate is more equable throughout the year. The environment, however, can only support a limited number of individuals throughout the year. This number is called the carrying capacity. When carrying capacity is reached, competition for resources increases, and the reproductive effort is reduced to maintain the population at the carrying capacity. This is called K strategy, with K standing for carrying capacity. In birds, clutch size tends to be inversely proportional to the climatic stability of the habitat: In temperate climates, more energy is directed to increase the reproductive rate. In the tropics, the carrying capacity is more important, resulting in a reduced reproductive rate. In the apparent contradiction of the crossbills and ravens, it may be the harshness of the habitat at higher latitudes that limits the resources available for successfully fledging a larger number of young. Frog Clines The cline exhibited by the common grass frog is one of the best known of all the examples of this phenomenon. It has the greatest range, occupies the widest array of habitats, and possesses the greatest amount of morphological variability of any frog species. This variability and adaptation are not 81
Clines, hybrid zones, and introgression haphazard. The species includes a number of temperature-adapted demes, varying from north to south. These adaptations involve the departmental processes from egg to larva. The northernmost demes have larger eggs that develop faster at lower temperatures than those of the southernmost demes. These physiological differences are so marked that matings between individuals from the extreme ends of the cline result in abnormal larvae or offspring that are inviable (cannot survive) even at a temperature that is average for the cline region. Leopard frogs from Vermont can interbreed readily with ones from New Jersey. Those in New Jersey can hybridize readily with those in the Carolinas, and those in turn with those in Georgia. Yet, hybrids of Vermont demes and Florida demes are usually abnormal and inviable. Thus, it appears that the Vermont gene pool has been selected for a rate of development that corresponds to a lower environmental temperature. The gene pool of the Florida race has a rate of development that is slower at a higher average temperature. The mixture of the genetic makeup of the northern and southern races is so discordant that it fails to regulate characteristic rates of development at any sublethal temperature, so the resulting embryo dies before it becomes a tadpole. There are two primary reasons why characters within a species may show clinal variation. First, if gene flow occurs between nearby demes of a population, the gene pools of demes that are close to one another will share more alleles than the gene pools of populations that are far apart. Second, environmental factors, such as annual climate, vary along gradients that can be defined longitudinally, latitudinally, or altitudinally. Because these environmental components act as selective pressures, the phenotypic characters that are best adapted to such pressures will also vary in a gradient. Hybridization, Hybrid Swards, Introgressive Demes Hybridization is the process whereby individuals of different species produce offspring. A hybrid zone is an area occupied by interbreeding species. Partial species can and do develop on the way to becoming new species as products of hybridization. Natural hybridization and gene flow can take place between biological species no matter how sterile most of the hybrid offspring may be. As long as the mechanisms that prevent free exchange of genes between populations can be penetrated, there is the potential for a new species to develop. Because the parental species has a tendency to be replaced by the hybrid types if natural selection favors them, hybridization can be a threat to the integrity of the parental species as a distinct entity. Hybridization between different species leads to various and unpredictable results. Any time that hybridization occurs, the isolation mecha82
Clines, hybrid zones, and introgression nisms of populations are overcome, forming bridging populations. Such connecting demes of hybrid origin fall into one of two general categories: hybrid swarms or introgressive demes. The formation of these types of demes reverses the process of speciation and changes the formerly distinct species into a complex mixture of highly variable individuals that are the products of the segregation and independent assortment of traits. This is the primary advantage of sexual reproduction: to produce variation in the population that is acted upon by natural selection over time. It cannot be overemphasized that hybrid swarms and introgressive demes are highly variable. The environmental conditions that contour animal communities have endured for a very long time. In long-lived communities, every available niche has been filled by well-adapted species. When populations with new adaptive characteristics occur, there is no niche for them to occupy, so they usually die out. In contrast, when such communities are disturbed, the parity among their component species is upset, which gives new variants an opportunity to become established. Hybrid swarms can be observed in nature by the careful investigator. The hybrid swarm forms in a disturbed habitat, where hybrid individuals backcross with the parental types to form a third population, which result from the migration of the genes of one population into the other. Such a population is designated an introgressive population. The progeny of such populations resemble the parent species, but the variations are in the direction of one parental species or the other. If introgression is extensive enough, it may eradicate the morphological and ecological distinctions of the parental types. The parental types become rarer and rarer, until they are no longer the representatives of the species. There appear to be three reasons that first-generation hybrids occurring naturally are more likely to form offspring by backcrossing to one of the parental species than by mating with each other. Primarily, the hybrids are always rarer than the parents. Second, the parental individuals are so much more fertile than the hybrids that many more parental gametes are available than hybrid ones. Finally, backcross progeny, since they contain primarily parentally derived genes, are more likely to be well adapted to the habitat in which they originated than are the purely hybrid individuals. Introgression Thus, the most likely result of hybridization is backcrossing to one of the parental species. Genotypes containing the most parental genes usually have the selective advantage, and the fact that they contain a few chromosomal segments from another species gives them unique characteristics 83
Clines, hybrid zones, and introgression that may also be advantageous. This sequence of events—hybridization, backcrossing, and stabilization of backcross types—is known as introgression. Hybrid swarms are interesting phenomena, but they are unlikely to be of evolutionary significance except through introgression. There are many examples of introgression among plants, but examples of introgression in animals are not common. Those that have been demonstrated are usually associated with the domestication of livestock. In the Himalayan region of Asia, there exists a relative of cattle, the yak, which is also domesticated. Many of the herds of cattle found along the western edge of the Himalayas, in central Asia, contain characteristics that clearly are derived from the gene pool of the yak. Many of these characteristics are manifested as adaptations to the harsh climatic conditions in this region. In western Canada, there has been a modest introgression of the genes of the American bison into the gene pool of strains of range cattle. The bisonlike characters incorporated into beef cattle created a new breed called the beefalo, which exhibits such characteristics as greater body musculature, lower fat content of the flesh, and great efficiency in the utilization of range forage. A beefalo steer is ready for market in only eight months, while the same live weight is not obtained in the standard beef breed until eighteen months. These examples serve to illustrate the concept that, as an evolutionary force, introgression is rather insignificant in natural biomes. It is almost always in the wake of human activity or the activities of their domesticated animals that the process of introgression can and does result in new combinations of gene pools from different species. Edward N. Nelson See also: Adaptive radiation; Biodiversity; Biogeography; Convergence and divergence; Demographics; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Isolating mechanisms; Nonrandom mating, genetic drift, and mutation; Population analysis; Population fluctuations; Population genetics; Population growth; Punctuated equilibrium vs. gradualism; Reproductive strategies; Speciation. Sources for Further Study Anderson, Edgar. Introgressive Hybridization. New York: Hafner Press, 1968. Arnold, M. L. Natural Hybridization and Evolution. New York: Oxford University Press, 1997. Briggs, D., and S. M. Walters. Plant Variation and Evolution. New York: Cambridge University Press, 1997. 84
Clines, hybrid zones, and introgression Dobzhansky, Theodosius G. Genetics and the Origin of Species. 1951. 3d rev. ed. Reprint. New York: Columbia University Press, 1982. Endler, John A. Geographic Variation: Speciation and Clines. Princeton, N.J.: Princeton University Press, 1977. Grant, V. The Origin of Adaptations. New York: Columbia University Press, 1963. Kimbel, William H., and Lawrence B. Martin, eds. Species, Species Concepts, and Primate Evolution. New York: Plenum Press, 1993. Ridley, M. Evolution. Boston: Blackwell Scientific Publications, 1993. Roughgarden, Jonathan. Theory of Population Genetics and Evolutionary Ecology: An Introduction. Upper Saddle River, N.J.: Prentice Hall, 1996. Stebbins, G. L., Jr. Variation and Evolution in Plants. New York: Columbia University Press, 1950.
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COEVOLUTION Types of ecology: Community ecology; Evolutionary ecology Coevolution is the interactive evolution of two or more species that results in a mutualistic or antagonistic relationship.
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hen two or more different species evolve in a way that affects one another’s evolution, coevolution is taking place. This interactive type of evolution is characterized by the fact that the participant life-forms are acting as a strong selective pressure upon one another over a period of time. The coevolution of plants and animals, whether animals are considered strictly in their plant-eating role or also as pollinators, is abundantly represented in every terrestrial ecosystem throughout the world where flora has established itself. Moreover, the overall history of some of the multitude of present and past plant and animal relationships is displayed (although fragmentally) in the fossil record found in the earth’s crust. Beginnings The most common coevolutionary relationships between plants and animals concern plants as a food source. Microscopic, unicellular plants were the earth’s first autotrophs (organisms that can produce their own organic energy through photosynthesis, that is, from basic chemical ingredients derived from the environment). In conjunction with the appearance of autotrophs, microscopic, unicellular heterotrophs (organisms, such as animals, that must derive food from other sources, such as autotrophs) evolved to exploit the autotrophs. Sometime during the later part of the Mesozoic era, angiosperms, the flowering plants, evolved and replaced most of the previously dominant land plants, such as the gymnosperms and the ferns. New species of herbivores evolved to exploit these new food sources. At some point, probably during the Cretaceous period of the late Mesozoic era, animals became unintentional aids in the angiosperm pollination process. As this coevolution proceeded, the first animal pollinators became more and more indispensable as partners to the plants. Eventually, highly coevolved plants and animals developed relationships of extreme interdependence, exemplified by the honeybees and their coevolved flowers. This angiosperm-insect relationship is thought to have arisen in the Mesozoic era by way of beetle predation, possibly on early, magnolia-like angiosperms. The fossil record gives some support to this 86
Coevolution theory. Whatever the exact route along which plant-animal pollination partnerships coevolved, the end result was a number of plant and animal species that gained mutual benefit from the new type of relationship. Coevolutionary Relationships Coevolved relationships include an immense number of relationships between plants and animals, and even between plants and other plants. Among these coevolved situations can be found commensalisms, in which different species have coevolved to live intimately with one another without injury to any participant, and symbioses, in which species have coevolved to literally “live together.” Such intertwined relationships can take the form of mutualism, in which neither partner is harmed and indeed one or both benefit—as in the relationships between fungi and algae in lichens, fungi and roots in mycorrhizae, and ants and acacia trees in a symbiotic mutualism in which the ants protect the acacias from herbivores. In parasitism, however, one partner benefits at the expense of the other; a classic example is the relationship between the mistletoe parasite and the oak tree. Another coevolu-
A nonsymbiotic mutualism has coevolved between this hummingbird and the funnel shape of the flower from which it extracts nectar with its long, pointed bill. The plant has achieved greater evolutionary fitness through its ability to attract the bird, which helps the plant propagate by facilitating pollination and seed dispersal. At the same time, the hummingbird benefits from a source of nutrition tailored to its anatomy and protected from competitors. (Corbis) 87
Coevolution tionary relationship, predation, is restricted primarily to animal-animal relationships (vertebrate carnivores eating other animals, most obviously), although some plants, such as Venus’s flytrap, mimic predation in having evolved means of trapping and ingesting insects as a source of food. Some highly evolved fungi, such as the oyster mushroom, have evolved anesthetizing compounds and other means of trapping protozoa, nematodes, and other small animals. One of the most obvious and complex coevolutionary relationships are the mutualisms that have evolved between plants bearing fleshy fruits and vertebrate animals, which serve to disperse the seeds in these fruits. Over time, plants that produce these fruits have benefited from natural selection because their seeds have enjoyed a high degree of survival and germination: Animals eat the fruits, whose seeds are passed through their digestive systems (or regurgitated to feed offspring) unharmed; at times the seeds are even encouraged toward germination as digestion helps break down the seed coat. Furthermore, dispersal through the animals’ mobility allows the seeds to enjoy more widely distributed propagation. The coevolutionary process works on the animals as well: Birds and animals that eat the fruits enjoy a higher degree of survival, and so natural selection favors both fleshy-fruit-producing plants and fleshy-fruit-eating animals. Similar selection has favored the coevolution of flowers with colors and smells that attract pollinators such as bees. Eventually some plant-animal mutualisms became so intertwined that one or both participants reached a point at which they could not exist without the aid of the other. These obligatory mutualisms ultimately involve other types of animal partners besides insects. Vertebrate partners such as birds, reptiles, and mammals became involved in mutualisms with plants. In the southwestern United States, for example, bats and the agave and saguaro cactus have a special coevolutionary relationship: The bats, nectar drinkers and pollen eaters, have evolved specialized feeding structures such as erectile tongues similar to those found among moths and other insects with similar lifestyles. In turn, angiosperms coevolutionarily involved with bats have developed such specializations as bat-attractive scents, flower structures that match the bats’ feeding habits and minimize the chance of injuring the animals, and petal openings timed to the nocturnal activity of bats. Defense Mechanisms Coevolution is manifested in defense mechanisms as well as attractants: Botanical structures and chemicals (secondary metabolites) have evolved to discourage or to prevent the attention of plant eaters. These include the 88
Coevolution development of spines, barbs, thorns, bristles, and hooks on plant leaves, stems, and trunk surfaces. Cacti, hollies, and rose bushes illustrate this form of plant strategy. Some plants produce chemical compounds that are bitter to the taste or poisonous. Plants that contain organic tannins, such as trees and shrubs, can partially inactivate animals’ digestive juices and create cumulative toxic effects that have been correlated with cancer. Grasses with a high silica content act to wear down the teeth of plant eaters. Animals have counteradapted to these defensive innovations by evolving a higher degree of resistance to plant toxins or by developing more efficient and tougher teeth with features such as harder enamel surfaces or the capacity of grinding with batteries of teeth. Frederick M. Surowiec, updated by Christina J. Moose See also: Adaptations and their mechanisms; Adaptive radiation; Colonization of the land; Convergence and divergence; Defense mechanisms; Evolution: definition and theories; Evolution of plants and climates; Grazing and overgrazing; Metabolites; Natural selection; Paleoecology; Pollination; Symbiosis. Sources for Further Study Bakker, Robert T. The Dinosaur Heresies. Reprint. Secaucus, N.J.: Citadel, 2001. Barth, Friedrich G. Insects and Flowers: The Biology of a Partnership. Translated by M. A. Biederman-Thorson. Princeton, N.J.: Princeton University Press, 1991. Gilbert, Lawrence E., and Peter H. Raven, eds. Coevolution of Animals and Plants. Austin: University of Texas Press, 1980. Gould, Stephen Jay. The Panda’s Thumb. Reprint. New York: W. W. Norton, 1992. Grant, Susan. Beauty and the Beast: The Coevolution of Plants and Animals. New York: Charles Scribner’s Sons, 1984. Hughes, Norman F. Paleobiology of Angiosperm Origins. Reprint. New York: Cambridge University Press, 1994. Thompson, John N. The Coevolutionary Process. Chicago: University of Chicago Press, 1994.
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COLONIZATION OF THE LAND Types of ecology: Evolutionary ecology; Paleoecology The advent of animals and plants on land during the Ordovician period added new complexity to preexisting ecosystems and paved the way for land ecosystems. The newly increased mass of vegetation on land served to stabilize soils against erosion and promoted the weathering of their nutrient minerals. Arthropods, too, found a place in this early ecosystem of nonvascular plants on land. The appearance of animals and plants on land by the Middle Ordovician period, some 450 million years ago, was a major event in the evolution of terrestrial ecosystems. Nevertheless, they probably were not the earth’s first inhabitants; there is a fossil record of blue-green algae and other microscopic life well back into Precambrian time, as much as 3.5 billion years ago. Indeed, it is doubtful that plants and animals visible to the naked eye could have lived on land without preexisting microbial ecosystems, which served to stabilize minerals in soils, to decompose and circulate organic matter of dead organisms, and to oxygenate the atmosphere by photosynthesis. The increased mass of more complex animals and plants on land during Ordovician time further stabilized soils, invigorated the recycling of organic matter, and boosted atmospheric oxygenation. In addition, large plants provided greater depth and structure to terrestrial ecosystems than was possible with microbes and so may have promoted photosynthetic efficiency, biological diversity, and perhaps also resistance to disturbance by floods and storms. This self-reinforcing boost to terrestrial productivity firmly established life on land. Invasion from the Sea Because there are marine fossils of plants and animals visible to the naked eye in Precambrian rocks (at least 600 million years old), it has commonly been assumed that the earliest creatures on land during the Ordovician and Silurian periods invaded from the sea. Reasons advanced to explain why the land was unavailable for marine creatures for more than 200 million years include the lack of available oxygen, the poverty of terrestrial microbial photosynthetic productivity, and an unpredictable land surface of flash floods and erosional badlands. This view of an invasion from the sea has been used to explain the origins of earliest land animals, which probably were arthropods, such as millipedes and spiders. A tremendous 90
Colonization of the land variety of fossil arthropods have been found in Cambrian, Ordovician, and Silurian deposits of shallow seas and estuaries. Like modern marine crabs, these creatures may have ventured out to a limited extent on land, and some may have become more fully adapted to more difficult conditions there. The external skeletons of arthropods, important for defense in the sea, also are effective for support, movement, and preventing desiccation on land. On the other hand, millipedes and spiders are not very closely related either to any known fossil or to living aquatic arthropods. A reassessment of the earliest fossil scorpions, formerly regarded as possible early land animals, has shown that they had a breathing apparatus that would have been effective only in water. Substantial evolution on land must have occurred to produce the earliest spiders and millipedes, perhaps from microscopic early microbial feeders that have left no fossil record. Immigrant vs. Indigenous Evolution The idea of invasion of the land by marine and freshwater algae is supported to some extent by the close biochemical similarities between modern land plants and charophytes (a kind of pond weed commonly called stonewort because of its calcified egg cells). Charophytes, however, are very different from land plants, and it is unlikely that such soft-bodied aquatic algae in the geological past were any more successful in colonizing the land than are the mounds of rotting seaweed now thrown up on beaches by storms. Land plants differ from stoneworts and seaweeds in many ways: They have a waxy and proteinaceous outer coating (cuticle) to prevent desiccation and to allow the plant body to remain turgid through internal water pressure; they have small openings (stomates) surrounded by cells that can open and close the opening in order to control loss of water and oxygen and intake of carbon dioxide; they have internal systems of support and water transport, which include tubular thick-walled cells (hydroids) in nonvascular plants, such as mosses and liverworts, and elongate cells with helical or banded woody thickenings (tracheids) in vascular plants; they have roots, unicellular root hairs, or rootlike organs (rhizoids) that gather water and nutrients from soil; and they have propagules (spores) protected from desiccation and abrasion by proteinaceous envelopes. To some botanists, the coordinated evolution of all these features from aquatic algae is extremely unlikely, notwithstanding the impressive diversity of algae today. This consideration, plus the simple nature of the earliest fossil land plants, has led to the argument that land plants evolved on land from microscopic algae already accustomed to such conditions. 91
Colonization of the land The Earliest Land Ecosystems While immigrant versus indigenous evolutionary origins of the earliest land creatures remains a theoretical problem, there is fossil evidence of very early land ecosystems. In Late Ordovician rocks are found the earliest spores of land plants. Most of them are smooth and closely appressed in groups of four, somewhat similar to spores of liverworts and mosses today. This is not to say that they belonged to liverworts and mosses; no clear fossils of land plants visible to the naked eye have yet been found in rocks of this age. Early moss and liverwort ancestors are found in Silurian rocks, but so are extinct nonvascular plants, such as nematophytes. These early experiments in the evolution of land plants had tissues supported by densely interwoven proteinaceous tubes. In life, they had the rubbery texture of a mushroom and a variety of bladelike and elongate forms similar to those of some living algae. Although the botanical affinities of the earliest spores of nonvascular land plants remain unclear, there is evidence that they grew in clumps. Buried soils of Late Ordovician age have been found with surficial erosion scours of the kind formed by wind around clumps of vegetation. The clumps are represented by gray spots from the reducing effect of remnant organic matter. Burrows also have been found in Late Ordovician buried soils as an indication of animals in these early land ecosystems. The fossil burrows are quite large (2 to 21 millimeters). They are similar in their clayey linings, backfill structures, and fecal pellets to the burrows of modern roundback millipedes. The buried soils are calcareous and strongly ferruginized—indications that they were nutrient-rich, periodically dry, and well drained, as are modern soils preferred by millipedes. Actual fossils of millipedes have not yet been found in rocks older than Late Silurian, so all that can be said at present is that these very early animals on land were in some ways like millipedes. Diversification of Life on Land By Silurian time (some 438 million years ago) there was a considerable diversification of life on land. Spores of fungi and of vascular land plants have been found fossilized in Early Silurian rocks. During Mid-Silurian time, there were small, leafless plants with bifurcating rhizomes and photosynthetic stems terminated by globular, spore-bearing organs. These matchstick-sized fossil plants have been called Cooksonia. Although not so well preserved as to show their water-conducting cells, they have been regarded as the earliest representatives of the extinct group of vascular plants called rhyniophytes. In Devonian rocks (some 408 million years old), some well-preserved rhyniophytes are known to have been 92
Colonization of the land true vascular plants, but there are other plants similar in general appearance that had simpler thick-walled conducting cells like those of nonvascular plants. By Devonian time, there were also vascular plants with spore-bearing organs borne above lateral branches (zosterophylls), plants with true roots and spore-bearing organs borne in clusters (trimerophytes), and spore-producing plants with woody roots and tree trunks (progymnosperms). The evolution of the earliest vascular plant cover on land, and of the first forests, involved different kinds of plants now extinct. To fossil millipedes of Silurian age were added during Devonian time spiders, centipedes, springtails (Collembola), and bristletails (Thysanura). The earliest vertebrates on land are known from bones of extinct amphibians (Ichthyostegalia) and from footprints of Devonian age, some 370 million years old. This great Silurian and Devonian evolutionary radiation promoted environmental changes similar to those initiated by the first colonization of land by plants and animals, as well as some new changes. For example, the formation of charcoal from wildfires in woodlands and the accumulation of peat in swamps were ways of burying carbon that otherwise might have decayed or digested into carbon dioxide in the atmosphere. Removal of carbon dioxide in this way allowed increased oxygenation of the atmosphere. Oxygenation was kept within bounds by increased flammability of woodlands when oxygen reached amounts much in excess of the present atmospheric level. Late Devonian ecosystems were very different from modern ones. Major ecological roles, such as insect-eating large animals on land, were still being added. More changes were to come, but the world at that time would have seemed a much more familiar place than the meadows of Cooksonia during the Silurian, the patchy cover of Ordovician nonvascular plants, and the red and green microbial earths of earlier times. Gregory J. Retallack See also: Coevolution; Convergence and divergence; Evolution: definition and theories; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Mycorrhizae; Natural selection; Paleoecology; Punctuated equilibrium vs. gradualism. Sources for Further Study Gordon, M. S., and E. C. Olson. Invasions of the Land: The Transition of Organisms from the Aquatic to Terrestrial Life. New York: Columbia University Press, 1995. 93
Colonization of the land Little, C. The Colonization of the Land. Cambridge, England: Cambridge University Press, 1983. Schopf, J. William, ed. Major Events in the History of Life. Boston: Jones and Bartlett, 1992. Schumm, Stanley A. The Fluvial System. New York: Wiley-Interscience, 1977. Stanley, Steven M. Earth and Life Through Time. 2d ed. New York: W. H. Freeman, 1989. Stebbins, G. L., and G. J. C. Hill. “Did Multicellular Plants Invade the Land?” American Naturalist 115 (1980): 342-353. Wright, V. P., and Alfred Fischer, eds. Paleosols: Their Recognition and Interpretation. Princeton, N.J.: Princeton University Press, 1986. Zimmer, Carl. At the Water’s Edge: Macroevolution and the Transformation of Life. New York: Free Press, 1998.
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COMMUNICATION Types of ecology: Behavioral ecology; Chemical ecology In animal communication, information is exchanged through signals. Such signals are vital for survival, finding mates, and rearing young.
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simple definition of animal communication is the transmission of information between animals by means of signals. Developing a more precise definition is difficult because of the broad array of behaviors that are considered messages or signals and the variety of contexts in which these behaviors may occur. Animal signals can be chemical, visual, auditory, tactile, or electrical. The primary means of communication used within a species will depend upon its sensory capacities and its ecology. Pheromones Of the modes of communication available, chemical signals, or pheromones, are assumed to have been the earliest signals used by animals. Transmission of chemical signals is not affected by darkness or by obstacles. One special advantage is that the sender of a chemical message can leave the message behind when it moves. The persistence of the signal may also be a disadvantage when it interferes with transmission of newer information. Another disadvantage is that the transmission is relatively slow. The speed at which a chemical message affects the recipient varies. Some messages have an immediate effect on the behavior of recipients. Alarm and sex-attractant pheromones of many insects, aggregation pheromones in cockroaches, or trail substances in ants are examples. Other chemical messages, primers, affect recipients more slowly, through changes in their physiology. Examples of primers include pheromones that control social structure in hive insects such as termites. Reproductive members of the colony secrete a substance that inhibits the development of reproductive capacity in other hive members. The chemicals important for controlling the hive are spread through grooming and food sharing (trophallaxis). Chemical communication is important not only among social and semisocial insects but also among animals, both vertebrate and invertebrate. Particularly common is the use of a pheromone to indicate that an animal is sexually receptive. Visual Signals Visual communication holds forth the advantage of immediate transmission. A visual signal or display is also able to encode a large amount of in95
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formation, including the location of the sender. Postures and movements of parts of an animal’s body are typical elements of visual communication. Color and timing are additional means of providing information. Some visual signals are discrete; that is, the signal shows no significant variation from performance to performance. Other displays are graded so that the information content of the signal can be varied. An example of a graded display is found in many of the threat or aggressive postures of birds. Threat postures of the chaffinch vary between low-intensity and highintensity postures. The elevation of the crest varies in ways that indicate the bird’s relative readiness for combat. The song spreads of red-winged blackbirds and cowbirds show variation in intensity. In red-winged blackbirds, the red epaulets, or shoulder patches, are exposed to heighten the effect of the display. Discrete and graded signals may be used together to increase the information provided by the signal. In zebras, ears back indicates a threat and ears up indicates greeting. The intensity of either message is shown by the degree to which the mouth is held open. A widely open mouth indicates a heightened greeting or threat. Visual displays depend upon the presence of light or the production of light. The ability to produce light, bioluminescence, is found most frequently in aquatic organisms, but its use in communication is probably best documented in fireflies, beetles belonging to the family Lampyridae. 96
Communication Firefly males advertise their presence by producing flashes of light in a species-specific pattern. Females respond with simple flashes, precisely timed, to indicate that they belong to the appropriate species. This communication system is used to advantage by females in a few predatory species of the genus Photuris. After females of predatory species have mated with males of their own species, they attract males of other species by mimicking the responses of the appropriate females. The males that are tricked are promptly eaten. The luminescence of fireflies does not attract a wide variety of nocturnal predators, because their bodies contain a chemical that makes them unpalatable. Visual displays are limited in the distance over which they can be used and are easily blocked by obstacles. Visual communication is important in primates, birds, and some insects, but can be dispensed with by many species that do not have the necessary sensory capacities. Auditory Communication The limitation of visual communication is frequently offset by the coupling of visual displays with other modes of communication. Visual displays can be coupled with auditory communication, for example. There are many advantages to using sound: It can be used in the dark, and it can go around obstacles and provide directional information. Because pitch, volume, and temporal patterns of sound can be varied, extremely complex messages can be communicated. The auditory communication of many bird species has been studied intensively. Bird vocalizations are usually classified into two groups, calls and songs. Calls are usually brief sounds, whereas songs are longer, more complex, and often more suited to transmission over distances. The call repertoire of a species serves a broad array of functions. Many young birds use both a visual signal, gaping, and calling in their food begging. Individuals that call more may receive more food. Begging calls and postures may also be used by females in some species to solicit food from mates. One call type that has been intensively studied is the alarm call. Alarm calls of many species are similar, and response is frequently interspecific (that is, interpretable by more than one species). Alarm calls are likely to be difficult to locate, a definite advantage to the individual giving the call. Calls used to gather individuals for mobbing predators are also similar in different species. Unlike alarm calls, mobbing calls provide good directional information, so that recruitment to the mobbing effort can be rapid. Call repertoires serve birds in a great variety of contexts important for survival of the individual. Song, on the other hand, most often serves a reproductive function, that of helping a male hold a territory and attract a 97
Communication mate. Songs are species-specific, like the distinctive markings of a species. In some cases, songs are more distinctive than physical appearance. The chiffchaff and willow warbler were not recognized as separate species until an English naturalist named Gilbert White discovered, by examining their distinctive songs, that they are separate. The North American wood and hermit thrushes can also be distinguished more readily by song than by appearance. Birdsong can communicate not only the species of the individual singing but also information about motivational state. Most singing is done by males during the breeding season. In many species, only the male sings. In some species, females sing as well. Their songs may be similar to the songs of the males of their species or they may be distinctive. If the songs are similar to those of the males, the female may sing songs infrequently and with less volume. In some instances, the female song serves to notify her mate of her location. An interesting phenomenon found in some species is duetting, in which the male and female develop a duet. Mates may sing in alternate and perfectly timed phrases, as is done by the African boubou shrike, Laniarius aethiopicus. An individual shrike can recall its mate by singing the entire song alone. Individuals in some bird species have a single song, and individuals of other species have repertoires of songs. Average repertoire size of the individual is characteristic of a species. Whether songs in repertoires are shared with neighbors or unique to the individual is also characteristic of a species. Sharing songs with neighbors permits song matching in countersinging. Cardinals and tufted titmice are species that frequently match songs in countersinging. Possible uses for matching are facilitating the recognition of intruders and indicating which neighbor has the attention of a singer. Some species of birds have dialects. The species-specific songs of one geographic region can be differentiated from the song of another geographic region. The development of dialects may be useful in maintaining local adaptations within a species, provided that females select mates of the same dialect as their fathers. Although auditory signals of birds have received a disproportionate share of attention in the study of animal communication, auditory communication is used by a broad spectrum of animals. Crickets have speciesspecific songs to attract females and courtship songs to encourage an approaching female. The ears of most insects can hear only one pitch, so the temporal pattern of sound pulses is the feature by which a species can be identified. Vervet monkeys use three different alarm calls, depending upon the kind of threat present; they respond to the calls appropriately by looking up, looking down, or climbing a tree, depending upon the kind of call given. 98
Communication Tactile Communication Tactile communication differs significantly from other forms of communication in that it cannot occur over a distance. This form of communication is important in many insects, equipped as they are with antennae rich in receptors. Shortly after a termite molts, for example, it strokes the end of the abdomen of another individual with its antennae and mouthparts. The individual receiving this signal responds by extruding a fluid from its hindgut. Tactile signals are frequently used in eliciting trophallaxis (food sharing) in social insects. Tactile signals are also important in the copulatory activity of a number of vertebrates. Additional channels of communication available in animals are electrical and surface vibration. Many modes of communication are used in combination with other modes. The channels used will depend in part on the sensory equipment of the species, its ecology, and the particular context. Most messages will be important either for the survival of the individual or the group or for the individual’s ability to transmit its genes to the next generation. Donna Janet Schroeder See also: Altruism; Defense mechanisms; Displays; Ethology; Hierarchies; Insect societies; Mammalian social systems; Mimicry; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study De Waal, Frans. Chimpanzee Politics: Power and Sex Among Apes. New York: Harper & Row, 1982. Goodall, Jane. In the Shadow of Man. Rev. ed. Boston: Houghton Mifflin, 2000. Gould, James L. Ethology. New York: W. W. Norton, 1982. Grier, James W. Biology of Animal Behavior. 2d ed. St. Louis: Times Mirror/ Mosby, 1992. Hart, Stephen. The Language of Animals. New York: H. Holt, 1996. Hauser, Marc D. The Evolution of Communication. Cambridge, Mass.: MIT Press, 1996. Peters, Roger. Mammalian Communication: A Behavioral Analysis of Meaning. Monterey, Calif.: Brooks/Cole, 1980. Roitblat, Herbert L., Louis M. Herman, and Paul E. Nachtigall, eds. Language and Communication: Comparative Perspectives. Hillsdale, N.J.: Lawrence Erlbaum, 1993. Wilson, Edward O. Insect Societies. Cambridge, Mass.: Harvard University Press, 1971. 99
COMMUNITIES: ECOSYSTEM INTERACTIONS Types of ecology: Community ecology; Ecosystem ecology Ecosystems are complex organizations of living and nonliving components. They are frequently named for their dominant biotic or physical features (such as marine kelp beds or coniferous forests). Communities are groups of species usually classified according to their most prominent members (such as grassland communities or shrub communities). The interactions between species and their ecosystems have lasting impacts on both.
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n an ecological sense, a community consists of all populations residing in a particular area. Examples of communities range in scale from all the trees in a given watershed, all soil microbes on an agricultural plot, or all phytoplankton in a particular harbor to all plants, animals, and microbes in vast areas, such as the Amazon River basin or the Chesapeake Bay. An ecosystem consists of the community of species as well as the environment of a given site. A forest ecosystem would include all living plants and animals, along with climate, soils, disturbance, and other abiotic (nonliving) factors. An estuarine ecosystem, likewise, would include all the living things present in addition to climate, currents, salinity, nutrients, and more. Interactions between species in communities and ecosystems range from mutually beneficial to mutually harmful. One such category of interaction is mutualism, which usually involves two species. Both species derive benefit from a mutualism. Commensalism is used to describe a situation in which one species benefits without harming the other. If the two species are neither helped nor harmed, a neutralism is said to occur, and an amensalism happens when one species is harmed while the other remains unaffected. During competition, both species involved are negatively affected. A number of terms are used to describe a relationship in which one species benefits at another’s expense, including herbivory, predation, parasitism, and pathogenicity. The choice of term more often than not depends on the relative sizes of the species involved. Competition Plants typically compete for resources, such as light, space, nutrients, and water. One way an individual may outcompete its neighbors is to outgrow 100
Communities: ecosystem interactions them, thus capturing more sunlight for itself (and thus producing more sugars and other organic molecules for itself). Another way is to be more fecund than the neighbors, flooding the surroundings with one’s progeny and thereby being more likely to occupy favorable sites for reproduction. For example, in closed forests treefall gaps are quickly filled with growth from the canopy, thus shading the ground and making it more difficult for competing seedlings and saplings to survive. Plants compete in the root zone as well, as plants with a more extensive root network can acquire more of the water and other inorganic nutrients necessary for growth and reproduction than can their competitors. In semiarid areas, for example, trees often have trouble colonizing grasslands because the extensive root systems of grasses are much more effective in capturing available rainwater. Sometimes plants resort to chemical “warfare,” known as allelopathy, in order to inhibit the growth of competitors in the surrounding area. The existence of allelopathy remains a controversial topic, and simpler explanations have been offered for many previously alleged instances of the phenomenon. Allelopathy cannot be rejected outright; however, the controversy most likely proves only that many aspects of nature cannot be pigeonholed into narrow explanations. Competition involves a cost in resources devoted to outgrowing or outreproducing the neighbors. Because of the cost, closely related, competing species will diverge in their ecological requirements. This principle is known as competitive exclusion. Mutualism, Commensalism, and Parasitism Many flowering plants could not exist without one of the most important mutualisms of all: pollination. In concept, pollination is simple: In exchange for carrying out the physical work of exchanging genetic material (in pollen form) between individual plants (thus enabling sexual reproduction), the carrier is rewarded with nutrients in the form of nectar or other materials. Many types of animals are involved in pollination: insects such as bees, flies, and beetles; birds, particularly the hummingbirds; and mammals such as bats. Another highly important mutualism is that between plant roots and fungal hyphae, or mycorrhizae. Mycorrhizae protect plant roots from pathogenic fungi and bacteria; their most important role, however, is to enhance water and nutrient uptake by the plant. In fact, regeneration of some plants is impossible in the absence of appropriate mycorrhizae. Mycorrhizae benefit, in turn, by receiving nutrients and other materials synthesized by the host plant. There are two types of mycorrhizae: ectomycor101
Communities: ecosystem interactions rhizae, whose hyphae may fill the space between plant roots but do not penetrate the roots themselves; and vesicular-arbuscular mycorrhizae, whose hyphae penetrate and develop within root cells. Few people can envision a swamp in the southeastern United States without thinking of bald cypress trees (Taxodium distichum) draped in ethereal nets of Spanish moss (Tillandsia usneoides), which is actually not a moss but a flowering plant in the monocot family Bromeliaceae. Tillandsia is an epiphyte, a plant that grows on the stems and branches of a tree. Epiphytism is one of the most common examples of a commensalism, in which one organism, for instance the epiphyte, benefits without any demonstrable cost to the other, in this case the host tree. Epiphytes are common in tropical rain forests and include orchids, bromeliads, cacti, and ferns. In temperate regions more primitive plants, such as lichens, are more likely to become epiphytes. Not all epiphytes are commensal, however. In the tropics, strangler figs, such as Ficus or Clusia, begin life as epiphytes but send down roots that in time completely encircle and kill the host. Mistletoes, such as Phoradendron or Arceuthobium, may draw off the photosynthetic production of the host, thus severely depleting its resources. Herbivory and Pathogenicity Plants, because of their ability to harvest light energy from the sun to produce the organic nutrients and building blocks necessary for life, are the primary producers of most of the earth’s ecosystems. Thus, they face an onslaught of macroscopic and microscopic consumers. If macroscopic, the consumers are generally regarded as herbivores (plant-eating animals); if microscopic, they are pathogens. Either way, herbivores and pathogens generally devour the tissues of the host. Plants have evolved a number of defense mechanisms in response to pressure from herbivores and pathogens. Some responses may be mechanical. For example, trees on an African savanna may evolve greater height to escape grazing pressures from large herbivores, but some large herbivores, specifically giraffes, may evolve to grow to greater heights as well. Plants may encase themselves in nearly indestructible outer coatings or arm themselves with spines in order to discourage grazers. Other responses may be chemical. Cellulose, one of the important chemical components of plant tissues such as wood, is virtually indigestible—unless the herbivore itself hosts a bacterial symbiont in its stomach that can manage the job of breaking down cellulose. Other chemicals, such as phenols and tannins—the class of compounds that gives tea its brown color—are likewise indigestible, thus discouraging feeding by insects. 102
Communities: ecosystem interactions Plants produce a wide range of toxins, such as alkaloids, which poison or kill herbivores. A number of hallucinogenic drugs are made from plant alkaloids. Phytoalexins are another group of defensive compounds produced by plants in response to bacterial and fungal pathogens. Substances present in the cell walls of bacteria and fungi are released via the action of plant enzymes and spread throughout the plant. The bacterial and fungal substances function as hormones to stimulate, or elicit, phytoalexin production. Hence, these substances are referred to as elicitors. The phytoalexins act as antibiotics, killing the infective agents. Tannins, phenols, and other compounds also serve to defend against pathogen attack. David M. Lawrence See also: Allelopathy; Animal-plant interactions; Biodiversity; Biogeography; Biological invasions; Coevolution; Communities: structure; Competition; Defense mechanisms; Food chains and webs; Lichens; Metabolites; Mycorrhizae; Pollination; Predation; Speciation; Succession; Symbiosis; Trophic levels and ecological niches. Sources for Further Study Barbour, Michael G., et al. Terrestrial Plant Ecology. 3d ed. Menlo Park, Calif.: Benjamin Cummings, 1999. Barnes, Burton V., Donald R. Zak, Shirley R. Denton, and Stephen H. Spurr. Forest Ecology. 4th ed. New York: John Wiley & Sons, 1998. Mitch, William J., and James G. Gosselink. Wetlands. 3d ed. New York: John Wiley & Sons, 2000. Morin, Peter J. Community Ecology. Oxford, England: Blackwell Science, 1999.
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COMMUNITIES: STRUCTURE Type of ecology: Community ecology An ecological community is the assemblage of species found in a given time and place. The species composition of different ecosystems and the ways in which they maintain equilibrium and react to disturbances are manifestations of the community’s stability.
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he populations that form a community interact through the processes of competition, predation, parasitism, and mutualism. The structures of communities are determined, in part, by the nature and strength of these biotic factors. Abiotic factors (physical factors such as temperature, rainfall, and soil fertility) are the other set of important influences determining community structure. An ecological community together with its physical environment is called an ecosystem. No ecosystem can be properly understood without a careful study of the biotic and abiotic factors that shape it. Energy Flow The most common way to characterize a community functionally is by describing the flow of energy through it. Based on the dynamics of energy flow, organisms can be classified into three groups: those that obtain energy through photosynthesis (called producers), those that obtain energy by consuming other organisms (consumers), and those that decompose dead organisms (decomposers). The pathway through which energy travels from producer through one or more consumers and finally to decomposer is called a food chain. Each link in a food chain is called a trophic level. Interconnected food chains in a community constitute a food web. Very few communities are so simple that they can be readily described by a food web. Most communities are compartmentalized: A given set of producers tends to be consumed by a limited number of consumers, which in turn are preyed upon by a smaller number of predators, and so on. Alternatively, consumers may obtain energy by specializing on one part of their prey (for example, some birds may eat only seeds of plants) but utilize a wide range of prey species. Compartmentalization is an important feature of community structure; it influences the formation, organization, and persistence of a community. Dominant and Keystone Species Some species, called dominant species, can exert powerful control over the 104
Communities: structure abundance of other species because of the dominant species’ large size, extended life span, or ability to monopolize energy or other resources. Communities are named according to their dominant species: for example, oakhickory forest, redwood forest, sagebrush desert, and tall-grass prairie. Some species, called keystone species, have a disproportionately large effect on community structure. These interact with other members of the community in such a way that loss of the keystone species can lead to the loss of many other species. Keystone species may also be the dominate species, but they may also appear insignificant to the community until they are gone. For example, cordgrass (Spartina) is the dominant plant in many tidal estuaries, and it is also a keystone species because so many members of the community depend on it for food and shelter. The species that make up a community are seldom distributed uniformly across the landscape; rather, some degree of patchiness is characteristic of virtually all species. There has been conflicting evidence as to the nature of this patchiness. Moving across an environmental gradient (for example, from wet to dry conditions or from low to high elevations), there is a corresponding change in species and community composition. Some studies have suggested that changes in species composition usually occur along relatively sharp boundaries and that these boundaries mark the border between adjacent communities. Other studies have indicated that species tend to respond individually to environmental gradients and that community boundaries are not sharply defined; rather, most communities broadly intergrade into one another, forming what is often called an ecotone. Degrees of Species Interaction These conflicting results have fueled a continuing debate as to the underlying nature of communities. Some communities seem to behave in a coordinated manner. For example, if a prairie is consumed by fire, it regenerates in a predictable sequence, ultimately returning to the same structure and composition it had before the fire. This process, called ecological succession, is to be expected if the species in a community have evolved together with one another. In this case, the community is behaving like an organism, maintaining its structure and function in the face of environmental disturbances and fluctuations (as long as the disturbances and fluctuations are not too extreme). The existence of relatively sharp boundaries between adjacent communities supports this explanation of the nature of the community. In other communities, it appears that the response to environmental fluctuation or disturbance is determined by the evolved adaptations of the 105
Communities: structure species available. There is no coordinated community response but rather a coincidental assembly of community structure over time. Some sets of species interact together so strongly that they enter a community together, but there is no evidence of an evolved community tendency to resist or accommodate environmental change. In this case, the community is formed primarily of species that happen to share similar environmental requirements. Competition and Predation Disagreement as to the underlying nature of communities usually reflects disagreement about the relative importance of the underlying mechanisms that determine community structure. Interspecific competition has long been invoked as the primary agent structuring communities. Competition is certainly important in some communities, but there is insufficient evidence to indicate how widespread and important it is in determining community structure. Much of the difficulty occurs because ecologists must infer the existence of past competition from present patterns in communities. It appears that competition has been important in many vertebrate communities and in communities dominated by sessile organisms, such as plants. It does not appear to have been important in structuring communities of plant-eating insects. Furthermore, the effects of competition typically affect individuals that use identical resources, so that only a small percentage of species in a community may be experiencing significant competition at any time. The effects of predation on community structure depend on the nature of the predation. Keystone predators usually exert their influence by preying on species that are competitively dominant, thus giving less competitive species a chance. Predators that do not specialize on one or a few species may also have a major effect on community structure, if they attack prey in proportion to their abundance. This frequency-dependent predation prevents any prey species from achieving dominance. If a predator is too efficient, it can drive its prey to extinction, which may cause a selective predator to become extinct as well. Predation appears to be most important in determining community structure in environments that are predictable or unchanging. Disasters and Catastrophes Chance events can also influence the structure of a community. No environment is completely uniform. Seasonal or longer-term environmental fluctuations affect community structure by limiting opportunities for colonization, by causing direct mortality, or by hindering or exacerbating the 106
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The checkerboard pattern of clear-cutting in forests of the Pacific Northwest threatens the survival of the northern spotted owl, the marbled murrelet, Vaux’s swift, and the red tree vole, even though fragments of the community remain. Such disruptions of community structure can be mitigated by thinning to sustain mixed-age, mixed-species trees. (PhotoDisc)
effects of competition and predation. Furthermore, all communities experience at least occasional disturbance: unpredictable, seemingly random environmental changes that may be quite severe. It is useful in this regard to distinguish between regular disturbances and rarer, more frequent catastrophic events. For example, fire occurs so often in tall-grass prairies that most of the plant species have become fireadapted—they have become efficient at acquiring nutrients left in the ash and at sprouting or germinating quickly after a fire. In contrast, the 1980 eruption of Mount St. Helens, a volcanic peak in Washington State, was so violent and so unexpected that no members of the nearby community were adequately adapted to such conditions. Natural disturbances occur at a variety of scales. Small-scale disturbances may simply create small openings in a community. In forests, for example, wind, lightning, and fungi cause single mature trees to die and fall, creating gaps that are typically colonized by species requiring such openings. Large disturbances are qualitatively different from small disturbances in that large portions of a community may be destroyed, including some of the ability to recover from the disturbance. For example, following 107
Communities: structure a large, intense forest fire, some tree species may not return for decades or centuries, because their seeds were consumed by the fire, and colonizers must travel a long distance. Early ecologists almost always saw disturbances as destructive and disruptive for communities. Under this assumption, most mathematical models portrayed communities as generally being in some stable state; if a disturbance occurred, the community inevitably returned to the same (or some alternative) equilibrium. It later became clear, however, that natural disturbance is a part of almost all natural communities. Ecologists now recognize that few communities exhibit an equilibrium; instead, communities are dynamic, always responding to the last disturbance. Long-Term Community Dynamics The evidence suggests that three conclusions can be drawn about the longterm dynamics of communities. First, it can no longer be assumed that all communities remain at equilibrium until changed by outside forces. Disturbances are so common, at so many different scales and frequencies, that the community must be viewed as an entity that is constantly changing as its constituent species readjust to disturbance and to one another. Second, communities respond in different ways to disturbance. A community may exhibit resistance, not markedly changing when disturbance occurs, until it reaches a threshold and suddenly and rapidly shifts to a new state. Alternatively, a community may exhibit resilience by quickly returning to its former state after a disturbance. Resilience may occur over a wide range of conditions and scales of disturbance in a dynamically robust system. On the other hand, a community that exhibits resilience only within a narrow range of conditions is said to be dynamically fragile. Finally, there is no simple way to predict the stability of a community. At the end of the 1970’s, many ecologists predicted that complex communities would be more stable than simple communities. It appeared that stability was conferred by more intricate food webs, greater structural complexity, and greater species richness. On the basis of numerous field studies and theoretical models, many ecologists now conclude that no such relationship exists. Both very complex communities, such as tropical rain forests, and very simple communities, such as Arctic tundra, may be very fragile. Studying Communities Most communities consist of thousands of species, and their complexity makes them very difficult to study. Most community ecologists specialize in taxonomically restricted subsets of communities (such as plant commu108
Communities: structure nities, bird communities, insect communities, or moss communities) or in functionally restricted subsets of communities (such as soil communities, tree-hole communities, pond communities, or detrivore communities). The type of community under investigation and the questions of interest determine the appropriate methods of study. The central questions in most community studies are how many species are present and what is the abundance of each. The answers to these questions can be estimated using mark-recapture methods or any other enumeration method. Often the aim is to compare communities (or to compare the same community at different times). A specialized parameter called similarity is used to compare and classify communities; more than two dozen measures of similarity are available. Measures of similarity are typically subjected to cluster analysis, a set of techniques that groups communities on the basis of their similarity. Many multivariate techniques are used to search for patterns in community data. Direct gradient analysis is the simplest of these techniques; it is used to study the distribution of species along an environmental gradient. Ordination includes several methods for collapsing community data for many species in many communities along several environmental gradients onto a single graph that summarizes their relationships and patterns. Community Disturbance At the most basic level, destruction of a community eliminates the species that make up the community. If the community is restricted in its extent, and if its constituent species are found nowhere else, those species become extinct. If the community covers a large area or is found in several areas, local extinction of species may occur without causing global extinction. Destruction of a community can cause unexpected changes in environmental conditions that were modified by the intact community. Even partial destruction of an extensive community can eliminate species. For example, the checkerboard pattern of clear-cutting in Douglas fir forests of the Pacific Northwest threatens the survival of the northern spotted owl, the marbled murrelet, Vaux’s swift, and the red tree vole, even though fragments of the community remain. Many fragments are simply too small to support these species. A Douglas fir forest is regenerated following cutting, but this young, even-aged stand is so different from an old, mixed-age forest that it functions as a different type of community. Altering the population of one species can affect others in a community. The black-footed ferret was once found widely throughout central North America as a predator of prairie dogs. As prairie dogs were poisoned, drowned, and shot throughout their range, the number of black-footed fer109
Communities: structure rets declined. The species nearly became extinct, and an attempt to increase their numbers and preserve the species was instituted in the late 1980’s in a Wyoming breeding program. Introducing a new species into a community can severely alter the interactions in the community. The introduction of the European rabbit into Australia led to a population explosion of rabbits, excessive predation on vegetation, and resulting declines in many native marsupials. Finally, it appears that many communities exhibit stability thresholds; if a community is disturbed beyond its threshold, its structure is permanently changed. For example, acid deposition in lakes is initially buffered by natural processes. As acid deposition exceeds the buffering capacity of a lake, it causes insoluble aluminum in the lake bottom to become soluble, and this soluble aluminum kills aquatic organisms directly or by making them more susceptible to disease. The lesson is clear: It is far easier to disrupt or destroy natural systems (even accidentally) than it is to restore or reconstruct them. Alan D. Copsey, updated by Bryan Ness See also: Animal-plant interactions; Biodiversity; Biogeography; Biological invasions; Coevolution; Communities: ecosystem interactions; Competition; Defense mechanisms; Eutrophication; Food chains and webs; Invasive plants; Predation; Speciation; Species loss; Succession; Trophic levels and ecological niches. Sources for Further Study Aber, John D., and Jerry M. Melillo. Terrestrial Ecosystems. 2d ed. San Diego: Harcourt, 2001. Begon, Michael, John L. Harper, and Colin R. Townsend. Ecology: Individuals, Populations, and Communities. 3d ed. Cambridge, Mass.: Blackwell Science, 1996. Bormann, Frank H., and Gene E. Likens. “Catastrophic Disturbance and the Steady State in Northern Hardwood Forests.” American Scientist 67 (1979): 660-669. Goldammer, J. G., ed. Tropical Forests in Transition: Ecology of Natural and Anthropogenic Disturbance Processes. Boston: Springer-Verlag, 1992. Krebs, Charles J. Ecology: The Experimental Analysis of Distribution and Abundance. 5th ed. San Francisco: Benjamin Cummings, 2001. Pickett, S. T. A., and P. S. White, eds. The Ecology of Natural Disturbance and Patch Dynamics. Orlando, Fla.: Academic Press, 1985. Pielou, E. C. The Interpretation of Ecological Data: A Primer on Classification and Ordination. New York: John Wiley & Sons, 1984. 110
COMPETITION Types of ecology: Behavioral ecology; Community ecology Competition is the conflict between different organisms for control of food, natural resources, territories, mates, and other aspects of survival. Competition can occur between individuals of the same species or between individuals of different species. In either case, it is natural selection for the fittest organisms and species; therefore, it is a major driving force in evolution.
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he science of ecology can best be defined as the experimental analysis of the distribution and abundance of organisms. Natural selection influences the distribution and abundance of organisms from place to place. The possible selecting factors include physical factors (temperature and light, for example), chemical factors such as water and salt, and species interactions. Any of these factors can influence the survivability of organisms in any particular environment. According to ecologist Charles Krebs, species interactions include four principal types: mutualism, which is the living together of two species that benefit each other (for example, humans and their pets); commensalism, which is the living together of two species that results in a distinct benefit (or number of benefits) to one species while the other remains unhurt (commensalism is shown in the relationship of birds and trees); predation, which is the hunting, killing, and eating of one species by another (examples: cats and mice; dogs and deer); and competition, which is defined as an active struggle for survival among all the species in a given environment. This struggle involves the acquisition of various resources: food, territory, and mates. Food is an obvious target of competition. All organisms must have energy in order to conduct the cellular chemical reactions (such as respiration) that keep them alive. Photoautotrophic organisms (plants, phytoplankton, photobacteria) obtain this energy by converting sunlight, carbon dioxide, and water into sugar, a process called photosynthesis. Photoautotrophs, also called producers, compete for light and water. For example, oak and hickory trees grow taller than most pines, thereby shading out smaller species and eventually dominating a forest. All other organisms—animals, zooplankton, and fungi—are heterotrophs; they must consume other organisms to obtain energy. Heterotrophs include herbivores, carnivores, omnivores, and saprotrophs. Herbivores (plant eaters such as rabbits and cattle) obtain the sugar manufactured by plants. Carni111
Competition vores (meat eaters such as cats and dogs) eat other heterotrophs in order to get the sugar that these heterotrophs received from other organisms. Omnivores, such as humans, eat plants and animals for the same reason. Saprotrophs (such as fungi and bacteria) decompose dead organisms for the same reason. Life on earth functions by intricately complex food chains in which organisms consume other organisms in order to obtain energy. Each human being is composed of molecules that were once part of other living organisms, even other humans. Ultimately, the earth’s energy comes from the sun. Territoriality is equally important for two reasons: An organism needs a place to live, and this place must contain adequate food and water reserves. A strong, well-adapted organism will fight and drive away weaker individuals of the same or different species in order to maintain exclusive rights to an area containing a large food and water supply. Species that are less well adapted will be relegated to areas where food and water are scarce. The stronger species will have more food and will tend to produce more offspring, since they will easily attract mates. Being stronger or more adapted does not necessarily mean being physically stronger. A physically strong organism can be overwhelmed easily by numerous weak individuals. In general, adaptability is defined by an organism’s ability to prosper in a hostile environment and leave many viable offspring.
Animals compete for territory, social status, food, and access to mates. Although competition may be violent and result in injury, competitive behavior (unlike predation) rarely results in death. (Corbis) 112
Competition Types of Competition Intraspecific competition occurs among individual members of the same population, for example, when sprouts from plants grow from seeds scattered closely together on the ground. Some seedlings will be able to grow faster than others and will inhibit the growth of less vigorous seedlings by overshadowing or overcrowding them. Within animal species, males attempt to attract females to their territory, or vice versa, by courtship dances and displays, often including bright colors such as red and blue and exaggerated body size. Mating displays are very similar to the threat displays used to drive away competitors, although there is no hostility involved. Generally, females are attracted to dominant males having the best, not necessarily the largest, territories. Interspecific competition involves two or more different species trying to use the same resources. All green plants, for example, depend on photosynthesis to derive the energy and carbon they need. Different areas or communities favor different growth characteristics. For plants with high light requirements, a taller-growing plant (or one with more or broader leaves) will have a competitive advantage if its leaves receive more direct sunlight than competitors. If, on the other hand, the species cannot tolerate much sun, a shorter-growing species that can benefit from sheltering shadows of larger plants nearby will have the competitive advantage over other shade-loving plants. Competition for food and territory is both interspecific and intraspecific. Competition for mates is intraspecific. In an environment, the place where an organism lives (such as a eucalyptus tree or in rotting logs) is referred to as its habitat. Simultaneously, each species has its own unique niche, or occupation, in the environment (such as decomposer or carnivore). More than one species can occupy a habitat if they have different ecological niches. When two or more different species occupy the same habitat and niche, competition arises. One species will outcompete and dominate, while the losing competitors may become reduced in numbers and may be driven away from the habitat. Pecking Orders In vertebrate organisms, intraspecific competition occurs between males as a group and between females as a group. Rarely is there male-versus-female competition, except in species having high social bonding—primates, for example. Competition begins when individuals are young. During play fighting, individuals nip or peck at each other while exhibiting threat displays. Dominant individuals exert their authority, while weaker individuals submit. The net result is a very ordered ranking of individuals from top 113
Competition to bottom, called a dominance hierarchy or pecking order. The top individual can threaten and force into submission any individual below it. The number two individual can threaten anyone except number one, and so on. The lowest-ranked individual can threaten no one and must submit to everyone. The lowest individual will have the least food, worst territory, and fewest (if any) mates. The number one individual will have the most food, best territory, and most mates. The pecking order changes over time because of continued group competition that is shown by challenges, aging, and accidents. Pecking orders are evident in hens. A very dominant individual will peck other hens many times but will rarely be pecked. A less dominant individual will peck less but be pecked more. A correct ranking can be obtained easily by counting the pecking rate for each hen. In the Netherlands, male black grouse contend with one another in an area called a “lek,” which may be occupied by as many as twenty males. The males establish their territories by pecking, wing-beating, and threat displays. The most dominant males occupy small territories (several hundred meters) at the center of the lek, where the food supply is greatest. Less dominant males occupy larger territories with less food reserves to the exterior of the lek. Established territories are maintained at measurable distances by crowing and flutter-jumping, with the home territory owner nearly always winning. Females, which nest in an adjoining meadow, are attracted to dominant males in the heavily contested small central territories. A baboon troop can range in size from ten to two hundred members, but usually averages about forty. Larger, dominant males and their many female mates move centrally within the troop. Less dominant males, with fewer females, lie toward the outside of the troop. Weak individuals at the troop periphery are more susceptible to predator attacks. Dominant males exert their authority by threat displays, such as the baring of the teeth or charging; weaker males submit by presenting their hindquarters. Conflicts are usually peacefully resolved. Female lions maintain an organized pride with a single ruling male. Young males are expelled and wander alone in the wilderness. Upon reaching adulthood, males attempt to take over a pride in order to gain access to females. If a male is successful in capturing a pride and expelling his rival, he will often kill the cubs of the pride, simultaneously eliminating his rival’s descendants and stimulating the females to enter estrus for mating. Competition Within Niches Interspecific competition occurs between different species over food and 114
Competition water reserves and territories. Two or more species occupying the same niche and habitat will struggle for the available resources until either one species dominates and the others are excluded from the habitat or the different species evolve into separate niches by targeting different food reserves, thus enabling all to survive in the same habitat. Numerous interspecific studies have been conducted—on crossbills, warblers, blackbirds, and insects, to mention a few. Crossbills are small birds that live in Europe and Asia. Three crossbill species inhabit similar habitats and nearly similar niches. Each species has evolved a slightly modified beak, however, for retrieving and eating seeds from three different cone-bearing (coniferous) trees. The white-winged crossbill has a slender beak for feeding from small larch cones, the common crossbill has a thicker beak for feeding from larger spruce cones, and the parrot crossbill appropriately has a very thick beak for feeding from pine cones. The evolution of different niches has enabled these three competitors to survive. Another example of this phenomenon is shown by five species of warblers that inhabit the coniferous forests of the American northeast. The myrtle warbler eats insects from all parts of trees up to seven meters high. The bay-breasted warbler eats insects from tree trunks six to twelve meters above the ground. The black-throated green, blackburnian, and cape may warblers all feed near the treetops, according to elaborate studies by Robert H. MacArthur. The coexistence of five different species is probably the result of the warblers occupying different parts of the trees, with some warblers developing different feeding habits so that all survive. G. H. Orians and G. Collier studied competitive exclusion between redwing and tricolored blackbirds. Introduction of tricolored blackbirds into redwing territories results in heavy redwing aggression, although the tricolored blackbirds nearly always prevail. Two species of African ants, Anoplolepis longipes and Oecophylla longinoda, fight aggressively for territorial space. M. J. Way found that Anoplolepis prevails in sandy environments, whereas Oecophylla dominates in areas having thick vegetation. Interspecific competition therefore results in the evolution of new traits and niches and the exclusion of certain species. Mathematical models of competition are based upon the work of A. J. Lotka and V. Volterra. The Lotka-Volterra equations attempt to measure competition between species for food and territory based upon the population size of each species, the density of each species within the defined area, the rate of population increase of each species, and time. 115
Competition Observing Competiton Studies of competition between individuals of the same or different species generally follow one basic method: observation. Interactions between organisms are observed and carefully measured to determine if the situation is competition, predation, parasitism, or mutualism. More detailed analyses of environmental chemical and physical conditions are used to determine the existence of additional influences. Observations of competition between organisms involve direct visual contact in the wild, mark-recapture experiments, transplant experiments, measurements of population sizes in given areas, and competition experiments in artificial environments. Direct visual contact involves the scientist entering the field, finding a neutral, nonthreatening position, and watching and recording the actions of the subject organisms. The observer must be familiar with the habits of the subject organism and must be keen to detect subtle cues such as facial gestures, vocalizations, colors, and patterns of movement from individual to individual. Useful instruments include binoculars, telescopes, cameras, and sound recorders. The observer must be capable of tracking individuals over long distances so that territorial boundaries and all relevant actions are recorded. The observer may have to endure long periods of time in the field under uncomfortable conditions. Mark-recapture experiments involve the capture of many organisms, tagging them, releasing them into an area, and then recapturing them (both tagged and untagged) at a later time. Repeated collections (recaptures) over time can give the experimenter an estimate of how well the species is faring in a particular environment. This technique is used in conjunction with other experiments, including transplants and population size measurements. In transplant experiments, individuals of a given species are marked and released into a specific environmental situation, such as a new habitat or another species’ territory. The objective of the experiment is to see how well the introduced species fares in the new situation, as well as the responses of the various species which normally inhabit the area. The tricolored blackbird takeover of redwing blackbird territories is a prime example. Another example is the red wolf, a species that was extinct in the wild until several dozen captive wolves were released at the Alligator River Wildlife Refuge in eastern North Carolina. Their survival is uncertain. Accidental transplants have had disastrous results for certain species; for example, the African honeybee poses a threat to the honey industry in Latin America and the southern United States because it is aggressive and produces poorly. 116
Competition Measurements of population sizes rely upon the point-quarter technique, in which numerous rectangular areas of equal size are marked in the field. The number of organisms of each species in the habitat is counted for a given area; an averaging of all areas is then made to obtain a relatively accurate measure of each population’s size. In combination with markrecapture experiments, population measurements can provide information for birthrates, death rates, immigration, and emigration over time for a given habitat. Laboratory experiments involve confrontations between different species or individuals of the same species within an artificial environment. For example, male mouse (Mus musculus) territoriality can be studied by introducing an intruder into another male’s home territory. Generally, the winner of the confrontation is the individual that nips its opponent more times. Usually, home court advantage prevails; the intruder is driven away. Similar studies have been performed with other mammalian, reptile, fish, insect, and bird species. Interactions between different species are subtle and intricate. Seeing how organisms associate enables scientists to understand evolution and to model various environments. Competition is a major driving force in evolution. The stronger species outcompete weaker species for the available ecological niches. Mutations in organisms create new traits and, therefore, new organisms (more species), which are selected by the environment for adaptability. All environments consist of a complex array of species, each dependent on the others for survival. The area in which they live is their habitat. Each species’ contribution to the habitat is that species’ niche. More than one species in a given habitat causes competition. Two species will struggle for available territory and food resources until either one species drives the other away or they adapt to each other and evolve different feeding habits and living arrangements. Competition can be interspecific (between individuals of different species) or intraspecific (between individuals of the same species). The environment benefits because the most adapted species survive, whereas weaker species are excluded. David Wason Hollar, Jr. See also: Allelopathy; Animal-plant interactions; Biodiversity; Biogeography; Biological invasions; Coevolution; Communities: ecosystem interactions; Communities: structure; Defense mechanisms; Food chains and webs; Gene flow; Genetic diversity; Lichens; Mycorrhizae; Pollination; Predation; Speciation; Succession; Symbiosis; Trophic levels and ecological niches. 117
Competition Sources for Further Study Andrewartha, H. G. Introduction to the Study of Animal Populations. Chicago: University of Chicago Press, 1967. Arthur, Wallace. The Niche in Competition and Evolution. New York: John Wiley & Sons, 1987. Hartl, Daniel L. Principles of Population Genetics. 3d ed. Sunderland, Mass.: Sinauer Associates, 1997. Keddy, Paul A. Competition. 2d ed. New York: Kluwer, 2000. Krebs, Charles J. Ecology: The Experimental Analysis of Distribution and Abundance. 5th ed. San Francisco: Benjamin Cummings, 2001. Lorenz, Konrad. On Aggression. New York: Harcourt, Brace & World, 1963. Raven, Peter H., and George B. Johnson. Biology. 5th ed. Boston: WCB/ McGraw-Hill, 1999. Wilson, Edward O. Sociobiology: The New Synthesis. Cambridge, Mass.: Belknap Press of Harvard University Press, 1975.
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CONSERVATION BIOLOGY Type of ecology: Restoration and conservation ecology Conservation biology is a multidisciplinary field that uses knowledge and skills from all aspects of biological science to design and implement methods to ensure the survival of species, ecosystems, and ecological processes.
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he overriding mission of conservation biology is to ensure the continued survival of all life-forms and to maintain the structure and function of all ecosystems and ecological processes. Attempting to achieve this goal requires biological knowledge from disciplines such as genetics, physiology, systematics, and ecology in combination with skills and practices from applied fields such as forestry, fisheries, and wildlife management. In addition to biological knowledge, social and economic issues must be addressed in the development of natural resource policies designed to preserve and protect species and ecosystems. Conservation biology, a relatively new discipline, arose from questions about how to develop methods and policies to maintain global biodiversity. Policy development and implementation must consider the role of evolutionary processes in order to preserve genetic diversity and enable the continued survival of threatened or endangered species. Conservation biologists are also concerned with practical issues such as the design of parks and nature reserves. David D. Reed See also: Biodiversity; Deforestation; Endangered animal species; Endangered plant species; Erosion and erosion control; Forest management; Genetic diversity; Grazing and overgrazing; Integrated pest management; Landscape ecology; Multiple-use approach; Old-growth forests; Reforestation; Restoration ecology; Species loss; Sustainable development; Urban and suburban wildlife; Waste management; Wildlife management; Zoos. Sources for Further Study Cox, G. W. Conservation Biology: Concepts and Applications. Dubuque, Iowa: William C. Brown, 1997. Hunter, Malcolm, Jr. Fundamentals of Conservation Biology. Cambridge, Mass.: Blackwell Science, 1996. Primack, Richard. Essentials of Conservation Biology. Sunderland, Mass.: Sinauer Associates, 1993. 119
CONVERGENCE AND DIVERGENCE Types of ecology: Evolutionary ecology; Population ecology; Speciation Some of the most dramatic examples of natural selection are the result of adaptation in response to stressful climatic conditions. Such selection may cause unrelated species to resemble one another in appearance and function, a phenomenon known as convergence. In other situations, subpopulations of a single species may split into separate species as the result of natural selection. Such divergence is best seen on isolated islands. Convergent Evolution Convergent evolution occurs when organisms from different evolutionary lineages evolve similar adaptations to similar environmental conditions. This can happen even when the organisms are widely separated geographically. A classic example of convergent evolution occurred with Cactaceae, the cactus family, of the Americas and with the spurge or euphorbs (Euphorbiaceae) family of South Africa, both of which have evolved succulent (water-storing) stems in response to desert conditions. The most primitive cacti are vinelike, tropical plants of the genus Pereskia. These cacti, which grow on the islands of the West Indies and in tropical Central and South America, have somewhat woody stems and broad, flat leaves. As deserts developed in North and South America, members of the cactus family began to undergo selection for features that were adaptive to hotter, dryer conditions. The stems became greatly enlarged and succulent as extensive waterstorage tissues formed in the pith or cortex. The leaves became much reduced. In some cactus species, such as the common prickly pear (Opuntia), the leaves are small, cylindrical pegs that shrivel and fall off after a month or so of growth. In most cacti, only the leaf base forms and remains as a small hump of tissue associated with an axillary bud. In some cacti this hump is enlarged and is known as a tubercle. Axillary buds in cacti are highly specialized and are known as areoles. The “leaves” of an areole are reduced to one or more spines. Particularly in columnar cacti, the areoles are arranged in longitudinal rows along a multiple-ridged stem. With the possible exception of the genus Rhipsalis, which has one species reported to occur naturally in Africa, all cacti are native to the Americas. As deserts formed in Africa, Eurasia, and Australia, different plant families evolved adaptations similar to those in cacti. The most notable examples are the candelabra euphorbs of South Africa. Desert-dwelling 120
Convergence and divergence members of the Euphorbiaceae frequently have succulent, ridged, cylindrical stems resembling those of cacti. The leaves are typically reduced in size and are present only during the rainy season. They are arranged in rows along each of several ridges of the stem. Associated with each leaf are one or two spines. As a result, when the leaves shrivel and fall off during the dry season, a spiny, cactuslike stem remains. The succulent euphorbs of Africa take on all the forms characteristic of American cacti, from pincushions and barrels to branched and unbranched columns. Other plant families that show convergence with the cacti, in having succulent stems or leaves, are the stem succulents of the milkweed family, sunflower family, stonecrop family, purslane family, grape family, leaf succulents of the ice plant family, daffodil family, pineapple family, geranium family, and lily family. Divergent Evolution Some of the most famous examples of divergent evolution have occurred in the Galápagos Islands. The Galápagos comprise fourteen volcanic islands located about 600 miles west of South America. A total of 543 species of vascular plants are found on the islands, 231 of which are endemic, found nowhere else on earth. Seeds of various species arrived on the islands by floating in the air or on the water or being carried by birds or humans. With few competitors and many different open habitats, variant forms of each species could adapt to specific conditions, a process known as
An example of convergent evolution is the way that sharks (left), which are fish, and dolphins (right), which are mammals, have evolved similar body shapes to adapt to their marine ecological niches. Although the two animals look very much alike, their differences in evolutionary terms are vast. (Digital Stock) 121
Convergence and divergence adaptive radiation. Those forms of a species best suited to each particular habitat were continually selected for and produced progeny in that habitat. Over time, this natural selection resulted in multiple new species sharing the same ancestor. The best examples of divergent evolution in the Galápagos have occurred in the Cactaceae and Euphorbiaceae. Eighteen species and variety of cacti are found on the islands, and all are endemic. Of the twenty-seven species and varieties of euphorbs, twenty are endemic. An interesting example of the outcome of divergent evolution can be seen in the artificial selection of different cultivars (cultivated varieties) in the genus Brassica. The scrubby Eurasian weed colewort (Brassica oleracea) is the ancestor of broccoli, brussels sprouts, cabbage, cauliflower, kale, and kohlrabi (rutabaga). All these vegetables are considered to belong to the same species, but since the origin of agriculture, each has been selected for a specific form that is now recognized as a distinct crop. Marshall D. Sundberg See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Dendrochronology; Development and ecological strategies; Evolution: definition and theories; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Genetically modified foods; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Paleoecology; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Species loss. Sources for Further Study Bowman, Robert I., Margaret Berson, and Alan E. Leviton. Patterns of Evolution in Galápagos Organisms. San Francisco: California Academy of Sciences, 1983. Darwin, Charles. “Journal and Remarks: 1832-1836.” In Narrative of the Surveying Voyages of His Majesty’s Ships Adventure and Beagle Between the Years 1826 and 1836: Describing Their Examination of the Southern Shores of South America, and the Beagle’s Circumnavigation of the Globe, edited by Robert Fitzroy. Vol. 3. Reprint. New York: AMS Press, 1966. Harris, James G., and Melinda Woolf Harris. Plant Identification Terminology: An Illustrated Glossary. Spring Lake, Utah: Spring Lake, 1994. Uno, Gordon, Richard Storey, and Randy Moore. Principles of Botany. New York: McGraw-Hill, 2001.
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DEEP ECOLOGY Type of ecology: Theoretical ecology Deep ecology is a school of environmental philosophy based on environmental activism and ecological spirituality.
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he term “deep ecology” was first used by Norwegian philosopher Arne Naess in 1972 to suggest the need to go beyond the anthropocentric view that nature is merely a resource for human use. The concept has been used in three major ways. First, it refers to a commitment to deep questioning about environmental ethics and the causes of environmental problems. Such questioning leads to critical reflection on the fundamental worldviews that underlie specific environmental ideas and practices. Second, deep ecology refers to a platform of generally agreed upon values that a variety of environmental activists share. These values include an affirmation of the intrinsic value of nature, the recognition of the importance of biodiversity, a call for a reduction of human impact on the natural world, greater concern with quality of life rather than material affluence, and a commitment to changing economic policies and the dominant view of nature. Third, deep ecology refers to particular philosophies of nature that tend to emphasize the value of nature as a whole (ecocentrism), an identification of the self with the natural world, and an intuitive and sensuous communion with the earth. Because of its emphasis on fundamental worldviews, deep ecology is often associated with non-Western spiritual traditions such as Buddhism and Native American cultures, as well as radical Western philosophers such as Baruch Spinoza and Martin Heidegger. It has also drawn on the nature writing of Henry David Thoreau, John Muir, Robinson Jeffers, and Gary Snyder. Deep ecology’s holistic tendencies have led to associations with the Gaia hypothesis, and its emphasis on diversity and intimacy with nature has linked it to bioregionalism. Deep ecological views have also had a strong impact on environmental activism, including the Earth First! movement. Deep ecologists have sometimes criticized the animal rights perspective for continuing the traditional Western emphasis on individuals while neglecting whole systems, as well as for a revised speciesism that still values certain parts of nature (animals) over others. Some deep ecologists have also been critical of mainstream environmental organizations such as the Sierra Club for not confronting the root causes of environmental degradation. 123
Deep ecology On the other hand, deep ecology has been criticized by ecofeminists for failing to consider gender differences in the experience of the self and nature, the lack of an analysis of the tie between the oppression of women and nature, and promoting a holism that supposedly disregards the reality and value of individuals and their relationships. Social ecologists have criticized deep ecology for a failure to critique the relationship between environmental destruction on the one hand and social structure and political ideology on the other. In addition, a distrust of human interference with nature has led some thinkers to present the ideal as pristine wilderness with no human presence. In rare and extreme cases, deep ecologists have implied a misanthropic attitude. In some instances, especially early writings by deep ecologists, such criticisms have considerable force. However, these problematic views are not essential to deep ecology, and a number of thinkers have developed a broadened view that overlaps with ecofeminism and social ecology. David Landis Barnhill See also: Balance of nature; Biomes: determinants; Biomes: types; Biosphere concept; Ecology: definition; Ecosystems: definition and history; Sustainable development; . Sources for Further Study Naess, Arne. Ecology, Community, and Lifestyle: Outline of an Ecosophy. Translated and revised by David Rothenberg. New York: Cambridge University Press, 1989. _______. Spinoza and the Deep Ecology Movement. Delft: Eburon, 1993.
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DEFENSE MECHANISMS Types of ecology: Behavioral ecology; Chemical ecology; Physiological ecology All organisms represent a potential resource for their predators. Several have evolved ingenious ways to prevent themselves from becoming a predator’s next meal.
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ll organisms are composed of fixed carbon, biomolecules, and mineral nutrients and therefore represent energy and nutrient resources for consumers. To be successful in life, animals must avoid, tolerate, or defend themselves against natural enemies such as predators, parasites, and competitors. The term “defense” can be attributed to any trait that reduces the likelihood that an organism, or part of an organism, will be consumed by a predator. Several categories of defenses have evolved in animals, including structural defenses, chemical defenses, associational defenses, behavioral defenses, autotomy, and nutritional defenses. Animals often possess more than one type of defense, thereby having backup plans in case the first line of defense fails. The number of defenses devised by organisms is a reflection of the strong selective pressure exerted by predators. Structural Defenses: Being Hard and Sharp Structures that defend animals can act as external shields: sharp spines located externally or internally, skeletal materials that make tissues too hard to bite easily, or weaponry such as horns, teeth, and claws. External structures that protect vulnerable soft tissues include the chitonous exoskeletons of crustaceans, the calcareous shells of corals, mollusks, and barnacles, the tests (skeletal plates) of echinoderms, the tough tunics of ascidians, and the hard plates of armadillos. The pretty shells that tourists collect along beaches were once used to protect a soft, delicate animal that lived inside the shell. Hard, protective shells remain after the animal dies and can be used by other animals for protection. For example, small fish will retreat into empty conch shells when they feel threatened by predators, and hermit crabs live inside empty snail shells to protect their soft, vulnerable abdomens. Some animals cover their bodies with sharp structures that puncture predators that try to bite them. The porcupine is a good example of a mammal that uses this defensive strategy. Porcupines are covered with tens of thousands of long, pointed spines, or quills, growing from their back and 125
Defense mechanisms sides. The quills have needle-sharp ends containing hundreds of barbs that make the quills difficult to remove. Sea urchins are also covered with long, sharp spines that deter would-be predators. Urchins can move their spines, and will direct them toward anything that comes in contact with them, such as a predator. While porcupines and urchins are covered with multiple spines, stingrays defend themselves from enemies by inflicting a wound with a single barbed spine. The wound is extremely painful, giving these rays their common name. Predators have sharp claws and teeth that help them grasp, subdue, and consume their prey. These same structures, used offensively in hunting, can also be used to protect themselves from their own predators. Small predators such as badgers, raccoons, and foxes can fend off larger predators such as wolves and mountain lions with their weaponry. Rather than risk injury, the larger predators will avoid a fight with the smaller predator and seek a less risky meal, such as a rabbit or mouse. Chemical Defenses: Poor Taste, Bad Smell, or Toxic Chemicals Both plants and animals defend themselves by using compounds that are distasteful, toxic, or otherwise repulsive to consumers. Most defensive compounds are secondary metabolites of unique structures, but can also include more generic compounds such as sulfuric acid or calcium carbonate. Secondary metabolites get their name because they are not involved in basic metabolic pathways such as respiration or photosynthesis (that is, primary metabolic reactions), not because they are of secondary importance. Indeed, many organisms probably could not survive in their natural environment without the protection of their secondary metabolites. Stink bugs get their names because of the smelly secondary metabolites they release from pores located on the sides of their thorax. These smelly compounds repel predators, and may even indicate toxicity to the predator. These insects are common garden pests that are usually controlled with chemical pesticides. However, it appears that the eggs of stink bugs are not defended against roly-poly pill bugs, which can control stink bug numbers (and hence, garden damage) by preying on eggs. Bombardier beetles take chemical defenses a step further, erupting a boiling hot spray of chemicals in the direction of a predator. To accomplish this, the bombardier beetle has a pair of glands that open at the tip of its abdomen. Each gland has two compartments, one that contains a solution of hydroquinone and hydrogen peroxide, and the other that contains a mixture of enzymes. When threatened by a predator, the bombardier beetle squeezes the hydroquinone and hydrogen peroxide mixture into the en126
Defense mechanisms zyme compartment, where an exothermic reaction that produces quinone takes place. The large amount of heat generated brings the quinone mixture to its boiling point, and it is forcefully emitted as a vapor toward the threat. An average bombardier beetle can produce about twenty loud discharges of repulsive, hot chemicals in quick succession. Chemical defenses are common among small, slow animals such as insects, sponges, cnidarians, and sea slugs, which might be limited in their ability to flee from predators. However, chemical defenses are rather rare among large, fast animals. One of the few mammals that uses chemical defenses is the black-and-white-striped skunk. Most people are familiar with the smelly chemical brew emitted from these animals, as it is distinctly detectable along roads when skunks get hit by cars, and can be detected up to a mile from the location where a skunk sprays. These mammals hold their smelly musk in glands located below their tail, and squirt the liquid through ducts that protrude from the anus. When threatened by a predator, the skunk raises its tail and directs its rear end toward the predator. A predator that has had prior experience with a skunk might retreat from this display, but if the predator is persistent at harassing the skunk, the striped mammal will deliver a spray of smelly chemicals that usually sends the predator running. The musk also causes intense pain and temporary blindness if it gets in the eyes of the predator. Associational Defenses Associational defenses occur when a species gains protection from a natural enemy by associating with a protective species, such as when humans gain protection from enemies by keeping a guard dog on their property. Types of protection provided to the defended species through this coevolution can be structural, chemical, or aggressive. Small animals can avoid predators by using a defended species as habitat. For example, small fish defend themselves by associating with sea urchins, gaining protection by hiding among the sharp spines. Some species of shrimp inhabit the cavities and canals of sponges. Sponges are known to be chemically and structurally defended against most predators, with the exception of angel fish and parrot fish. Finally, much of the diverse coral reef fauna seek protection among the cracks and the crevices in the reef. Reefs, slowly built by coral animals, are the largest structures ever made by living organisms, and serve a protective role for thousands of species that inhabit reefs. Associational defenses can also be chemically mediated. For example, bacteria that grow symbiotically on shrimp eggs produce secondary metabolites that protect the egg from a parasitic fungus. The numerous ex127
Defense mechanisms amples of sequestration of chemical defenses can be categorized as associational defenses, as they involve associating with chemically defended prey. An organism might even be defended by protective species that aggressively attack would-be predators, especially if the protected species is a resource for the aggressive defender. For example, humans are protected by guard dogs because dogs view people as a resource that provides them with food, water, and shelter. Stop feeding the dog, and it is likely to look elsewhere for somebody to protect. There are several nonhuman examples of aggressive defensive associations, especially among ants. Aphids are insects that feed on the sugary phloem stream of plants. In the process of feeding and processing phloem, the aphids secrete large amounts of honeydew, which the ants harvest and consume; that is, aphids provide ants with a resource. Ants tend to aphids in the same way that dairy farmers tend to their cows. The ants carry aphids to prime feeding locations, defend aphids from predators, and periodically “milk” the aphids of their honeydew by stroking them with their antennae. Aposematic Coloration and Mimicry Being chemically defended does not protect an animal from being accidentally eaten. Therefore, chemically defended animals often advertise the fact that they are nasty to avoid such accidents. This advertisement is often in the form of outlandish colors and patterns that flaunt the animal’s distastefulness to predators. Using bright warning patterns is called aposematic coloration. One problem with aposematic coloration is the training of predators: Bright coloration is useful only if the predator understands the warning. Otherwise, the coloration simply makes the animal a conspicuous prey item. One way that different species with aposematic coloration share the cost of training naïve predators is through mimicry. A predator that eats an individual of species A (assume species A is bright red with blue stripes) and vomits shortly thereafter may learn to avoid things that are red with blue stripes, though at the cost of that first individual’s life. This educated predator will now avoid other members of species A, and any other organism that looks like species A (the mimic), whether the mimic is toxic or not. If the mimic is toxic, the system is termed Müllerian mimicry. If the mimic is a palatable species that looks like a toxic model, the system is termed Batesian mimicry. Mimicry is common within groups of closely related organisms (for example, snakes, butterflies, and bees) which are already similar in appearance. However, mimicry can also occur even when the model and mimic 128
Defense mechanisms are distantly related. For example, there are caterpillars that mimic the head of a snake, moths that mimic the eyes of a cat, and beetles, moths, and flies that mimic stinging bees and wasps. Autotomy: Throw the Predator a Bone Sometimes, despite the best defenses, a predator will get hold of a prey. When this happens, some animals are able to sacrifice a portion of their body to the predator, with the hopes that the remaining parts will survive, and perhaps even regrow the lost parts. This ability to lose a body part intentionally is called autotomy. Many lower animals, such as sponges, cnidarians, and worms, have great regeneration abilities, and can regrow body parts well. In fact, these animals can even use regeneration as a form of asexual reproduction: Break the animal into four parts, and the parts will generate four complete individuals. Sea cucumbers, in addition to being chemically defended, are able to eviscerate (autotomy of intestines) when harassed by a predator. These are not fast animals, so this action does not allow them to escape, but it might satisfy (or disgust) the predator enough to make it lose interest in the sea cucumber. Losing a large portion of its digestive tract interferes with feeding, but the sea cucumber can regenerate those parts of the gut that were eviscerated, restoring itself to original function. Sea cucumbers also play an important role in a defensive association with the pearlfish. When the pearlfish feels threatened, it locates the anus of a sea cucumber, then backs into its intestine, where it hides until the danger has passed. The regenerative ability of higher animals is generally less than that of lower animals. However, autonomy does occur even in some vertebrates. Lizards are well known for their ability to release the tips of their tails when grabbed by a predator. The predator is distracted, and perhaps satisfied, by the wiggling piece of flesh, and in the meantime, the remainder of the lizard scampers off to safety. Geckos release skin instead of tails. The part of the skin that is grabbed by the predator is released, enabling the gecko to break free and escape. Nutritional Defenses Some animals, such as corals, jellyfish, anemones, and gorgonians (phylum Cnidaria), possess a type of combined structural and chemical defense in the form of specialized stinging cells called nematocysts. When nematocysts are stimulated, they rapidly discharge a barb that punctures the skin of a predator, often releasing toxic chemicals at the same time. The stinging sensation that people get when they come into contact with a jelly129
Defense mechanisms fish is caused by nematocysts. Some of these jellyfish stings are so potent that they can result in death. Not only do many predators avoid jellyfish because they posses nematocysts, but predators may avoid jellyfish because they are jellylike, being composed of more than 95 percent water. It takes time and effort for predators to locate, handle, ingest, and digest prey. If the prey item is basically a bag of seawater (as jellyfish are), then predators might not bother eating these nutrient-deficient animals. Thus, these animals are “nutritionally” defended. Nutritional defenses are also used by plants, but they are generally not an available strategy for animals other than jellyfish, as most animal tissue is relatively nutritious. Greg Cronin See also: Allelopathy; Animal-plant interactions; Bioluminescence; Coevolution; Communities: ecosystem interactions; Metabolites; Poisonous animals; Poisonous plants; Predation; Territoriality and aggression. Sources for Further Study Cloudsley-Thompson, John L. Tooth and Claw: Defensive Strategies in the Animal World. London: J. M. Dent & Sons, 1980. Edmunds, Malcolm. Defence in Animals. Burnt Mill, England: Longman, 1974. Evans, David L., and Justin O. Schmidt, eds. Insect Defenses: Adaptive Mechanisms and Strategies of Prey and Predators. Albany: State University of New York Press, 1990. Kaner, Etta. Animal Defenses: How Animals Protect Themselves. Toronto: Kids Can Press, 1999. McClintock, James B., and Bill J. Baker, eds. Marine Chemical Ecology. Boca Raton, Fla.: CRC Press, 2001. Owen, Denis. Survival in the Wild: Camouflage and Mimicry. Chicago: University of Chicago Press, 1980.
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DEFORESTATION Types of ecology: Ecotoxicology; Restoration and conservation ecology Deforestation is the loss of forestlands through encroachment by agriculture, industrial development, or nonsustainable commercial forestry, and other human as well as natural activity.
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oncerns about deforestation, particularly in tropical regions, have risen as the role that tropical rain forests play in moderating global climate has become better understood. Environmental activists decried the apparent accelerating pace of deforestation in the twentieth century because of the potential loss of wildlife and plant habitat and the negative effects on biodiversity. By the 1990’s research by mainstream scientists had confirmed that deforestation was indeed occurring on a global scale and that it posed a serious threat to global ecology. Deforestation as a result of expansion of agricultural lands or nonsustainable timber harvesting has occurred in many regions of the world at different periods in history. The Bible, for example, refers to the cedars of Lebanon. Lebanon, like many of the countries bordering the Mediterranean Sea, was thickly forested several thousand years ago. A growing human population, overharvesting, and the introduction of grazing animals such as sheep and goats decimated the forests, which never recovered. Countries in Latin America, Asia, and Africa have also lost woodlands. While some of this deforestation is caused by a demand for tropical hardwoods for lumber or pulp, the leading cause of deforestation in the twentieth century, as it was several hundred years ago, was the expansion of agriculture. The growing demand by the industrialized world for agricultural products such as beef has led to millions of acres of forestland being bulldozed or burned to create pastures for cattle. Researchers in Central America have watched with dismay as large beef-raising operations have expanded into fragile ecosystems in countries such as Costa Rica, Guatemala, and Mexico. A tragic irony in this expansion of agriculture into tropical rain forests is that the soil underlying the trees is often unsuited for pastureland or raising other crops. Exposed to sunlight, the soil is quickly depleted of nutrients and often hardens. The once-verdant land becomes an arid desert, prone to erosion, that may never return to forest. As the soil becomes less fertile, hardy weeds begin to choke out the desirable forage plants, and the cattle ranchers move on to clear a fresh tract. 131
Deforestation Slash-and-Burn Agriculture Beef industry representatives often argue that their ranching practices are simply a form of slash-and-burn agriculture and do no permanent harm. It is true that many indigenous peoples in tropical regions have practiced slash-and-burn agriculture for millennia, with only a minimal impact on the environment. These farmers burn shrubs and trees to clear small plots of land. Anthropological studies have shown that the small plots these peasant farmers clear can usually be measured in square feet, not hectares as cattle ranches are, and are used for five to ten years. As fertility declines, the farmer clears a plot next to the depleted one. The farmer’s family or village will gradually rotate through the forest, clearing small plots and using them for a few years, and then shifting to new ground, until they eventually come back to where their ancestors began one hundred or more years before. As long as the size of the plots cleared by farmers remains small in proportion to the forest overall, slash-and-burn agriculture does not contribute significantly to deforestation. If the population of farmers grows, however, more land must be cleared with each succeeding generation. In many tropical countries, traditional slash-and-burn agriculture can then be as ecologically devastating as the more mechanized cattle ranching operations. Logging Although logging is not the leading cause of deforestation, it is a significant factor. Tropical forests are rarely clear-cut by loggers, as they typically contain hundreds of different species of trees, many of which have no commercial value. Loggers may select trees for harvesting from each stand. Selective harvesting is a standard practice in sustainable forestry. However, just as loggers engaged in the disreputable practice of high-grading across North America in the nineteenth century, so are loggers high-grading in the early twenty-first century in Malaysia, Indonesia, and other nations with tropical forests. High-grading is a practice in which loggers cut over a tract to remove the most valuable timber while ignoring the damage being done to the residual stand. The assumption is that, having logged over the tract once, the timber company will not be coming back. This practice stopped in North America, not because the timber companies voluntarily recognized the ecological damage they were doing but because they ran out of easily accessible, old-growth timber to cut. Fear of a timber famine caused logging companies to begin forest plantations and to practice sustainable forestry. 132
Deforestation
Percentage of Annual Deforestation by Country, 1990-1995
1 percent or more
From 0 to 1 percent
From –1 to 0 percent
Less than –1 percent
No data
Source: United Nations Food and Agriculture Organization
While global satellite photos indicate that significant deforestation has occurred in tropical areas, enough easily harvested old-growth forest remains in some areas that there is no economic incentive for timber companies to switch to sustainable forestry. Logging may also contribute to deforestation by making it easier for agriculture to encroach on forestlands. The logging company builds roads for use while harvesting trees. Those roads are then used by farmers and ranchers to move into the logged tracts, where they clear whatever trees the loggers have left. Environmental Impacts Despite clear evidence that deforestation is accelerating, the extent of the problem remains debatable. The United Nations Food and Agriculture Organization (FAO), which monitors deforestation worldwide, bases its statistics on measurements taken from satellite images. These data indicate that between 1980 and 1990, at least 159 million hectares (393 million acres) of land became deforested. The data also reveal that, in contrast to the intense focus on Latin America by both activists and scientists, the most dramatic loss of forestlands occurred in Asia. The deforestation rate in Latin America was 7.45 percent, while in Asia 11.42 percent of the forests vanished. Environmental activists are particularly con133
Deforestation cerned about forest losses in Indonesia and Malaysia, two countries where timber companies have been accused of abusing or exploiting native peoples in addition to engaging in environmentally damaging harvesting methods. Researchers outside the United Nations have challenged the FAO’s data. Some scientists claim the numbers are much too high, while others provide convincing evidence that the FAO numbers are too low. Few researchers, however, have tried to claim that deforestation on a global scale is not happening. In the 1990’s the reforestation of the Northern Hemisphere, while providing an encouraging example that it is possible to reverse deforestation, was not enough to offset the depletion of forestland in tropical areas. The debate among forestry experts centers on whether deforestation has slowed, and, if so, by how much. Deforestation affects the environment in a multitude of ways. The most obvious effect is a loss of biodiversity. When an ecosystem is radically altered through deforestation, the trees are not the only thing to disappear. Wildlife species decrease in number and in variety. As forest habitat
Results of Deforestation Population increase (human and animal) Requiring more: Agricultural land Rangeland
Forest products
Contributing to: Deforestation Resulting in:
Increased soil Loss of Reduced water Reduction in erosion by shelterbelt retention in biological wind and water soil diversity
Increased Desertification reservoir siltation
Increased flooding
Fuelwood scarcity
Higher Loss of endangered socioeconomic costs species
Source: Adapted from A. K. Biswas, “Envioronmental Concerns in Pakistan, with Special Reference to Water and Forests,” in Environmental Conservation, 1987.
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Deforestation shrinks through deforestation, many plants and animals become vulnerable to extinction. Many biologists believe that numerous animals and plants native to tropical forests will become extinct from deforestation before humans have a chance to even catalog their existence. Other effects of deforestation may be less obvious. Deforestation can lead to increased flooding during rainy seasons. Rainwater that once would have been slowed or absorbed by trees instead runs off denuded hillsides, pushing rivers over their banks and causing devastating floods downstream. The role of forests in regulating water has long been recognized by engineers and foresters. Flood control was, in fact, one of the motivations behind the creation of the federal forest reserves in the United States during the nineteenth century. More recently, disastrous floods in Bangladesh have been blamed on logging tropical hardwoods in the mountains of Nepal and India. Conversely, trees can also help mitigate against drought. Like all plants, trees release water into the atmosphere through the process of transpiration. As the world’s forests shrink in total acreage, fewer greenhouse gases such as carbon dioxide will be removed from the atmosphere, less oxygen and water will be released into it, and the world will become a hotter, dryer place. Scientists and policy analysts alike agree that deforestation is a major threat to the environment. The question is whether effective policies can be developed to reverse it or if short-term economic greed will win out over long-term global survival. Nancy Farm Männikkö See also: Biodiversity; Conservation biology; Endangered plant species; Erosion and erosion control; Forest management; Forests; Grazing and overgrazing; Multiple-use approach; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reforestation; Restoration ecology; Slash-and-burn agriculture; Soil contamination; Sustainable development. Sources for Further Study Bevis, William W. Borneo Log: The Struggle for Sarawak’s Forests. Seattle: University of Washington Press, 1995. Colchester, Marcus, and Larry Lohmann, eds. Struggle for Land and the Fate of the Forests. Atlantic Highlands, N.J.: Zed Books, 1993. Dean, Warren. With Broadax and Firebrand: The Destruction of the Brazilian Atlantic Forest. Berkeley: University of California Press, 1997. Richards, John F., and Richard P. Tucker, eds. World Deforestation in the Twentieth Century. Durham, N.C.: Duke University Press, 1988. 135
Deforestation Rudel, Thomas K., and Bruce Horowitz. Tropical Deforestation: Small Farmers and Land Clearing in the Ecuadorian Amazon. New York: Columbia University Press, 1993. Sponsel, Leslie E., Robert Converse Bailey, and Thomas N. Headland, eds. Tropical Deforestation: The Human Dimension. New York: Columbia University Press, 1996. Vajpeyi, Dhirendrea K., ed. Deforestation, Environment, and Sustainable Development: A Comparative Analysis. Westport, Conn.: Praeger, 2001. Wilson, Edward O. The Future of Life. New York: Alfred A. Knopf, 2001.
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DEMOGRAPHICS Type of ecology: Population ecology Demography is the study of the numbers of organisms born in a population within a certain time period, the rate at which they survive to various ages, and the number of offspring that they produce. Many different patterns of birth, survival, and reproduction are found among organisms in nature.
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o animal lives forever. Instead, each individual has a generalized life history that begins with fertilization and then goes through embryonic development, a juvenile stage, a period in which it produces offspring, and finally death. There are many variations on this general theme. Still, the life of each organism has two constants: a beginning and an end. Many biologists are fascinated by the births and deaths of individuals in a population and seek to understand the processes that govern the production of new individuals and the deaths of those already present. The branch of biology that deals with such phenomena is called demography. The word “demography” is derived from Greek; demos means “people.” For many centuries, demography was applied almost exclusively to humans as a way of keeping written records of new births, marriages, deaths, and other socially relevant information. During the first half of the twentieth century, biologists gradually began to census populations of naturally occurring organisms to understand their ecology more fully. Biologists initially focused on vertebrate animals, particularly game animals and fish. Beginning in the 1960’s and 1970’s, invertebrate animals, plants, and microbes also became subjects of demographic studies. Studies clearly show that different species of organisms vary greatly in their demographic properties. Often, there is a clear relationship between those demographic properties and the habitat in which these organisms live. Demographic Parameters When conducting demographic studies, a demographer must gather certain types of basic information about the population. The first is the number of new organisms that appear in a given amount of time. There are two ways that an organism can enter a population: by being born into it or by immigrating from elsewhere. Demographers generally ignore immigration and concentrate instead on newborns. The number of new individuals 137
Demographics born into a population during a specific time interval is termed the natality rate. The natality rate is often based on the number of individuals already in the population. For example, if ten newborns enter a population of a thousand individuals during a given time period, the natality rate is 0.010. A specific time interval must be expressed (days, months, years) for the natality rate to have any meaning. A second demographic parameter is the mortality rate, which is simply the rate at which individuals are lost from the population by death. Losses that result from emigration to a different population are ignored by most demographers. Like the natality rate, the mortality rate is based on the number of individuals in the population, and it reflects losses during a certain time period. If calculated properly, the natality and mortality rates are directly comparable, and one can subtract the latter from the former to provide an index of the change in population size over time. The population increases whenever natality exceeds mortality and decreases when the reverse is true. The absolute value of the difference denotes the rate of population growth or decline. When studying mortality, demographers determine the age at which organisms die. Theoretically, each species has a natural life span that no individuals can surpass, even under the most ideal conditions. Normally, however, few organisms reach their natural life span, because conditions are far from ideal in nature. Juveniles, young adults, and old adults can all die. When trying to understand the dynamics of a population, demographers therefore note whether the individuals are dying mainly as adults or mainly as juveniles. Patterns of Survival Looking at it another way, demographers want to know the pattern of survival for a given population. This can best be determined by identifying a cohort, which is defined as a group of individuals that are born at about the same time. That cohort is then followed over time, and the number of survivors is counted at set time intervals. The census stops after the last member of the cohort dies. The pattern of survival exhibited by the whole cohort is called its survivorship. Ecologists have examined the survivorship patterns of a wide array of species, including vertebrate animals, invertebrates, plants, fungi, algae, and even microscopic organisms. They have also investigated organisms from a variety of habitats, including oceans, deserts, rain forests, mountain peaks, meadows, and ponds. Survivorship patterns vary tremendously. Some species have a survivorship pattern in which the young and middle-aged individuals have a high rate of survival, but old individu138
Demographics als die in large numbers. Several species of organisms that live in nature, such as mountain sheep and rotifers (tiny aquatic invertebrates), exhibit this survivorship pattern. At the other extreme, many species exhibit a survivorship pattern in which mortality is heaviest among the young. Those few individuals that are fortunate enough to survive the period of heavy mortality then enjoy a high probability of surviving until the end of their natural life span. Examples of species that have this pattern include marine invertebrates such as sponges and clams, most species of fish, and parasitic worms. An intermediate pattern is also observed, in which the probability of dying stays relatively constant as the cohort gets older. American robins, gray squirrels, and hydras all display this pattern. These survivorship patterns are usually depicted on a graph that has the age of individuals in the cohort on the x-axis and the number of survivors on the y-axis. Each of the three survivorship patterns gives a different curve when the number of survivors is plotted as a function of age. In the first pattern (high survival among juveniles), the curve is horizontal at first but then swings downward at the right of the graph. In the second pattern (low survival among juveniles), the curve drops at the left of the graph but then levels out to form a horizontal line. The third survivorship pattern (constant mortality throughout the life of the cohort) gives a straight line that runs from the upper-left corner of the graph to the lower right (this is best seen when the y-axis is expressed as the logarithm of the number of survivors). In the first half of the twentieth century, demographers Raymond Pearl and Edward S. Deevey labeled each survivorship pattern: Type I is high survival among juveniles, type II is constant mortality through the life of the cohort, and type III is low survival among juveniles. That terminology became well entrenched in the biological literature by the 1950’s. Few species exhibit a pure type I, II, or III pattern, however; instead, survivorship varies so that the pattern may be one type at one part of the cohort’s existence and another type later. Perhaps the most common survivorship pattern, especially among vertebrates, is composed of a type III pattern for juveniles and young adults followed by a type I pattern for older adults. This pattern can be explained biologically. Most species tend to suffer heavy juvenile mortality because of predation, starvation, cannibalism, or the inability to cope with a stressful environment. Juveniles that survive this hazardous period then become strong adults that enjoy relatively low mortality. As time passes, the adults reach old age and ultimately fall victim to disease, predation, and organ-system failure, thus causing a second downward plunge in the survivorship curve. 139
Demographics Patterns of Reproduction Demographers are not interested only in measuring the survivorship of cohorts. They also want to understand the patterns of reproduction, especially among females. Different species show widely varying patterns of reproduction. For example, some species, such as octopuses and certain salmon, reproduce only once in their life and then die soon afterward. Others, such as humans and most birds, reproduce several or many times in their lives. Species that reproduce only once accumulate energy throughout their lives and essentially put all of it into producing young. Reproduction essentially exhausts them to death. Conversely, those that reproduce several times devote only a small amount of their energy to each reproductive event. Species also vary in their fecundity, which is the number of offspring that an individual makes when it reproduces. Large mammals have low fecundity, because they produce only one or two progeny at a time. Birds, reptiles, and small mammals have higher fecundity because they typically produce a clutch or litter of several offspring. Fish, frogs, and parasitic worms have very high fecundity, producing hundreds or thousands of offspring. A species’ pattern of reproduction is often related to its survivorship. For example, a species with low fecundity or one that reproduces only once tends to have type I or type II survivorship. Conversely, a species that produces huge numbers of offspring generally shows type III survivorship. Many biologists are fascinated by this interrelationship between survivorship and reproduction. Beginning in the 1950’s, some demographers proposed mathematically based explanations as to how the interrelationship might have evolved as well as the ecological conditions in which various life histories would be expected. For example, some demographers predicted that species with low fecundity and type I survival should be found in undisturbed, densely populated areas (such as a tropical rain forest). In contrast, species with high fecundity and type III survival should prevail in places that are either uncrowded or highly disturbed (such as an abandoned farm field). Ecologists have conducted field studies of both plants and animals to determine whether the patterns that actually occur in nature fit the theoretical predictions. In some cases the predictions were upheld, but in others they were found to be wrong and had to be modified. Age Structures and Sex Ratios Another feature of a population is its age structure, which is simply the number of individuals of each age. Some populations have an age struc140
Demographics ture characterized by many juveniles and only a few adults. Two situations could account for such a pattern. First, the population could be rapidly expanding, with the adults successfully reproducing many progeny that are enjoying high survival. Second, the population could be producing many offspring that have type III survival. In this second case, the size of the population can remain constant or even decline. Other populations have a different age structure, in which the number of juveniles only slightly exceeds the number of adults. Those populations tend to remain relatively constant over time. Still other populations have an age structure in which there are relatively few juveniles and many adults. Those populations are probably declining or are about to decline because the adults are not successfully reproducing. Since most animals are unisexual, an important demographic characteristic of a population is its sex ratio, defined as the ratio of males to females. While the ratio for birds and mammals tends to be 1:1 at conception (the fertilization of an egg), it tends to be weighted toward males at birth, because female embryos are slightly less viable. After birth, the sex ratio for mammals tends to favor females, because young males suffer higher mortality. The posthatching ratio in birds tends to remain skewed toward males, because females devote considerable energy to producing young and suffer higher mortality. As a result, male birds must compete with one another for the opportunity to mate with the scarcer females. The Age-Specific Approach To understand the demography of a particular species, one must collect information about its survivorship and reproduction. The best survivorship data are obtained when a demographer follows a group of newly born organisms (this being a cohort) over time, periodically counting the survivors until the last one dies. Although that sounds relatively straightforward, many factors complicate the collection of survivorship data; demographers must be willing to adjust their methods to fit the particular species and environmental conditions. First, a demographer must decide how many newborns should be included in the cohort. Survivorship is usually based on one thousand newborns, but few studies follow that exact number. Instead, demographers follow a certain number of newborns and multiply or divide their data so that the cohort is expressed as one thousand newborns. For example, one may choose to follow five hundred newborns; the number of survivors is then multiplied by two. Demographers generally consider cohorts composed of fewer than one hundred newborns to be too small. Second, methods of determining survivorship are much more different for highly motile 141
Demographics organisms, such as mammals and birds, than for more sedentary ones, such as bivalves (oysters and clams). To determine survivorship of a sedentary species, demographers often find some newborns during an initial visit to a site and then periodically revisit that site to count the number of survivors. Highly motile animals are much more difficult to census because they do not stay in one place waiting to be counted. Vertebrates and large invertebrates can be tagged, and individuals can be followed by subsequently recapturing them. Some biologists use small radio transmitters to follow highly active species. The demography of small invertebrates such as insects is best determined when there is only one generation per year and members of the population are all of the same age-class. For such species, demographers merely count the number present at periodic intervals. Third, the frequency of the census periods varies from species to species. Short-lived species, such as insects, must be censused every week or two. Longer-lived species need to be counted only once a year. Fourth, the definition of a “newborn” may be troublesome, especially for species with complex life cycles. Demographic studies usually begin with the birth of an infant. Some would argue, however, that the fetus should be included in the analysis because the starting point is really conception. Many sedentary marine invertebrates (sponges, starfish, and barnacles) have highly motile larval stages, and these should be included in the analysis for survivorship to be completely understood. Parasitic roundworms and flatworms that have numerous juvenile stages, each found inside a different host, are particularly challenging to the demographer. The Time-Specific Approach The survivorship of long-lived species, such as large mammals, is really impossible to determine by the methods given above. Because of their sheer longevity, one could not expect a scientist to be willing to wait decades or centuries until the last member of a cohort dies. Demographers attempt to overcome this problem by using the age distribution of organisms that are alive at one time to infer cohort survivorship. This is often termed a “horizontal” or “time-specific” approach, as opposed to the “vertical” or “age-specific” approach that requires repeated observations of a single cohort. For example, one might construct a time-specific survivorship curve for a population of fish by live-trapping a sufficiently large sample, counting the rings on the scales on each individual (which for many species is correlated with the age in years), and then determining the number of oneyear-olds, two-year-olds, and so on. Typically, demographers who use age distributions to infer age-specific survivorship automatically assume that natality and mortality remain constant from year to year. That is often not 142
Demographics the case, however, because environmental conditions often change over time. Thus, demographers must be cautious when using age distribution data to infer survivorship. Methods for determining fecundity are relatively straightforward. Typically, fertile individuals are collected, their ages are determined, and the number of progeny (eggs or live young) are counted. Species that reproduce continually (parasitic worms) or those that reproduce several times a year (small mammals and many insects) must be observed over a period of time. Demographers usually want to determine whether the production of new offspring (natality) balances the losses attributable to mortality. To accomplish this, they construct a life table, which is a chart with several columns and rows. Each row represents a different age of the cohort, from birth to death. The columns show the survival and fecundity of the cohort. By recalculating the survivorship and fecundity information, demographers can compute several interesting aspects of the cohort, including the life expectancy of individuals at different ages, the cohort’s reproductive value (which is the number of progeny that an individual can expect to produce in the future), the length of a generation for that species, and the growth rate for the population. Uses of Demography Demographic techniques have been applied to nonhuman species, particularly by wildlife managers, foresters, and ecologists. Wildlife managers seek to understand how a population is surviving and reproducing within a certain area, and therefore to determine whether it is increasing or decreasing over time. With that information, a wildlife biologist can then estimate the effect of hunting or other management practice on the population. By extension, fisheries biologists can also make use of demographic techniques to determine the growth rate of the species of interest. If the population is determined to be increasing, it can be harvested without fear of depleting the population. Alternatively, one can conduct demographic analyses to see whether certain species are being overfished. An often unappreciated benefit of survivorship analyses is that they can help ecologists pinpoint factors that limit population growth in an area. This may be especially important in efforts to prevent rare animals and plants from becoming extinct. Once the factor is identified, the population can be appropriately managed. Increasing amounts of public and private money are allocated each year to biologists who conduct demographic studies on rare species. Kenneth M. Klemow 143
Demographics See also: Adaptive radiation; Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Convergence and divergence; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Human population growth; Insect societies; Nonrandom mating, genetic drift, and mutation; Population analysis; Population fluctuations; Population genetics; Population growth; Reproductive strategies. Sources for Further Study Begon, Michael, John L. Harper, and Colin R. Townsend. Ecology: Individuals, Populations, and Communities. 3d ed. Boston: Blackwell, 1996. Begon, Michael, Martin Mortimer, and David J. Thompson. Population Ecology: A Unified Study of Animals and Plants. 3d ed. Cambridge, Mass.: Blackwell, 1996. Brewer, Richard. The Science of Ecology. 2d ed. Fort Worth, Tex.: Saunders College Publishing, 1994. Elseth, Gerald D., and Kandy D. Baumgardner. Population Biology. New York: Van Nostrand, 1981. Gotelli, Nicholas J. A Primer of Ecology. 2d ed. Sunderland, Mass.: Sinauer Associates, 1998. Hutchinson, G. Evelyn. An Introduction to Population Ecology. New Haven, Conn.: Yale University Press, 1978. Smith, Robert Leo. Elements of Ecology. 4th ed. San Francisco, Calif.: Benjamin/Cummings, 2000. Wilson, Edward O., and William Bossert. A Primer of Population Biology. Sunderland, Mass.: Sinauer Associates, 1977.
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DENDROCHRONOLOGY Types of ecology: Evolutionary ecology; Paleoecology Dendrochronology is the science of examining and comparing growth rings in both living and aged woods to draw inferences about past ecosystems and environmental conditions.
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n forested regions with seasonal climates, trees produce a growth ring to correspond with each growing season. At the beginning of the growing season, when conditions are optimum, the vascular cambium produces many files of large xylem cells that form wood. As the conditions become less optimal, the size and number of cells produced decreases until growth stops at the end of the growing season. These seasonal differences in size and number of cells produced are usually visible to the unaided eye. The layers produced during rapid early growth appear relatively light-colored because the volume of the large cells is primarily intracellular space. These layers are frequently called springwood because in northern temperate regions spring is the beginning of the growing season. Wood formed later, summerwood, is darker because the cells are smaller and more tightly compacted. The juxtaposition of dark summerwood of one year with the light springwood of the following year marks a distinct line between growth increments. The width of the ring between one line and the next measures the growth increment for a single growing season. If there is a single growing season per year, as in much of the temperate world, then a tree will produce a single annual ring each year. Tree Rings and Climate Leonardo da Vinci is credited with counting tree rings in the early 1500’s to determine “the nature of past seasons,” but it was not until the early 1900’s that dendrochronology was established as a science. Andrew Douglass, an astronomer interested in relating sunspot activity to climate patterns on Earth, began to record the sequences of wide and narrow rings in the wood of Douglas firs and ponderosa pines in the American Southwest. Originally, trees were cut down in order to examine the ring patterns, but in the 1920’s Douglass began to use a Swedish increment borer to remove core samples from living trees. This instrument works like a hollow drill that is screwed into a tree by hand. When the borer reaches the center of the tree it is unscrewed, and the wood core sample inside is withdrawn with the borer. The small hole quickly fills with sap, and the tree is unharmed. 145
Dendrochronology Borers range in size from 20 centimeters to 100 centimeters or more in length, so with care, samples can be taken from very large, very old living trees. Counting backward in the rings is counting backward in time. By correlating the size of a ring with the known regional climate of the year the ring was produced, a researcher can calibrate a core sample to indicate the surrounding climate during any year of the tree’s growth. By extending his work to sequoias in California, Douglass was able to map a chronology extending back three thousand years. Tree Rings and History In order to extend his chronologies so far back in time, Douglass devised the method of cross-dating. By matching distinctive synchronous ring patterns from living and dead trees of the same species in a region, researchers can extend the pattern further into the past than the lifetime of the younger tree. Archaeologists quickly realized that this was a tool that could help to assign the age of prehistoric sites by determining the age of wood artefacts and construction timbers. In this way archaeologists could calculate the age of pre-Columbian southwestern ruins, such as the cliff dwellings at Mesa Verde, Arizona, by cross-dating living trees with dead trees and the latter with timbers from the sites. In 1937 Douglass established the Laboratory of Tree-Ring Research at the University of Arizona, which continues to be a major center of dendrochronological research. Fine-Tuning In the mid-1950’s Edmund Schulman confirmed the great age of living bristlecone pines in the Inyo National Forest of the White Mountains of California. In 1957 he discovered the Methuselah Tree, which was more than forty-six hundred years old. The section of forest in which he worked is now known as the Ancient Bristlecone Pine Forest. During the next thirty years, Charles Ferguson extended the bristlecone chronology of this area back 8,686 years. This sequence formed the basis for calibrating the technique of radiocarbon dating. In the 1960’s, radiocarbon analysis began to be used to determine the age of organic (carbon-based) artefacts from ancient sites. It has the advantage of being applicable to any item made of organic material but the disadvantage of having a built-in uncertainty of 2 percent or more. Tree-ring chronologies provide an absolute date against which radiocarbon analyses of wood samples from a site can be compared. At about the same time, Valmore LaMarche, a young geologist, began to study root growth of the ancient trees to determine how they could be used to predict the erosional history of a site. By cross-referencing growth ring 146
Dendrochronology
Dendrochronology, or tree-ring counting, can be used to assess the age of a tree because the width of the ring between one line and the next measures the growth increment for a single growing season. (PhotoDisc)
asymmetry to degree of exposure and slope profiles, he was able to estimate rates of soil erosion and rock weathering, which in turn could be cross-referenced to the climatic conditions predicted by growth rings in the stem. LaMarche and his colleagues, particularly Harold Fritts, continued to “fine-tune” the reading of growth rings to be able to take into account factors such as soil characteristics, frost patterns, and daily, weekly, and monthly patterns. The Oldest Tree The Methuselah Tree, mentioned above, is the oldest known living tree. Schulman also cored a 4,700-year-old living specimen in the White Mountains, but he did not name it or identify its location. While most of the living specimens older than 4,000 years are found in the White Mountains, the oldest living tree was discovered in the Wheeler Peak area of what is now Great Basin National Park in eastern Nevada. This tree, variously known as WPN-114 and the Prometheus Tree, was estimated to be between 4,900 and 5,100 years old when it was cut down in 1964 as part of a research project. The controversy that followed has left many interesting but unanswered questions. Marshall D. Sundberg 147
Dendrochronology See also: Evolution of plants and climates; Forests; Global warming; Oldgrowth forests; Paleoecology. Sources for Further Study Cohen, Michael P. Garden of Bristlecones: Tales of Change in the Great Basin. Reno: University of Nevada Press, 2000. Cook, E. R., and L. A. Kairiustis, eds. Methods of Dendrochronology: Applications in the Environmental Sciences. Boston: Kluwer Academic, 1987. Harlow, William M. Inside Wood: Masterpiece of Nature. Washington, D.C.: The American Forestry Association, 1970. McGraw, Donald J. Andrew Ellicott Douglass and the Role of the Giant Sequoia in the Development of Dendrochronology. Lewiston, N.Y.: Edwin Mellen Press, 2001. Stokes, Marvin A., and Terah L. Smiley. An Introduction to Tree-Ring Dating. Tucson: University of Arizona Press, 1996.
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DESERTIFICATION Type of ecology: Ecosystem ecology Desertification is the degradation of arid, semiarid, and dry, subhumid lands as a result of human activities or climatic variations, such as a prolonged drought.
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esertification is recognized by scientists and policymakers as a major economic, social, and environmental problem in more than one hundred countries. It impacts about one billion people throughout the world. Deserts are climatic regions that receive fewer than 25 centimeters (10 inches) of precipitation per year. They constitute the most widespread of all climates of the world, occupying 25 percent of the earth’s land area. Most deserts are surrounded by semiarid climates referred to as steppes, which occupy 8 percent of the world’s lands. Deserts occur in the interior of continents, on the leeward side of mountains, and along the west sides of continents in subtropical regions. All the world’s deserts risk further desertification. Deserts of the World The largest deserts are in North Africa, Asia, Australia, and North America. Four thousand to six thousand years ago, these desert areas were less extensive and were occupied by prairie or savanna grasslands. Rock paintings found in the Sahara Desert show that humans during this era hunted buffalo and raised cattle on grasslands where giraffes browsed. The region near the Tigris and Euphrates Rivers in the Middle East was also fertile. In the desert of northwest India, cattle and goats were grazed, and people lived in cities that have long since been abandoned. The deserts in the southwestern region of North America appear to have been wetter, according to the study of tree rings (dendrochronology) from that area. Ancient Palestine, which includes the Negev Desert of present-day Israel, was lush and was occupied by three million people. Scientists use various methods to determine the historical climatic conditions of a region. These methods include studies of the historical distribution of trees and shrubs determined by the deposit patterns in lakes and bogs, patterns of ancient sand dunes, changes in lake levels through time, archaeological records, and tree rings. The earth’s creeping deserts supported approximately 720 million people, or one-sixth of the world’s population, in the late 1970’s. Accord149
Desertification ing to the United Nations, the world’s hyperarid or extreme deserts are the Atacama and Peruvian Deserts (located along the west coast of South America), the Sonoran Desert of North America, the Takla Makan Desert of Central Asia, the Arabian Desert of Saudi Arabia, and the Sahara Desert of North Africa, which is the largest desert in the world. The arid zones surround the extreme desert zones, and the semiarid zones surround the arid zones. Areas that surround the semiarid zones have a high risk of becoming desert. By the late 1980’s the expanding deserts were claiming about 15 million acres of land per year, or an area approximately the size of the state of West Virginia. The total area threatened by desertification equaled about 37.5 million square kilometers (14.5 million square miles). Causes of Desertification Desertification results from a two-prong process: climatic variations and human activities. First, the major deserts of the world are located in areas of high atmospheric pressure, which experience subsiding dry air unfavorable to precipitation. Subtropical deserts have been experiencing prolonged periods of drought since the late 1960’s, which causes these areas to be dryer than usual. The problem of desertification was identified in the late 1960’s and early 1970’s as a result of severe drought in the Sahel Desert, which extends along the southern margin of the Sahara in West Africa. Rainfall has declined an average of 30 percent in the Sahel. One set of scientific studies of the drought focuses on changes in heat distribution in the ocean. A correlation has been found between sea surface temperatures and the reduction of rainfall in the Sahel. The Atlantic Ocean’s higher surface temperatures south of the equator and lower temperatures north of the equator west of Africa are associated with lower precipitation in northern tropical Africa. However, the cause for the change in sea surface temperature patterns has not been determined. Another set of studies is associated with land-cover changes. Lack of rain causes the ground and soils to get extremely dry. Without vegetative cover to hold it in place, thin soil blows away. As the water table drops from the lack of the natural recharge of the aquifers and the withdrawal of water by desert dwellers, inhabitants are forced to migrate to the grasslands and forests at fringes of the desert. Overgrazing, overcultivation, deforestation, and poor irrigation practices (which can cause salinization of soils) eventually lead to a repetition of the process, and the desert begins to encroach. These causes are influenced by changes in population, climate, and social and economic conditions. 150
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Desertification of Africa Mediterranean Sea
Tropic of Cancer
Gulf of Guinea Equator True desert Acute risk of desertification
Indian Ocean Atlantic Ocean
Moderate to great risk
Tropic of Capricorn
The fundamental cause of desertification, therefore, is human activity. This is especially true when environmental stress occurs because of seasonal dryness, drought, or high winds. Many different forms of social, economic, and political pressure cause the overutilization of these dry lands. People may be pushed onto unsuitable agricultural land because of land shortages, poverty, and other forces, while farmers overcultivate the fields in the few remaining fertile land areas. Atmospheric Consequences A reduction in vegetation cover and soil quality may impact the local climate by causing a rise in temperatures and a reduction in moisture. This can, in turn, impact the area beyond the desert by causing changes in the 151
Desertification climate and atmospheric patterns of the region. It is predicted that by the year 2050 substantial changes in vegetation cover in humid and subhumid areas will occur and cause substantial regional climatic changes. Desertification is a global problem because it causes the loss of biodiversity as well as the pollution of rivers, lakes, and oceans. As a result of excessive rainfall and flooding in subhumid areas, fields lacking sufficient vegetation may be eroded by runoff. Greenhouse Effect Desertification and even the efforts to combat it may be impacting climatic change because of the emission and absorption of greenhouse gases. The decline in vegetation and soil quality can result in the release of carbon, while revegetation can influence the absorption of carbon from the atmosphere. The use of fertilizer to reclaim dry lands may cause an increase in nitrous oxide emissions. Although scientists involved in studies of rising greenhouse gases have not been able to gather evidence conclusive enough to support such theories, evidence of the impact of greenhouse gases on global warming continues to accumulate. Policy Actions As a result of the Sahelian drought, which lasted from 1968 to 1973, representatives from various countries met in Nairobi, Kenya, in 1977 for a United Nations conference on desertification. The conference resulted in the Plan of Action to Combat Desertification. The plan listed twenty-eight measures to combat land degradation by national, regional, and international organizations. A lack of adequate funding and commitment by governments caused the plan to fail. When the plan was assessed by the United Nations Environment Programme (UNEP), it found that little had been accomplished and that desertification had increased. As a result of the 1977 United Nations conference, several countries developed national plans to combat desertification. One example is Kenya, where local organizations have worked with primary schools to plant five thousand to ten thousand seedlings per year. One U.S.-based organization promotes reforestation by providing materials to establish nurseries, training programs, and extension services. Community efforts to combat desertification have been more successful, and UNEP has recognized that such projects have a greater success rate than top-down projects. The Earth Summit, held in Rio de Janeiro, Brazil, in 1992, supported the concept of sustainable development at the community level to combat the problem of desertification. Roberto Garza 152
Desertification See also: Biomes: determinants; Biomes: types; Deserts; Ecosystems: definition and history; Erosion and erosion control; Global warming; Greenhouse effect; Hydrologic cycle; Rain forests and the atmosphere; Soil; Soil contamination. Sources for Further Study Bryson, Reid A., and Thomas J. Murray. Climates of Hunger: Mankind and the World’s Changing Weather. Madison: University of Wisconsin Press, 1977. Glantz, Michael H., ed. Desertification: Environmental Degradation in and Around Arid Lands. Boulder, Colo.: Westview Press, 1977. Grainger, Alan. Desertification: How People Make Deserts, Why People Can Stop, and Why They Don’t. London: International Institute for Environment and Development, 1982. Hulme, Mike, and Mick Kelly. “Exploring the Links Between Desertification and Climate Change.” Environment, July/August, 1993. Mainguet, Monique. Aridity: Droughts and Human Development. New York: Springer, 1999. _______. Desertification: Natural Background and Human Mismanagement. 2d ed. New York: Springer-Verlag, 1994. Matthews, Samuel W. “What’s Happening to Our Climate.” National Geographic, November, 1976. Postel, Sandra. “Land’s End.” Worldwatch, May/June, 1989.
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DESERTS Types of ecology: Biomes; Ecosystem ecology Regions characterized by 10 inches or less of precipitation per year are considered deserts. Desert ecosystems are subject to disruption by human activities.
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eserts are regions, or biomes, too dry to support grasslands or forest vegetation but with enough moisture to allow specially adapted plants to live. In deserts, hot days alternate with cold nights. Ninety percent of incoming solar radiation reaches the ground during the day, and 90 percent of that is radiated back out into space at night, the result of the absence of clouds, low humidity, and sparse vegetation. The surface of the ground in desert areas is devoid of a continuous layer of plant litter and is usually rocky or sandy. Nutrient cycling in deserts is tight, with phosphorus and nitrogen typically in short supply. How Deserts Form Most large landmasses have interior desert regions. Air masses blown inland from coastal areas lose their moisture before reaching the interior. Examples include the Gobi Desert in Mongolia and parts of the Sahara Desert in Africa. Another factor in the formation of deserts is the rain-shadow effect. If moisture-laden air masses bump up against a mountain range, the air mass is deflected upward. As the air mass rises, it cools, and moisture precipitates as rain or snow on the windward side of the mountain range. As the air mass passes over the mountain range, it begins to descend. Because it lost most of its moisture on the windward side, the air mass is dry. As it descends, the air heats up, creating drier conditions on the leeward side of the mountain range. Sometimes these differences in moisture are so pronounced that different plant communities grow on the windward and leeward sides. Latitude can also influence desert formation. Most deserts lie between 15 and 35 degrees north or south latitude. At the equator, the sun’s rays hit the earth straight on. Moist equatorial air, warmed by intense heat from the sun, rises. As this air rises, it cools and loses its moisture, which falls as rain; this is why it usually rains every day in the equatorial rain forests. The Coriolis force causes the air masses to veer off, to the north in the Northern Hemisphere and to the south in the Southern Hemisphere. The now-dry air begins to descend and warm, reaching the ground between 15 and 35 154
Deserts degrees north and south latitude, creating the belt of deserts circling the globe between these latitudes. Deserts can also form along coastlines next to cold-water ocean currents, which chill the air above them, decreasing their moisture content. Offshore winds blow the air above cold ocean waters back out to sea. In deserts, rain is infrequent, creating great hardships for the native plants and animals. The main source of moisture for the plants and animals of coastal deserts is fog. Types of Deserts Depending upon whether the precipitation comes from rain or snow, deserts can be divided into hot (rain) or cold (snow) deserts. The deserts of Arabia, Australia, Chihuahua, Kalahari, Monte, Sonora, and Thar are all considered hot deserts, found in lower latitudes. Cold deserts, found at higher latitudes, include the Atacama, Gobi, Basin, Iranian, Namib, and Turkestan deserts. Regardless of whether the desert is hot or cold, organisms living within desert biomes have to adapt to cope with the scarcity of water and violent swings of temperature. North America contains four different deserts that are usually defined by their characteristic vegetation, which ecologists call indicator species.
Although desert climates are characterized by less than 10 inches of precipitation per year, they can support a broad variety of plant and animal life adapted to survive such arid climates. Cacti, for example, have developed a method of photosynthesis that maximizes water retention, as well as protective spines that inhibit predators that might feed on them. (PhotoDisc) 155
Deserts In Mexico’s Chihuahuan Desert, lechuguilla (Agave lechuguilla) is the indicator species. Fibers from lechuguilla can be made into nets, baskets, mats, ropes, and sandals. Its stems yield a soap substitute, and its pulp has been used as a spot remover. Certain compounds in lechuguilla are poisonous and were once used to poison the tips of arrows and as fish poisons. Two of the most common plants in the Chihuahuan Desert are creosote bush (Larrea divaricata) and soaptree yucca (Yucca elata). Cacti in this desert are numerous and diverse, especially the prickly pears and chollas. The Joshua tree (Yucca brevifolia), is the indicator species of the Mojave Desert in Southern California. Nearly one-fourth of all the Mojave Desert plants are endemics, including the Joshua tree, Parry saltbush, Mojave sage, and woolly bur sage. The Great Basin Desert, situated between the Sierra Nevada and the Rocky Mountains, is a cold desert, with fewer plant species than other North American deserts. Great Basin Desert plants are small to mediumsize shrubs, usually sagebrushes or saltbushes. The indicator species of the Great Basin is big sagebrush (Artemisia tridentata). Other common plants are littleleaf horsebrush and Mormon tea. The major cactus species is the Plains prickly pear. In the Sonoran Desert in Mexico, California, and Arizona, plants come in more shapes and sizes than in the other North American deserts, especially in the Cactaceae. The indicator species of the Sonoran Desert is the saguaro cactus (Carnegiea gigantecus). The Sahara Desert of northern Africa is the world’s largest, at 3.5 million square miles. The Northern Hemisphere also contains the Arabian, Indian, and Iranian deserts and the Eurasian deserts: the Takla Makan, Turkestan, and Gobi. Deserts in the Southern Hemisphere include the Australian, Kalahari, Namib, Atacama-Peruvian (the world’s driest), and the Patagonian. Desert Vegetation Many typical desert perennial plants, such as members of the Cactaceae (the cactus family), have thick, fleshy stems or leaves with heavy cuticles, sunken stomata (pores), and spiny defenses against browsing animals. The spines also trap a layer of air around the plant, retarding moisture loss. Desert plants, many of which photosynthesize using C4 or CAM (crassulean acid metabolism), live spaced out from other plants. Many desert plants are tall and thin, to minimize the surface area exposed to the strongest light. For example, the entire stem of the Saguaro cactus is exposed to sunlight in the early morning and late afternoon; at noon, only the tops 156
Deserts of the stems receive full sun. These traits allow the plants to cope with heat stress and competition for water and avoid damage from herbivores (plant-eating animals). Where the mixture of heat and water stress is less severe, perennial bushes of the Chenopodiaceae (goosefoot family) or Asteraceae (sunflower family) form clumps of vegetation surrounded by bare ground. Numerous annuals, called ephemerals, can grow prolifically, if only briefly, following rainfall. Unrelated plant families from different desert areas of the world show similar adaptations to desert conditions. This has resulted from a process called convergent evolution. Animal Life in Deserts Animals living in the desert include mammals, birds and fish, reptiles and amphibians, and insects and spiders. A few examples of mammals include bats, bighorn sheep, bobcats, and coyotes. Desert bats, members of the suborder Microchioptera, are often considered to be flying mice, but they are more closely related to primates. Bats are unique among mammals because they can fly. Most bat species also possess a system of acoustic orientation, technically known as echolocation. The bighorn sheep lives in dry, desert mountain ranges and foothills near rocky cliffs. Its body is compact and muscular; the muzzle is narrow and pointed; the ears, short and pointed; the tail, very short. The fur is deerlike and usually a shade of brown, with whitish rump patches. Bighorns are grazers, consuming grasses, sedges, and other low-lying plants. The bobcat (Felis rufus) has long legs, large paws, and a short tail (six to seven inches long), with average body weight of fifteen to twenty pounds. However, it is quite fierce and is equipped to kill animals as large as deer. The desert coyote (Canis latrans), a member of the dog family, weighs about twenty pounds, less than half the weight of its mountain kin, which can weigh up to fifty pounds. Its body color is light gray or tan, which helps it to reflect heat and blend in in the desert. A variety of birds reside in the desert due to the abundance of insects and spiders. Golden eagles (Aquila chrysaetos) get their name from the golden feathers on the back of their necks. They are birds of the open country, building large stick nests in trees or cliff walls where they have plenty of room to maneuver. Adults weigh 9 to 12.5 pounds, with females usually larger than males. Ravens (Corvus corax) are the largest birds of the crow family, averaging twenty-four inches tall, with a wingspan of forty-six to fifty-six inches. Ravens are strong fliers that can soar like a hawk, and they may form large flocks of over several hundred individuals during their au157
Deserts tumn migration. The American turkey (Meleagris gallopavo), the largest upland game bird in North America, is thirty-six to forty-eight inches long, with a four- to five-foot wingspan. Males average ten inches longer than females, which are paler and of a more buff color. Turkeys inhabit a variety of habitats from open grassland and fields to open woodlands and mature deciduous or coniferous forests. Many species of reptiles and amphibians live in the desert, including the black-collared lizard (genus Crotaphytus), bullfrog (Rana catesbeiana), desert dinosaur (orders Saurischia and Ornithischia), desert iguana (Dispsosaurus dorsalis), rattlesnake (genus Crotalus), and many others. Insects and spiders include dragonflies (suborder Anisoptera), scorpions (order Scorpionida), and black widow spiders (Latrodectus hesperus). It is nothing short of a miracle that such an abundance of life, both plant and animal, can survive in the extreme conditions of the desert. Animal Survival in the Desert Among the thousands of desert animal species, many have remarkable behavioral and structural adaptations for avoiding excess heat. Equally ingenious are the diverse mechanisms various animal species have developed to acquire, conserve, recycle, and actually manufacture water. Certain species of birds, such as the Phanopepla, breed during the relatively cool spring, then leave the desert for cooler areas at higher elevations or along the Pacific coast. The Costa’s hummingbird begins breeding in late winter and leaves in late spring when temperatures become extreme. Many birds, as well as other mammals and reptiles, are crepuscular, meaning they are active only at dusk and again at dawn. Many animals, including bats, many snakes, most rodents, and some larger animals such as foxes and skunks, are nocturnal, restricting all their activities to the cooler temperatures of the night and sleeping in a cool den, cave, or burrow by day. A few desert animals, such as the round-tailed ground squirrel, sleep away the hottest part of summer and also hibernate in winter to avoid the cold season. Yet other animals, such as desert toads, remain dormant deep in the ground until the summer rains fill ponds. They then emerge, breed, lay eggs, and replenish their body reserves of food and water for another long period. Various mechanisms are employed to dissipate heat absorbed by desert animals. Many mammals have long appendages to release body heat into their environment. The enormous ears of jackrabbits, with their many blood vessels, dissipate heat when the animal is resting in a cool, shady location. Their close relatives in cooler regions have much shorter ears. New World vultures, dark in color and thus absorbing considerable heat in the 158
Deserts desert, excrete urine on their legs to cool them by evaporation, and circulate the cooled blood back through the body. Many desert animals are paler than their relatives elsewhere, ensuring that they not only suffer less heat absorption, but also are less conspicuous to predators in the bright, pallid surroundings. The mechanisms by which water is retained by desert animals are even more elaborate. Reptiles and birds excrete metabolic wastes in the form of uric acid, an insoluble white compound, wasting very little water in the process. Other animals retain water by burrowing into moist soil during the dry daylight hours. Some predatory and scavenging animals can obtain their entire water needs from the food they eat. Most mammals, however, need access to a good supply of fresh water at least every few days, if not daily, due to the considerable water loss from excretion of urea, a soluble compound. Many desert animals obtain water from plants, particularly succulent ones such as cactus and saguaro. Many species of insects thrive in the desert, as they tap plant fluids for water and nectar. The abundance of insect life permits insectivorous birds, bats, and lizards to thrive in the desert. Certain desert animals, such as kangaroo rats, have multiple adaptation mechanisms to acquire and conserve water. First, they live in underground dens that they seal off to block out heat and to recycle the moisture from their own breathing. Second, they have specialized kidneys with extra microscopic projections to extract most of the water from their urine and return it to the bloodstream. Third, and most fascinating of all, they actually manufacture their water metabolically from the digestion of dry seeds. These are just a few examples of the variety of ingenious adaptations animals use to survive in the desert, overcoming the extremes of heat and the paucity of water. Habitat Loss Urban and suburban sprawl paves over desert land and destroys habitat for plants and animals, some of which are endemic to specific deserts. Farmers and metropolitan-area builders can tap into critical desert water supplies, changing the hydrology of desert regions. Off-road vehicles can destroy plant and animal life and leave tracks that may last for decades. Carol S. Radford and Yujia Weng See also: Biomes: determinants; Biomes: types; Desertification; Ecosystems: definition and history; Erosion and erosion control; Global warming; Greenhouse effect; Hydrologic cycle; Nutrient cycles; Rain forests and the atmosphere; Soil; Soil contamination. 159
Deserts Sources for Further Study Allaby, Michael. Deserts. New York: Facts on File, 2001. Baylor, Byrd. The Desert Is Theirs. Reprint. New York: Aladdin Books, 1987. Bothma, J. du P. Carnivore Ecology in Arid Lands. New York: SpringerVerlag, 1998. Bowers, Janice. Shrubs and Trees of the Southwest Deserts. Tucson, Ariz.: Southwest Parks & Monuments Association, 1993. Epple, Anne O. Field Guide to the Plants of Arizona. Helena, Mont.: Falcon, 1997. Hare, John. The Lost Camels of Tartary: A Quest into Forbidden China. Boston: Little, Brown, 1998. Larson, Peggy Pickering, Lane Larson, Edward Abbey, and Iy Larson. The Deserts of the Southwest: A Sierra Club Naturalist’s Guide. 2d ed. San Francisco: Sierra Club Books, 2000. Raskin, Lawrence, and Debora Pearson. Fifty-two Days by Camel: My Sahara Adventure. Toronto: Annick Press, 1998.
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DEVELOPMENT AND ECOLOGICAL STRATEGIES Type of ecology: Evolutionary ecology The relationship between ontogeny (individual development) and phylogeny (the evolution of species and lineages) is a core concept in the study of ecology and life sciences in general. Changes in developmental timing produce parallels between ontogeny and phylogeny. The subject illuminates the biology of regulation, the evolution of ecological strategies, and the mechanisms for evolutionary change in form.
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he idea of a relationship between individual development, or ontogeny, and the evolutionary history of a race, or phylogeny, is an old one. The concept received much attention in the nineteenth century and is often associated with the names of Karl Ernst von Baer and Ernst Haeckel, two prominent German biologists. It was Haeckel who coined the catchphrase and dominant paradigm: Ontogeny recapitulates (or repeats) phylogeny. Since Haeckel’s time, however, the relations between ontogeny and phylogeny have been portrayed in a variety of ways, including the reverse notion that phylogeny is the succession of ontogenies. Research in the 1970’s and 1980’s on the parallels between ontogeny and phylogeny focused on the change of timing in developmental events as a mechanism for recapitulation and on the developmental-genetic basis of evolutionary change. Early Concepts of Biogenetic Law During the early nineteenth century, two different concepts of parallels between development and evolution arose. The German J. F. Meckel and the Frenchman E. R. Serres believed that a higher animal in its embryonic development recapitulates the adult structures of animals below it on a scale of being. Baer, on the other hand, argued that no higher animal repeats an earlier adult stage but rather the embryo proceeds from undifferentiated homogeneity to differentiated heterogeneity, from the general to the specific. Baer published his famous and influential four laws in 1828: (1) The more general characters of a large group of animals appear earlier in their embryos than the more special characters. (2) From the most general forms, the less general are developed. (3) Every embryo of a given animal, instead of passing through the other forms, becomes separated from them. (4) The embryo of a higher form never resembles any other form, only its embryo.
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Development and ecological strategies By the late nineteenth century, the notion of recapitulation and Baer’s laws of embryonic similarity were recast in evolutionary terms. Haeckel and others established the biogenetic law: that is, ontogeny recapitulates the adult stages of phylogeny. It was, in a sense, an updated version of the Serres-Meckel law but differed in that the notion was valid not only for a chain of being but also for many divergent lines of descent; ancestors had evolved into complex forms and were now considered to be modified by descent. More specifically, Haeckel thought of ontogeny as a short and quick recapitulation of phylogeny caused by the physiological functions of heredity and adaptation. During its individual development, he wrote, the organic individual repeats the most important changes in form through which its forefathers passed during the slow and long course of their paleontological development. The adult stages of ancestors are repeated during the development of descendants but crowded back into earlier stages of ontogeny. Ontogeny is the abbreviated version of phylogeny. These repeated stages reflect the history of the race. Haeckel considered phylogeny to be the mechanical cause of ontogeny. The classic example of recapitulation is the stage of development in an unhatched bird or unborn mammal when gill slits are present. Haeckel argued that gill slits in this stage represented gill slits of the adult stage of ancestral fish, which in birds and mammals were pressed back into early stages of development. This theory differed from Baer’s notion that the gill slit in the human embryo and in the adult fish represented the same stage in development. The gill slits, explained the recapitulationists, got from a large adult ancestor to a small embryo in two ways: first, terminal addition (in which stages are added to the end of an ancestral ontogeny); and second, condensation (in which development is speeded up as ancestral features are pushed back to earlier stages of the embryo). Haeckel also coined another term widely used currently in another sense: “heterochrony.” He used the term to denote a displacement in time of the appearance of one organ in ontogeny before another, thus disrupting the recapitulation of phylogeny in ontogeny. Haeckel was not, however, interested primarily in mechanisms or in embryology for its own sake, but rather for the information it could provide for developing evolutionary histories. Recapitulation in the Twentieth Century With the rise of mechanistic experimental embryology and with the establishment of Mendelian genetics in the early twentieth century, the biogenetic law was largely repudiated by biologists. Descriptive embryology was out of fashion, and the existence of genes made the two correlate laws to recapitulation—terminal addition and condensation—untenable. One 162
Development and ecological strategies of the most influential modifications for later work on the subject was broached in a paper by Walter Garstang in 1922, in which he reformulated the theory of recapitulation and refurbished the concept of heterochrony. Garstang argued that phylogeny does not control ontogeny but rather makes a record of the former: that is, phylogeny is a result of ontogeny. He suggested that adaptive changes in a larval stage coupled with shifts in the timing of development (heterochrony) could result in radical shifts in adult morphology. Stephen Jay Gould resurrected the long unpopular concept of recapitulation with his book Ontogeny and Phylogeny (1977). In addition to recounting the historical development of the idea of recapitulation, he made an original contribution to defining and explicating the mechanism (heterochrony) involved in producing parallels between ontogeny and phylogeny. He argued that heterochrony—“changes in the relative time of appearance and rate of development for characters already present in ancestors”—was of prime evolutionary importance. He reduced Gavin de Beer’s complex eight-mode analysis of heterochrony to two simplified processes: acceleration and retardation. Acceleration occurs if a character appears earlier in the ontogeny of a descendant than it did in an ancestor because of a speeding up of development. Conversely, retardation occurs if a character appears later in the ontogeny of a descendant than it did in an ancestor because of a slowing down of development. To demonstrate these concepts, Gould introduced a “clock model” in order to bring some standardization and quantification to the heterochrony concept. He considered the primary evolutionary value of ontogeny and phylogeny to be in the immediate ecological advantages for slow or rapid maturation rather than in the long-term changes of form. Neoteny (the opposite of recapitulation) is the most important determinant of human evolution. Humans have evolved by retaining the young characters of their ancestors and have therefore achieved behavioral flexibility and their characteristic form. For example, there is a striking resemblance between some types of juvenile apes and adult humans; this similarity for the ape soon fades in its ontogeny as the jaw begins to protrude and the brain shrinks. Gould also insightfully predicted that an understanding of ontogeny and phylogeny would lead to a rapprochement between molecular and evolutionary biology. By the 1980’s, Rudolf Raff and Thomas Kaufman found this rapprochement by synthesizing embryology with genetics and evolution. Their work focuses on the developmental-genetic mechanisms that generate evolutionary change in morphology. They believe that a genetic program governs ontogeny, that the great decisions in development are made by a small number of genes that function as switches between alternate states or path163
Development and ecological strategies ways. When these genetic switch systems are modified, evolutionary changes in morphology occur mechanistically. They argue further that regulatory genes—genes that control development by turning structural genes on and off—control the timing of development, make decisions about the fates of cells, and integrate the expression of structural genes to produce differentiated tissue. All this plays a considerable role in evolution. Description vs. Experimentation Both embryology and evolution have traditionally been descriptive sciences using methods of observation and comparison. By the end of the nineteenth century, a dichotomy had arisen between the naturalistic (descriptive) and the experimentalist tradition. The naturalists’ tradition viewed the organism as a whole, and morphological studies and observations of embryological development were central to their program. Experimentalists, on the other hand, focused on laboratory studies of isolated aspects of function. A mechanistic outlook was compatible with this experimental approach. Modern embryology uses both descriptive and experimental methods. Descriptive embryology uses topographic, histological (tissue analysis), cytological (cell analysis), and electron microscope techniques supplemented by morphometric (the measurement of form) analysis. Embryos are visualized using either plastic models of developmental stages, schematic drawings, or computer simulations. Cell lineage drawings are also used with the comparative method for phylogenies. Experimental embryology, on the other hand, uses more invasive methods of manipulating the organism. During this field of study’s early period, scientists subjected embryos to various changes to their normal path of development; they were chopped into pieces, transplanted, exposed to chemicals, and spun in centrifuges. Later, fate maps came into usage in order to determine the future development of regions in the embryo. It was found that small patches of cells on the surface of the embryo could be stained, without damaging the cell, by applying small pieces of agar soaked in a vital dye. One could then follow the stained cells to their eventual position in the gastrula. Amphibian eggs are used as material because they are big, easy to procure, and can undergo radical experimental manipulation. Interdisciplinary Studies Evolutionary theory primarily uses paleontology (study of the fossil record) to study the evolutionary history of species, yet Gould also used quantification (the clock model, for example), statistics, and ecology to un164
Development and ecological strategies derstand the parallels between ontogeny and phylogeny. Most scientists interested in the relationships between ontogeny and phylogeny chiefly use comparative and theoretical methods. For example, they compare structures in different animal groups or compare the adult structures of an animal with the young stage of another. If similarities exist, are the lineages similar? Are the stages in ontogenetic development similar to those of the development of the whole species? Yet, the study of relationships between ontogeny and phylogeny is an interdisciplinary subject. Not only are methods from embryology and evolutionary theory of help, but also, increasingly, techniques are applied from molecular genetics. Haeckel’s method was primarily a descriptive historical one, and he collected myriad descriptive studies of different animals. Although scientists in those days had relatively simple microscopes, they left meticulous and detailed accounts. A fusion of embryology, evolution, and genetics involves combining different methods from each of the respective disciplines for the study of the relationship between ontogeny and phylogeny. The unifying approach has been causal-analytical, in the sense that biologists have been examining mechanisms that produce parallels between ontogeny and phylogeny as well as the developmental-genetic basis for evolutionary change. The methods are either technical or theoretical. The technical ones include the use of the electron microscope, histological, cytological, and experimental analyses; the theoretical methods include comparison, historical analysis, observations, statistics, and computer simulation. Ramifications Beyond Science The relationship between ontogeny and phylogeny is one of the most important ideas in biology and a central theme in evolutionary biology. It illuminates the evolution of ecological strategies, large-scale evolutionary change, and the biology of regulation. This scientific idea has also had farreaching influences in areas such as anthropology, political theory, literature, child development, education, and psychology. In the late nineteenth century, embryological development was a major part of evolutionary theory; however, that was not the case for much of the twentieth century. Although there was some interest in embryology and evolution from the 1920’s to the 1950’s by Garstang, J. S. Huxley, de Beer, and Richard Goldschmidt, during the first three decades of the twentieth century genetics and development were among the most important and active areas in biological thought, yet there were few attempts to integrate the two areas. It is this new synthesis of evolution, embryology, and genetics that has emerged as one of the most exciting frontiers in the life sciences. 165
Development and ecological strategies Although knowledge to be gained from a synthesis of development and evolution seems not to have any immediate practical application, it can offer greater insights into mechanisms of evolution, and a knowledge of evolution will give similar insights into mechanisms of development. A study of these relations and interactions also enlarges humankind’s understanding of the nature of the development of individuals and their relation to the larger historical panorama of the history of life. Kristie Macrakis See also: Evolution: definition and theories; Evolution: history; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Population genetics; Punctuated equilibrium vs. gradualism. Sources for Further Study Bonner, J. T. Morphogenesis: An Essay on Development. Princeton, N.J.: Princeton University Press, 1952. De Beer, Gavin. Embryos and Ancestors. Oxford, England: Clarendon Press, 1951. Gould, Stephen Jay. Ontogeny and Phylogeny. Cambridge, Mass.: Harvard University Press, 1977. _______. “Ontogeny and Phylogeny—Revisited and Reunited.” BioEssays 14, no. 4 (April, 1992): 275-280. Hall, Brian K. Evolutionary Developmental Biology. 2d ed. New York: Chapman & Hall, 1998. Raff, Rudolf A., and Thomas C. Kaufman. Embryos, Genes, and Evolution: The Developmental-Genetic Basis of Evolutionary Change. New York: Macmillan, 1983. Schwartz, Jeffrey H. Sudden Origins: Fossils, Genes, and the Emergence of Species. New York: Wiley, 1999.
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DISPLAYS Type of ecology: Behavioral ecology Displays are specialized behaviors that act as communication signals within, and occasionally between, species.
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onlinguistic forms of communication are called displays. Some displays involve, literally and simply, the visual display of a physical feature. Among insects, for example, green or brown coloring is often used for camouflage. Insects that are poisonous do not need camouflage and often advertise themselves with warning colors, such as black and red, or black and orange. This is referred to as aposematic coloration or an aposematic display. Physical features can also indicate an individual’s sex, age, and reproductive status—as do peacock tails, turkey wattles, deer antlers, the canine teeth of male baboons, and the swollen genitals of estrous female chimpanzees. Many such features vary in size, shape, or color in relation to an animal’s health, hormones, or social status and are therefore referred to as status badges or signs. Often, meaningful physical features are highlighted by behavioral displays. A courting peacock or turkey will fan open his tail and shake it back and forth for emphasis; a challenged buck will load plant material onto his antlers so as to exaggerate their size; an angry baboon will curl back his lip to expose his canine teeth; and an estrous chimpanzee will approach a friendly male and assume a posture displaying her fertile state. A particularly energetic or dramatic behavioral display not only calls attention to a physical feature but also indicates the health and vitality of the performer. The principle of honest signaling refers to the fact that large and healthy individuals tend to have brighter or more contrasting colors, make deeper-pitched and louder sounds, and produce longer, more intense performances than small or weak ones. Such differences in display quality are readily noticed by predators, potential competitors, and potential mates. Most displays are performed by individuals and are one-way: sender to receiver. Threat displays, however, may involve reciprocal signaling between two challengers or between two groups of challengers. Courtship displays also may occur in groups: In some species, males gather together to perform in what is called a lek or a lekking display. Courtship of monogamous species may include long sequences of frequently repeated, ritual167
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Male peacocks fan their tails and shake them in a courting display to attract females. Such physical features can also signal an individual’s health, age, and social status and are therefore called “status badges.” (Digital Stock)
ized interactions in which both partners participate. Such pair-bonding displays may continue well into the breeding season and the mateship; initially serving to familiarize the pair with one another and to synchronize their hormones and breeding behavior, they may later serve as greeting displays after separation. Interpreting Displays Charles Darwin noted that displays having opposite characteristics often signal opposite meaning. In humans, for example, a face with upturned corners of the mouth (a smile) signals friendliness, whereas a face with downturned corners of the mouth (a frown) signals displeasure. In most animals, loud, deep-pitched sounds (for example, roars and growls) indicate aggression, whereas quiet, high-pitched sounds (for example, mews and peeps) indicate anxiety or fear. Similarly, body postures exaggerating size tend to signal dominance, whereas postures minimizing size tend to signal submission. Darwin called his observation the principle of antithesis. Although some rules of display can be applied across species, most displays are specialized for intraspecific (within-species) communication— male to female, parent to offspring, or dominant to subordinate—and are therefore species-specific. That is, the ability to perform and interpret a particular display (such as a particular birdsong) is generally characteristic only of individuals of a particular species and is either innate (inborn) or learned from conspecifics (individuals of the same species) during an early critical period of development. In order that their meaning is easily and quickly conveyed, most displays also tend to be highly ritualized; that is, they are performed only in certain contexts and always in the same way. This consistency in commu168
Displays nication prevents errors of interpretation that could be disastrous. It would be a grave mistake, for example, to interpret an aggressive signal as a sexual overture, or an alarm call (predator alert signal) as an offspring’s begging call. Mistakes of interpretation are also minimized by signal redundancy; that is, messages are often conveyed simultaneously in more than one sensory modality. Display Modality Displays utilize every sensory modality. Visual displays involve the use of bright, contrasting, and sometimes changing colors; changes in body size, shape, and posture; and what ethologists call “intention movements”— brief, suggestive movements which reveal motivational state and likely future actions. Auditory displays include vocal songs and calls, as well as a variety of sounds produced by tapping, rubbing, scraping, or inflating and deflating various parts of the body. Tactile displays include aspects of social grooming, comfort contacts (such as between littermates or parents and offspring), and the seismic signaling of water-striders, elephants, frogs, and spiders which vibrate, respectively, the water, ground, plants, or web beneath them. Olfactory displays include signals from chemicals that have been wafted into the air or water, rubbed onto objects, or deposited in saliva, urine, or feces. Olfaction (sense of smell) is the most primitive, and therefore the most common and most important, sense in the animal kingdom. Species of almost every taxonomic group use smell to signal their whereabouts and, generally, their sex and reproductive state. (Birds seem to be an exception.) Animals may also use smell to identify particular individuals, to recognize who is related to them and who is not, and to determine the relative dominance status of a conspecific.
Many animals, such as this badger, assume aggressive postures—bared teeth, fluffed fur to make them look larger, growling, and a variety of other signals—to warn off a threatening presence such as a predator or a human being. (Digital Stock) 169
Displays Chemicals used in displays are called pheromones. They may be derived from waste products or hormones, acquired by ingesting certain food items, or obtained directly from plants or other animals. Some pheromones not only communicate information, but also have physical effects on their receivers. Linda Mealey See also: Altruism; Communication; Competition; Defense mechanisms; Ethology; Hierarchies; Insect societies; Mammalian social systems; Migration; Mimicry; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study Agosta, William C. Chemical Communication: The Language of Pheromones. New York: Scientific American Library, 1992. Bailey, Winston. Acoustic Behaviour in Insects. New York: Chapman and Hall, 1991. Eibl-Eibesfeldt, I. Ethology: The Biology of Behavior. Translated by Erich Klinghammer. 2d ed. New York: Holt, Reinhart and Winston, 1975. Guthrie, R. Dale. Body Hot Spots: The Anatomy of Human Social Organs and Behavior. New York: Van Nostrand Reinhold, 1976. Johnsgard, Paul A. Arena Birds: Sexual Selection and Behavior. Washington, D.C.: Smithsonian Institution Press, 1994. Morris, Desmond. Animalwatching. New York: Crown, 1990. Owen, Denis. Camouflage and Mimicry. Chicago: University of Chicago Press, 1980.
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ECOLOGY: DEFINITION Type of ecology: Theoretical ecology Ecology is the study of the relationships of organisms to their environments. By examining those relationships in natural ecosystems, ecologists can discover principles that help humankind understand its own role on the planet.
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cology is the study of how organisms relate to their natural environments. The two principal concerns of ecologists are the distribution and abundance of organisms: Why are animals, plants, and other organisms found where they are, and why are some common and others rare? These questions have their roots in the theory of evolution. In fact, it is difficult (and not often worthwhile) to separate modern ecological matters from the concerns of evolutionary biologists. Ecology can be divided according to several levels of organization: the individual organism, the population, the community, and the ecosystem. Individual Organisms An ecologist views organisms as consequences of past natural selection brought about by their environments. That is, each organism represents an array of adaptations that can provide insight into the environmental pressures that resulted in its present form. Adaptations of organisms are also revealed by other features, such as the range of temperature an organism can tolerate, the amount of moisture it requires, or the variety of food it can exploit. Food and space for living are considered resources; factors such as temperature, light, and moisture are conditions that determine the rate of resource utilization. When ecologists have discovered the full range of resources and conditions necessary for an organism’s existence, they have discovered its niche. Many species, such as many insects and plants, have a large reproductive output. This compensates for high mortality imposed by natural selection. Other species, such as large mammals and birds, have fewer offspring. Many of these animals care for their young, thus increasing the chances that their offspring will survive to reproduce. These are two different strategies for success, based upon the principle that organisms have a finite energy budget. Energy acquired from food (animals) or sunlight (plants) must be partitioned among growth, maintenance, and reproduction. The greater the energy allocated to the care of offspring, for example, the fewer the offspring that can be produced. 171
Ecology: definition The concept of an energy budget is a key to understanding evolutionary strategies of organisms, as well as the energetics of ecosystems. The amount of energy fixed and stored by an organism is called net production; this is the energy used for growth and reproduction. Net production is the difference between gross production (the amount of energy assimilated) and respiration (metabolic maintenance cost). The greater the respiration, the less energy will be left over for growth and reproduction. Endothermic animals, which physiologically regulate their body heat (mammals and birds), have a very high respiration rate relative to ectotherms (reptiles, amphibians, fish, and invertebrates), which cannot. Among endotherms, smaller animals have higher respiration rates than larger ones, because the ratio of body surface area (the area over which heat is exchanged with the environment) to volume (the size of the “furnace”) decreases with increasing body size. Populations Although single organisms can be studied with regard to adaptations, in nature most organisms exist in populations rather than as individuals. Some organisms reproduce asexually (that is, by forming clones), so that a single individual may spawn an entire population of genetically identical individuals. Populations of sexually reproducing organisms, however, have the property of genetic variability, since not all individuals are identical. That is, members of a population have slightly different niches and will therefore not all be equally capable of living in a given environment. This is the property upon which Charles Darwin’s theory of natural selection depends: Because not all individuals are identical, some will have greater fitness than others. Those with superior fitness will reproduce in greater numbers and therefore will contribute more genes to successive generations. In nature, many species consist of populations occupying more than a single habitat. This constitutes a buffer against extinction: If one habitat is destroyed, the species will not go extinct, because it exists in other habitats. Two dynamic features of populations are growth and regulation. Growth is simply the difference between birth and death rates, which can be positive (growing), negative (declining), or zero (in equilibrium). Every species has a genetic capacity for exponential (continuously accelerating) increase, which will express itself to varying degrees depending on environmental conditions: A population in its ideal environment will express this capacity more nearly than one in a less favorable environment. The rate of growth of a population is affected by its age structure—the proportion of individuals of different ages. For example, a population that is growing rapidly will 172
Ecology: definition have a higher proportion of juvenile individuals than one that is growing more slowly. Populations may be regulated (so that they have equal birth and death rates) by a number of factors, all of which are sensitive to changes in population size. A population may be regulated by competition among its members for the resource that is in shortest supply (limiting). The largest population that can be sustained by the available resources is called the carrying capacity of the environment. A population of rodents, for example, might be limited by its food supply such that as the population grows and food runs out, the reproductive rate declines. Thus, the effect of food on population growth depends upon the population size relative to the limiting resource. Similarly, parasites that cause disease spread faster in large, dense populations than in smaller, more diffuse ones. Predators can also regulate populations of their prey by responding to changes in prey availability. Climate and catastrophic events such as storms may severely affect populations, but their effect is not dependent upon density and is thus not considered regulatory. Communities Communities of organisms are composed of many populations that may interact with one another in a variety of ways: predation, competition, mutualism, parasitism, and so on. The composition of communities changes over time through the process of succession. In terrestrial communities, bare rock may be weathered and broken down by bacteria and other organisms until it becomes soil. Plants can then invade and colonize this newly formed soil, which in turn provides food and habitat for animals. The developing community goes through a series of stages, the nature of which depends on local climatic conditions, until it reaches a kind of equilibrium. In many cases this equilibrium stage, called climax, is a mature forest. Aquatic succession essentially is a process of becoming a terrestrial community. The basin of a lake, for example, will gradually be filled with silt from terrestrial runoff and accumulated dead organic material from populations of organisms within the lake itself. Competition occurs between, as well as within, species. Two species are said to be in competition with each other if and only if they share a resource that is in short supply. If, however, they merely share a resource that is plentiful, then they are not really competing for it. Competition is thought to be a major force in determining how many species can coexist in natural communities. There are a number of alternative hypotheses, however, which involve such factors as evolutionary time, productivity (the energy base for a community), heterogeneity of the habitat, and physical harshness of the environment. 173
Ecology: definition Predator-prey interactions are those in which the predator benefits from killing and consuming its prey. These differ from most parasite-host interactions in that parasites usually do not kill their hosts (a form of suicide for creatures that live inside other creatures). Similarly, most plant-eating animals (herbivores) do not kill the plants on which they feed. Many ecologists classify herbivores as parasites for this reason. There are exceptions, such as birds and rodents that eat seeds, and these can be classified as legitimate predator-prey interactions. Predators can influence the number of species in a community by affecting competition among their prey: If populations of competing species are lowered by predators so that they are below their carrying capacities, then there may be enough resources to support colonization by new species. In many cases, the interaction between two species is mutually beneficial. Mutualism is often thought to arise as a result of closely linked evolutionary histories (coevolution) of different species. Termites harbor protozoans in their guts that produce an enzyme that breaks down cellulose in wood. The protozoans thus are provided with a habitat, and the termites in turn are able to derive nourishment from wood. Some acacia trees in the tropics have hollow thorns which provide a habitat for ants. In return, the ants defend the trees from other insects which would otherwise damage or defoliate them. Ecosystems Ecosystems consist of several trophic levels, or levels at which energy is acquired: primary producers, consumers, and decomposers. Primary producers are green plants that capture solar energy and transform it, through the process of photosynthesis, into chemical energy. Organisms that eat plants (herbivores) or animals (carnivores) to obtain their energy are collectively called consumers. Decomposers are those consumers, such as bacteria and fungi, that obtain energy by breaking down dead bodies of plants and animals. These trophic levels are linked together into a structure called a food web, in which energy is transferred from primary producers to consumers and decomposers, until finally all is lost as heat. Each transfer of energy entails a loss (as heat) of at least 90 percent, which means that the total amount of energy available to carnivores in an ecosystem is substantially less than that available to herbivores. As with individual organisms, ecosystems and their trophic levels have energy budgets. The net production of one trophic level is available to the next-higher trophic level as biomass (mass of biological material). Plants have higher net productivity (rates of production) than animals because their metabolic maintenance cost is lower relative to gross productivity; 174
Ecology: definition herbivores often have higher net productivity than predators for the same reason. For the community as a whole, net productivity is highest during early successional stages, since biomass is being added more rapidly than later on, when the community is closer to climax equilibrium. In contrast to the unidirectional flow of energy, materials are conserved and recycled from dead organisms by decomposers to support productivity at higher trophic levels. Carbon, water, and mineral nutrients required for plant growth are cycled through various organisms within an ecosystem. Materials and energy are also exchanged among ecosystems: There is no such thing in nature as a “closed” ecosystem that is entirely selfcontained. Methods of Studying Ecology The science of ecology is necessarily more broadly based than most biological disciplines; consequently, there is more than one approach to it. Ecological studies fall into three categories: descriptive, experimental, and mathematical. Descriptive ecology is concerned with describing natural history, usually in qualitative terms. The study of adaptations, for example, is descriptive in that one can measure the present “value” of an adaptive feature, but one can only conjecture as to the history of natural selection that was responsible for it. On the other hand, there are some patterns discernible in nature for which hypotheses can be constructed and tested by statistical inference. For example, the spatial distribution (dispersion) of birds on an island may be random, indicating no biological interaction among them. If the birds are more evenly spaced (uniform dispersion) than predicted assuming randomness, however, then it might be inferred that the birds are competing for space; they are exhibiting territorial exclusion of one another. Such “natural experiments,” as they are called, depend heavily upon the careful design of statistical tests. Experimental ecology is no different from any other experimental discipline; hypotheses are constructed from observations of nature, controlled experiments are designed to test them, and conclusions are drawn from the results of the experiments. The basic laboratory for an ecologist is the field. Experiments in the field are difficult because it is hard to isolate and manipulate variable factors one at a time, which is a requisite for any good experiment in science. A common experiment that is performed to test for resource limitation in an organism is enhancement of that resource. If food, for example, is thought to be in short supply (implying competition), one section of the habitat is provided more food than is already present; another section is left alone as a control. If survivorship, growth, or repro175
Ecology: definition ductive output is higher in the enhanced portion of the habitat than in the control area, the researcher may infer that the organisms therein were food-limited. Alternatively, an ecologist might have decreased the density of organisms in one portion of the habitat, which might seem equivalent to increasing food supply for the remaining organisms, except that it represents a change in population density as well. Therefore, this second design will not allow the researcher to differentiate between the possibly separate effects of food level and simple population density on organisms in the habitat. Mathematical ecology relies heavily upon computers to generate models of nature. A model is simply a formalized, quantitative set of hypotheses constructed from sets of assumptions of how things happen in nature. A model of population growth might contain assumptions about the age structure of a population, its genetic capacity for increase, and the average rate of resource utilization by its members. By changing these assumptions, scientists can cause the model population to behave in different ways over time. The utility of such modeling is limited to the accuracy of the assumptions employed. Modern ecology is concerned with integrating these different approaches, all of which have in common the goal of predicting the way nature will behave in the future, based upon how it behaves in the present. Description of natural history leads to hypotheses that can be tested experimentally, which in turn may allow the construction of realistic mathematical (quantitative) models of how nature works. Human Impacts and Applications People historically have viewed nature as an adversary. The “conquest of nature” has traditionally meant human encroachment on natural ecosystems, usually without benefit of predictive knowledge. Such environmental problems as pollution, species extinction, and overpopulation can be viewed as experiments performed on a grand scale without appropriate controls. The problem with such experiments is that the outcomes might be irreversible. A major lesson of ecology is that humans are not separate from nature; we are constrained by the same principles as are other organisms on the earth. One object of ecology, then, is to learn these principles so that they can be applied to our portion of the earth’s ecosystem. Populations that are not regulated by predators, disease, or food limitation grow exponentially. The human population, on a global scale, has grown this way. All the wars and famines in history have scarcely made a dent in this growth pattern. Humankind has yet to identify its carrying capacity on a global scale, although regional famines certainly have provided 176
Ecology: definition insights into what happens when local carrying capacity is exceeded. The human carrying capacity needs to be defined in realistic ecological terms, and such constraints as energy, food, and space must be incorporated into the calculations. For example, knowledge of energy flow teaches that there is more energy at the bottom of a food web (producers) than at successively higher trophic levels (consumers), which means that more people could be supported as herbivores than as carnivores. The study of disease transmission, epidemiology, relies heavily on ecological principles. Population density, rates of migration among epidemic centers, physiological tolerance of the host, and rates of evolution of disease-causing parasites are all the subjects of ecological study. An obvious application of ecological principles is conservation. Before habitats for endangered species can be set aside, for example, their ecological requirements, such as migratory routes, breeding, and feeding habits, must be known. This also applies to the introduction (intentional or accidental) of exotic species into habitats. History is filled with examples of introduced species that caused the extinction of native species. Application of ecological knowledge in a timely fashion, therefore, might prevent species from becoming endangered in the first place. One of the greatest challenges humans face is the loss of habitats worldwide. This is especially true of the tropics, which contain most of the earth’s species of plants and animals. Species in the tropics have narrow niches, which means that they are more restricted in range and less tolerant of change than are many temperate species. Therefore, destruction of tropical habitats, such as rain forests, leads to rapid species extinction. These species are the potential sources of many pharmaceutically valuable drugs; further, they are a genetic record of millions of years of evolutionary history. Tropical rain forests also are prime sources of oxygen and act as a buffer against carbon dioxide accumulation in the atmosphere. Ecological knowledge of global carbon cycles permits the prediction that destruction of these forests will have a profound impact on the quality of the air. Lawrence E. Hurd See also: Balance of nature; Biomes: determinants; Biomes: types; Biosphere concept; Deep ecology; Ecosystems: definition and history; Sustainable development. Sources for Further Study Begon, Michael, John L. Harper, and Colin R. Townsend. Ecology: Individuals, Populations, and Communities. 3d ed. Cambridge, Mass.: Blackwell Science, 1996. 177
Ecology: definition Bush, M. B. Ecology of a Changing Planet. 2d ed. Upper Saddle River, N.J.: Prentice-Hall, 2000. Carson, Rachel. Silent Spring. Boston: Houghton Mifflin, 1962. Elton, Charles. Animal Ecology. New York: Macmillan, 1927. Hutchinson, G. Evelyn. The Ecological Theater and the Evolutionary Play. New Haven, Conn.: Yale University Press, 1969. Krebs, Charles J. Ecological Methodology. 2d ed. Menlo Park, Calif.: Benjamin/ Cummings, 1999. _______. Ecology: The Experimental Analysis of Distribution and Abundance. 5th ed. San Francisco: Benjamin/Cummings, 2001. _______. The Message of Ecology. New York: Harper & Row, 1987. Pianka, Eric R. Evolutionary Ecology. 6th ed. San Francisco: Benjamin/Cummings, 2000. Ricklefs, Robert E. Ecology. 4th ed. New York: Chiron Press, 1999.
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ECOLOGY: HISTORY Type of ecology: History of ecology As a formal discipline, ecology, the science that studies the relationships among organisms and their biotic and abiotic environments, is a relatively new science, which became a focus of study at about the same time evolutionary theories were being proposed.
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he study of ecological topics arose in ancient Greece, but these studies were part of a catch-all science called natural history. The earliest attempt to organize an ecological science separate from natural history was made by Carolus Linnaeus in his essay Oeconomia Naturae (1749; The Economy of Nature), which focused on the balance of nature and the environments in which various natural communities existed. Although the essay was well known, the eighteenth century was dominated by biological exploration of the world, and the science of ecology did not develop. Early Ecological Studies The study of fossils led some naturalists to conclude that many species known only as fossils must have become extinct. However, Jean-Baptiste Lamarck argued in his Philosophie zoologique (1809; Zoological Philosophy, 1914) that fossils represented the early stages of species that evolved into different species that were still living. In order to refute this claim, geologist Charles Lyell mastered the science of biogeography and used it to argue that species do become extinct and that competition from other species seemed to be the main cause. English naturalist Charles Darwin’s book On the Origin of Species by Means of Natural Selection (1859) blends his own researches with the influence of Linnaeus and Lyell in order to argue that some species do become extinct, but existing species have evolved from earlier ones. Lamarck had underrated and Lyell had overrated the importance of competition in nature. Although Darwin’s book was an important step toward ecological science, he and his colleagues mainly studied evolution rather than ecology. German evolutionist Ernst Haeckel realized the need for an ecological science and coined the name oecologie in 1866. It was not until the 1890’s, however, that steps were taken to organize this science. Virtually all of the early ecologists were specialists in the study of particular groups of organisms, and it was only in the late 1930’s that some efforts were made to write textbooks covering all aspects of ecology. Since the 1890’s, many ecologists 179
Ecology: history have viewed themselves as plant ecologists, animal ecologists, marine biologists, or limnologists. Limnology is the study of freshwater aquatic environments. Nevertheless, general ecological societies were established. The first was the British Ecological Society, which was founded in 1913 and began publishing the Journal of Ecology in the same year. Two years later, ecologists in the United States and Canada founded the Ecological Society of America, which began publishing Ecology as a quarterly journal in 1920; in 1965 Ecology began appearing bimonthly. Other national societies have since been established. More specialized societies and journals also began appearing. For example, the Limnological Society of America was established in 1936 and expanded in 1948 into the American Society of Limnology and Oceanography. It publishes the journal Limnology and Oceanography. These and now many other professional organizations, both academic and applied, sponsor not only journals but also Web sites, reports, and symposia. Although Great Britain and Western Europe were active in establishing the study of ecological sciences, it was difficult for their trained ecologists to obtain full-time employment that utilized their expertise. European universities were mostly venerable institutions with fixed budgets; they already had as many faculty positions as they could afford, and these were all allocated to the older arts and sciences. Governments employed few, if any, ecologists. The situation was more favorable in the United States, Canada, and Australia, where universities were still growing. In the United States, the universities that became important for ecological research and the training of new ecologists were mostly in the Midwest. The reason was that eastern universities were similar to European ones in being well established, with scientists in traditional fields. Ecology After 1950 Ecological research in the United States was not well funded until after World War II. With the advent of the Cold War, science was suddenly considered important for national welfare. In 1950 the U.S. Congress established the National Science Foundation, and ecologists were able to make the case for their research along with that of the other sciences. The Atomic Energy Commission had already begun to fund ecological research by 1947, and under its patronage the Oak Ridge National Laboratory and the University of Georgia gradually became important centers for radiation ecology research. Another important source of research funds was the International Biological Program (IBP), which, though international in scope, depended 180
Ecology: history upon national research funds. It got under way in the United States in 1968 and was still producing publications in the 1980’s. Even though no new funding sources were created for the IBP, its existence meant that more research money flowed to ecologists than otherwise would have. Ecologists learned to think big. Computers became available for ecological research shortly before the IBP got under way, and so computers and the IBP became linked in ecologists’ imaginations. Earth Day, established in 1970, helped awaken Americans to the environmental crisis. The IBP encouraged a variety of studies, but in the United States, studies of biomes (large-scale environments) and ecosystems were most prominent. The biome studies were grouped under the headings of desert, eastern deciduous forest, western coniferous forest, grassland, and tundra (a proposed tropical forest program was never funded). When the IBP ended, a number of its biome studies continued at a reduced level. Ecosystem studies are also large-scale, at least in comparison with many previous ecological studies, though smaller in size than a biome. The goal of ecosystem studies was to gain a total understanding of how an ecosystem—such as a lake, river valley, or forest—works. IBP funds enabled students to collect data, which computers processed. However, ecologists could not agree on what data to collect, how to compute outcomes, and how to interpret the results. Therefore, thinking big did not always produce impressive results. Plant Ecology Because ecology is enormous in scope, it was bound to have growing pains. It arose at the same time as the science of genetics, but because genetics is a cohesive science, it reached maturity much sooner than ecology. Ecology can be subdivided in a wide variety of ways, and any collection of ecology textbooks will show how diversely it is organized by different ecologists. Nevertheless, self-identified professional subgroups tend to produce their own coherent findings. Plant ecology progressed more rapidly than other subgroups and has retained its prominence. In the early nineteenth century, German naturalist Alexander von Humboldt’s many publications on plant geography in relation to climate and topography were a powerful stimulus to other botanists. By the early twentieth century, however, the idea of plant communities was the main focus for plant ecologists. Henry Chandler Cowles began his studies at the University of Chicago in geology but switched to botany and studied plant communities on the Indiana dunes of Lake Michigan. He received his doctorate in 1898 and stayed at that university as a plant ecologist. He trained others in the study of community succession. 181
Ecology: history Frederic Edward Clements received his doctorate in botany in 1898 from the University of Nebraska. He carried the concept of plant community succession to an extreme by taking literally the analogy between the growth and maturation of an organism and that of a plant community. His numerous studies were funded by the Carnegie Institute in Washington, D.C., and even ecologists who disagreed with his theoretical extremes found his data useful. Henry Allan Gleason was skeptical; his studies indicated that plant species that have similar environmental needs compete with one another and do not form cohesive communities. Although Gleason first expressed his views in 1917, Clements and his disciples held the day until 1947, when Gleason’s individualistic concept received the support of three leading ecologists. Debates over plant succession and the reality of communities helped increase the sophistication of plant ecologists and prepared them for later studies on biomes, ecosystems, and the degradation of vegetation by pollution, logging, and agriculture. Marine Ecology Marine ecology is viewed as a branch of either ecology or oceanography. Early studies were made either from the ocean shore or close to shore because of the great expense of committing oceangoing vessels to research. The first important research institute was the Statione Zoologica at Naples, Italy, founded in 1874. Its successes soon inspired the founding of others in Europe, the United States, and other countries. Karl Möbius, a German zoologist who studied oyster beds, was an important pioneer of the community concept in ecology. Great Britain dominated the seas during the nineteenth century and made the first substantial commitment to deep-sea research by equipping the HMS Challenger as an oceangoing laboratory that sailed the world’s seas from 1872 to 1876. Its scientists collected so many specimens and so much data that they called upon marine scientists in other countries to help them write the fifty large volumes of reports (1885-1895). The development of new technologies and the funding of new institutions and ships in the nineteenth century enabled marine ecologists to monitor the world’s marine fisheries and other resources and provide advice on harvesting marine species. Limnology is the scientific study of bodies of fresh water. The Swiss zoologist François A. Forel coined the term and also published the first textbook on the subject in 1901. He taught zoology at the Académie de Lausanne and devoted his life’s researches to understanding Lake Geneva’s characteristics and its plants and animals. In the United States in the early twentieth century, the University of Wisconsin became the leading 182
Ecology: history center for limnological research and the training of limnologists, and it has retained that preeminence. Limnology is important for managing freshwater fisheries and water quality. Frank N. Egerton See also: Ecology: history; Ecosystems: definition and history; Evolution: history. Sources for Further Study Allen, Timothy F. H., and Thomas W. Hoekstra. Toward a Unified Ecology. New York: Columbia University Press, 1992. Hynes, H. Patricia. The Recurring Silent Spring. New York: Pergamon Press, 1989. Leuzzi, Linda. Life Connections: Pioneers in Ecology. Danbury, Conn.: Franklin Watts, 2000.
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ECOSYSTEMS: DEFINITION AND HISTORY Types of ecology: Ecosystem ecology; History of ecology; Theoretical ecology The ecosystem is the fundamental concept in ecology: the basic unit of nature, consisting of the complex of interacting organisms inhabiting a region with all the nonliving physical factors that make up their environment. Ecologists study structural and functional relationships of ecosystem components to be able to predict how the system will respond to natural change and human disturbance.
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he ecosystem is essentially an abstract organizing unit superimposed on the landscape to help ecologists study the form and function of the natural world. An ecosystem consists of one or more communities of interacting organisms and their physical environment. Ecosystems have no distinct boundaries; thus the size of any particular ecosystem should be inferred from the context of the discussion. Individual lakes, streams, or strands of trees can be described as distinct ecosystems, as can the entire North American Great Lakes region. Size and boundaries are arbitrary because no ecosystem stands in complete isolation from those that surround it. A lake ecosystem, for example, is greatly affected by the streams that flow into it and by the soils and vegetation through which these streams flow. Energy, organisms, and materials routinely migrate across whatever perimeters the ecologist may define. Thus, investigators are allowed considerable latitude in establishing the scale of the ecosystem they are studying. Whatever the scale, though, the importance of the ecosystem concept is that it forces ecologists to treat organisms not as isolated individuals or species but in the context of the structural and functional conditions of their environment. Development of the Ecosystem Concept Antecedents to the ecosystem concept may be traced back to one of America’s first ecologists, Stephen Alfred Forbes, an eminent Illinois naturalist who studied food relationships among birds, fish, and insects. During the course of his investigations, Forbes recognized in 1880 that full knowledge of organisms and their response to disturbances would come only from more concentrated research on their interactions with other organisms and with their inorganic (nonliving) physical surroundings. In 1887, Forbes 184
Ecosystems: definition and history suggested that a lake could be viewed as a discrete system for study: a microcosm. A lake could serve as a scale model of nature that would help biologists understand more general functional relationships among organisms and their environment. Forbes explained how the food supply of a single species, the largemouth bass, was dependent either directly or indirectly upon nearly all the fauna and much of the flora of the lake. Therefore, whenever even one species was subjected to disturbance from outside the microcosm, the effects would probably be felt throughout the community. In 1927, British ecologist Charles Elton incorporated ideas introduced by Forbes and other fishery biologists into the twin concepts of the food chain and the food web. Elton defined a food chain as a series of linkages connecting basic plants, or food producers, to herbivores and their various carnivorous predators, or consumers. Elton used the term “food cycle” instead of “food web,” but his diagrams reveal that his notion of a food cycle— that it is simply a network of interconnecting food chains—is consistent with the modern term. Elton’s diagrams, which traced various pathways of nitrogen through the community, paved the way for understanding the importance of the cycling of inorganic nutrients such as carbon, nitrogen, and phosphorus through ecosystems, a process that is known as biogeochemical cycling. Very simply, Elton illustrated how bacteria could make nitrogen available to algae at the base of the food chain. The nitrogen then could be incorporated into a succession of ever larger consumers until it reached the top of the chain. When the top predators died, decomposer organisms would return the nitrogen to forms that could eventually be taken up again by plants and algae at the base of the food chain, thus completing the cycle. Elton’s other key contribution to the ecosystem concept was his articulation of the pyramid of numbers, the idea that small animals in any given community are far more common than large animals. Organisms at the base of a food chain are numerous, and those at the top are relatively scarce. Each level of the pyramid supplies food for the level immediately above it—a level consisting of various species of predators that generally are larger in size and fewer in number. That level, in turn, serves as prey for a level of larger, more powerful predators, fewer still in number. A graph of this concept results in a pyramidal shape of discrete levels, which today are called trophic (feeding) levels. Ecosystems in Twentieth Century Thought Although the basic concept of an ecosystem had been recognized by Forbes as early as 1880, it was not until 1935 that British ecologist Arthur G. 185
Ecosystems: definition and history Tansley coined the term. Though he acknowledged that ecologists were primarily interested in organisms, Tansley declared that organisms could not be separated from their physical environments, as organism and environment formed one complete system. As Forbes had pointed out half a century earlier, organisms were inseparably linked to their nonliving environment. Consequently, ecosystems came to be viewed as consisting of two fundamental parts: the biotic, or living components, and the abiotic, or nonliving components. No one articulated this better than Raymond Lindeman, a limnologist (freshwater biologist) from Minnesota who in 1941 skillfully integrated the ideas of earlier ecological scientists when he published an elegant ecosystem study of Cedar Bog Lake. Lindeman’s classic work set the stage for decades of research that centered on the ecosystem as the primary organizing unit of study in ecology. Drawing on the work of his mentor, G. Evelyn Hutchinson, and Charles Elton, Arthur Tansley, and other scientists, Lindeman explained how ecological pyramids were a necessary result of energy transfers from one trophic level to the next. By analyzing ecosystems in this manner, Lindeman was able to answer a fundamental ecological question that had been posed fourteen years earlier by Elton: Why were the largest and most powerful animals, such as polar bears, sharks, and tigers, so rare? Elton had thought the relative scarcity of top predators was due to their lower rates of reproduction. Lindeman corrected this misconception by explaining that higher trophic levels held fewer animals not because of their reproductive rates but because of a loss of chemical energy with each step up the pyramid. It could be looked upon as a necessary condition of the second law of thermodynamics: Energy transfers yield a loss or degradation of energy. The predators of one food level could never completely extract all the energy from the level below. Some energy would always be lost to the environment through respiration, some energy would not be assimilated by the predators, and some energy simply would be lost to decomposer chains when potential prey died of nonpredatory causes. This meant that each successive trophic level had substantially less chemical energy available to it than was transferred to the one below and, therefore, could not support as many animals. Ecologists soon expanded the principle of Elton’s pyramid of numbers to model other ecosystem processes. They found, for example, that the flow of chemical energy through an ecosystem could be characterized as an energy pyramid; the biomass (the weight of organic material, as in plant or animal tissue) in a community could be plotted in a pyramid of biomass. Collectively, such pyramidal models became known as ecological pyramids. 186
Ecosystems: definition and history Energy Production and Transmission Lindeman subdivided the biotic components of ecosystems into producers, consumers, and decomposers. Producers (also known as autotrophs) produce their own food from compounds in their environment. Green plants are the main producers in terrestrial ecosystems; algae are the most common producers in aquatic ecosystems. Both plants and algae are producers that use sunlight as energy to make food from carbon dioxide and water in the process of photosynthesis. During photosynthesis, plants, algae, and certain bacteria capture the sun’s energy in chlorophyll molecules. (Chlorophyll is a pigment that gives plants their green color.) This energy, in turn, is used to synthesize energy-rich compounds such as glucose, which can be used to power activities such as growth, maintenance, and reproduction or can be stored as biomass for later use. These energy-rich compounds can also be passed on in the form of biomass from one organism to another, as when animals (primary consumers) graze on plants or when decomposers break down detritus (dead organic matter). The energy collected by green plants is called primary production because it forms the first level at the base of the ecological pyramid. Total photosynthesis is represented as gross primary production. This is the amount of the sun’s energy actually assimilated by autotrophs. The rate of this production of organic tissue by photosynthesis is called primary productivity. Plants, however, need to utilize some of the energy they produce for their own growth, maintenance, and reproduction. This energy becomes available for such activities through respiration, which essentially is a chemical reversal of the process of photosynthesis. As a result, not all the energy assimilated by autotrophs is available to the consumers in the next trophic level of the pyramid. Consequently, respiration costs generally are subtracted from gross primary production to determine the net primary production, the chemical energy actually available to primary consumers. Measuring Ecosystem Productivity The carrying capacity for all the species supported by an ecosystem ultimately depends upon the system’s net primary productivity. By knowing the productivity, ecologists can, for example, estimate the number of herbivores that an ecosystem can support. Consequently ecosystem ecologists have developed a variety of methods to measure the net primary productivity of different systems. Productivity is generally expressed in kilocalories per square meter per year when quantifying energy, and in grams per square meter per year when quantifying biomass. 187
Ecosystems: definition and history Production in aquatic ecosystems may be measured by using the light and dark bottle method. In this technique two bottles containing samples of water and the natural phytoplankton population are suspended for twenty-four hours at a given depth in a body of water. One bottle is dark, permitting respiration but no photosynthesis by the phytoplankton. The other is clear and therefore permits both photosynthesis and respiration. The light bottle provides a measure of net production (photosynthesis minus respiration) if the quantity of oxygen is measured before and after the twenty-four-hour period. (The amount of oxygen produced by photosynthesis is proportional to the amount of organic matter fixed.) Measuring the amount of oxygen in the dark bottle before and after the run provides an estimate of respiration, since no photosynthesis can occur in the dark. Combining net production from the light bottle with total respiration from the dark bottle yields an estimate of gross primary production. Other studies have concentrated on quantifying the rate of movement of energy and materials through ecosystems. Investigations begun in the 1940’s and 1950’s by the Atomic Energy Commission to track radioactive fallout were eventually diverted into studies of ecosystems that demonstrated how radionuclides moved through natural environments by means of food-chain transfers. This research confirmed the interlocking nature of all organisms linked by the food relationship and eventually yielded rates at which both organic and inorganic materials could be cycled through ecosystems. As a result of such studies, the Radiation Ecology Section at Oak Ridge National Laboratory in Tennessee became established as a principal center for systems ecology. Ecologists sometimes extend the temporal boundaries of their studies by utilizing the methods of paleoecology (the use of fossils to study the nature of ecosystems in the past). Research of this type generally centers on the analysis of lake sediments, whose layers often hold centuries of ecosystem history embodied in the character and abundance of pollen grains, diatoms, fragments of zooplankton, and other organic microfossils. More general trends in the methods of studying ecosystems include a continuing emphasis on quantitative methods, often using increasingly sophisticated computer modeling techniques to simulate ecosystem functions. Equally significant is a trend toward a “big science” approach, modeled on the Manhattan Project, which employed teams of investigators working on different problems related to nuclear fission in different parts of the country. The well-known international biological program, the Hubbard Brook project in New Hampshire, and continuing projects on longterm ecological research all serve as examples of ecosystem studies that involve teams of researchers from a wide range of disciplines. 188
Ecosystems: definition and history Responding to Disturbance One of the practical benefits of studying ecosystems derives from naturalist Stephen Forbes’s suggestion, made in 1880, that the knowledge from biological research be used to predict the response of organisms to disturbance. When disturbance is caused by natural events such as droughts, floods, or fires, ecologists can use their knowledge of the structure and function of ecosystems to help resource managers plan for the subsequent recolonization and succession of species. The broad perspective of the ecosystem approach becomes particularly useful in examining the effects of certain toxic compounds because of the complexity of their interaction within the environment. The synergistic effects that sometimes occur with toxic substances can produce pronounced impacts on ecosystems already stressed by other disturbances. For example, after the atmosphere deposits mercury on the surface of a lake, the pollutant eventually settles in the sediments where bacteria make it available to organisms at the base of the food chain. The contaminant then bioaccumulates as it is passed on to organisms such as fish and fish-eating birds at higher trophic levels. Synergistic effects occur in lakes already affected by acid deposition; researchers have found that acidity somehow stimulates microbes to increase the bioavailability of the mercury. Thus, aquatic ecosystems that have become acidified through atmospheric processes may stress their flora and fauna even further by enhancing the availability of mercury from atmospheric fallout. The complexity of such interactions demands research at the ecosystem level, and ecosystem studies are prerequisite for prudent public policy actions on environmental contaminants. Robert Lovely See also: Biomes: determinants; Biomes: types; Communities: ecosystem interactions; Ecology: history; Ecosystems: studies; Food chains and webs; Geochemical cycles; Habitats and biomes; Lakes and limnology; Nutrient cycles; Trophic levels and ecological niches. Sources for Further Study Begon, M., J. L. Harper, and C. R. Townsend. Ecology: Individuals, Populations, and Communities. Oxford, England: Blackwell Scientific Publications, 1996. Clark, Tim W., A. Peyton Curlee, Steven C. Minta, and Peter M. Kareiva, eds. Carnivores in Ecosystems: The Yellowstone Experience. New Haven, Conn.: Yale University Press, 1999. Colinvaux, Paul. Why Big Fierce Animals Are Rare: An Ecologist’s Perspective. Princeton, N.J.: Princeton University Press, 1978. 189
Ecosystems: definition and history Golly, Frank Benjamin. A History of the Ecosystem Concept in Ecology: More than the Sum of the Parts. New Haven, Conn.: Yale University Press, 1993. Hagen, Joel B. An Entangled Bank: The Origins of Ecosystem Ecology. New Brunswick, N.J.: Rutgers University Press, 1992. Hunter, Malcolm, Jr. Maintaining Biodiversity in Forest Ecosystems. New York: Cambridge University Press, 1999. Odum, Eugene P. Ecology and Our Endangered Life-Support Systems. Sunderland, Mass.: Sinauer Associates, 1989. Real, Leslie A., and James H. Brown. Foundations of Ecology: Classic Papers with Commentaries. Chicago: University of Chicago Press, 1991. Smith, Robert Leo. Ecology and Field Biology. 6th ed. San Francisco: Benjamin/Cummings, 2001.
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ECOSYSTEMS: STUDIES Type of ecology: Ecosystem ecology The study of ecosystems defines a specific area of the earth and the attendant interactions among organisms and the physical-chemical environment present at the site.
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cosystems are viewed by ecologists as basic units of the biosphere, much as cells are considered by biologists to be the basic units of an organism. Ecosystems are self-organized and self-regulating entities within which energy flows and resources are cycled in a coordinated, interdependent manner to sustain life. Disruptions and perturbations to, or within, the unit’s organization or processes may reduce the quality of life there or cause its demise. Ecosystem boundaries are usually defined by the research or management questions being asked. An entire ocean can be viewed as an ecosystem, as can a single tree, a rotting log, or a drop of pond water. Systems with tangible boundaries—such as forests, grasslands, ponds, lakes, watersheds, seas, or oceans—are especially useful to ecosystem research. Research Principles The ecosystem concept was first put to use by American limnologist Raymond L. Lindeman in the classic study he conducted on Cedar Bog Lake, Minnesota, which resulted in his article “The Trophic Dynamic Aspect of Ecology” (1942). Lindeman’s study, along with the publication of Eugene P. Odum’s Fundamentals of Ecology (1953), converted the ecosystem notion into a guiding paradigm for ecological studies, thus making it a concept of theoretical and applied significance. Ecologists study ecosystems as integrated components through which energy flows and resources cycle. Although ecosystems can be divided into many components, the four fundamental ones are abiotic (nonliving) resources, producers, consumers, and decomposers. The ultimate sources of energy come from outside the boundaries of the ecosystem (solar energy or chemothermo energy from deep-ocean hydrothermal vent systems). Because this energy is captured and transformed into chemical energy by producers and translocated through all biological systems via consumers and decomposers, all organisms are considered as potential sources of energy. Abiotic resources—water, carbon dioxide, nitrogen, oxygen, and other inorganic nutrients and minerals—primarily come from within the bound191
Ecosystems: studies aries of the ecosystem. From these, producers utilizing energy synthesize biomolecules, which are transformed, upgraded, and degraded as they cycle through the living systems that comprise the various components. The destiny of these bioresources is to be degraded to their original abiotic forms and be recycled. The ecosystem approach to environmental research is a major endeavor. It requires amassing large amounts of data relevant to the structure and function of each component. These data are then integrated among the components, in an attempt to determine linkages and relationships. This holistic ecosystem approach to research involves the use of systems information theory, predictive models, and computer application and simulations. As ecosystem ecologist Frank B. Golley stated in his book A History of the Ecosystem Concept in Ecology (1993), the ecosystem approach to the study of ecosystems is “machine theory applied to nature.” Research Projects Initially, ecosystem ecologists used the principles of Arthur G. Tansley, Lindeman, and Odum to determine and describe the flow of energy and resources through organisms and their environment. Fundamental academic questions that plagued ecologists concerned controls on ecosystem productivity: What are the connections between animal and plant productivity? How are energy and nutrients transformed and cycled in ecosystems? Once fundamental insights were obtained, computer-model-driven theories were constructed to provide an understanding of the biochemophysical dynamics that govern ecosystems. Responses of ecosystem components could then be examined by manipulating parameters within the simulation model. Early development of the ecosystem concept culminated, during the 1960’s, in defining the approach of ecosystem studies. Ecosystem projects were primarily funded under the umbrella of the International Biological Program (IBP). Other funding came from the Atomic Energy Commission and the National Science Foundation. The intention of the IBP was to integrate data collected by teams of scientists at research sites that were considered typical of wide regions. Although the IBP was international in scope, studies in the United States received the greatest portion of the funds—approximately $45 million during the life of IBP (1964-1974). Five major IBP ecosystem studies, involving grasslands, tundra, deserts, coniferous forests, and deciduous forests, were undertaken. The Grasslands Project, directed by George Van Dyne, set the research stage for the other four endeavors. However, because the research effort was so exten192
Ecosystems: studies sive in scope, the objectives of the IBP were not totally realized. Because of the large number of scientists involved, little coherence in results was obtained even within the same project. A more pervasive concern, voiced by environmentalists and scientists alike, was that little of the information obtained from the ecosystem simulation models could be applied to the solution of existing environmental problems. An unconventional project partially funded by the IBP was called the Hubbard Brook Watershed Ecosystem. Located in New Hampshire and studied by F. Herbert Bormann and Gene E. Likens, the project redirected the research approach for studying ecosystems from the IBP computermodel-driven theory to more conventional scientific methods of study. Under the Hubbard Brook approach, an ecosystem phenomenon is observed and noted. A pattern for the phenomenon’s behavior is then established for observation, and questions are posed about the behavior. Hypotheses are developed to allow experimentation in an attempt to explain the observed behavior. This approach requires detailed scrutiny of the ecosystem’s subsystems and their linkages. Since each ecosystem functions as a unique entity, this approach has more utility. The end results provide insights specific to the activities observed within particular ecosystems. Explanations for these observed behaviors can then be made in terms of biological, chemical, or physical principles. Utility of the Concept Publicity from the massive ecosystem projects and the publication of Rachel Carson’s classic Silent Spring (1962) helped stimulate the environmental movement of the 1960’s. The public began to realize that human activity was destroying the bioecological matrices that sustained life. By the end of the 1960’s, the applicability of the IBP approach to ecosystem research was proving to be purely academic and provided few solutions to the problems that plagued the environment. Scientists realized that, because of the lack of fundamental knowledge about many of the systems and their links and because of the technological shortcomings that existed, ecosystems could not be divided into three to five components and analyzed by computer simulation. The more applied approach taken in the Hubbard Brook project, however, showed that the ecosystem approach to environmental studies could be successful if the principles of the scientific method were used. The Hubbard Brook study area and the protocols used to study it were clearly defined. This ecosystem allowed hypotheses to be generated and experimentally tested. Applying the scientific method to the study of ecosystems had practical utility for the management of natural resources and for testing 193
Ecosystems: studies possible solutions to environmental problems. When perturbations such as diseases, parasites, fire, deforestation, and urban and rural centers disrupt ecosystems from within, this approach helps define potential mitigation and management plans. Similarly, external causative agents within airsheds, drainage flows, or watersheds can be considered. The principles and research approach of the ecosystem concept are being used to define and attack the impact of environmental changes caused by humans. Such problems as human population growth, apportioning of resources, toxification of biosphere, loss of biodiversity, global warming, acid rain, atmospheric ozone depletion, land-use changes, and eutrophication are being holistically examined. Management programs related to woodlands (the New Forestry program) and urban and rural centers (the Urban to Rural Gradient Ecology, or URGE, program), as well as other governmental agencies that are investigating water and land use, fisheries, endangered species, and exotic species introductions, have found the ecosystem perspective useful. Ecosystems are also viewed as systems that provide the services necessary to sustain life on earth. Most people either take these services for granted or do not realize that such natural processes exist. Ecosystem research has identified seventeen naturally occurring services, including water purification, regulation, and supply, as well as atmospheric gas regulation and pollination. A 1997 article by Robert Costanza and others, “The Value of the World’s Ecosystem Services and Natural Capital,” placed a monetary cost to humanity should the service, for some disastrous reason, need to be maintained by human technology. The amount is staggering, averaging $33 trillion per year. Humanity could not afford this; the global gross national product is only about $20 trillion. Academically, ecosystem science has been shown to be a tool to dissect environmental problems, but this has not been effectively demonstrated to the public and private sectors, especially decision makers and policymakers at governmental levels. The idea that healthy ecosystems provide socioeconomic benefits and services remains controversial. In order to bridge this gap between academia and the public, Scott Collins of the National Science Foundation suggested to the Association of Ecosystem Research Centers that ecosystem scientists be “bilingual”; that is, they should be able speak their scientific language and translate it so that the nonscientist can understand. Richard F. Modlin See also: Biodiversity; Biomes: determinants; Biomes: types; Communities: ecosystem interactions; Desertification; Ecosystems: definition and 194
Ecosystems: studies history; Geochemical cycles; Habitats and biomes; Hydrologic cycle; Nutrient cycles; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Aber, J. D., and J. M. Melillo. Terrestrial Ecosystems. 2d ed. San Diego, Calif.: Harcourt Academic Press, 2001. Allen, T. F. H., and T. W. Hoekstra. Toward a Unified Ecology. New York: Columbia University Press, 1992. Costanza, Robert, et al. “The Value of the World’s Ecosystem Services and Natural Capital.” Nature 387, no. 6630 (May 15, 1997): 253-260. Daily, Gretchen C., ed. Nature’s Services: Societal Dependence on Natural Ecosystems. Washington, D.C.: Island Press, 1997. Dodson, Stanley I., et al. Ecology. New York: Oxford University Press, 1998. Golley, Frank B. A History of the Ecosystem Concept in Ecology. New Haven, Conn.: Yale University Press, 1993. Likens, Gene E. The Ecosystem Approach: Its Use and Abuse. Oldendorf/ Luhe, Germany: Ecology Institute, 1992. Vogt, Kristiina A., et al. Ecosystems: Balancing Science with Management. New York: Springer, 1997.
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ENDANGERED ANIMAL SPECIES Type of ecology: Restoration and conservation ecology Endangered species are those varieties of plants and animals that are in immediate danger of becoming extinct. Threatened species, by contrast, are those identified as likely to become endangered in the near future.
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t the beginning of 2003, the U.S. Fish and Wildlife Service listed nearly 400 animal species in the United States as “endangered”: in immediate danger of extinction. Another 129 species of animals were designated as threatened, meaning likely to become endangered in the near future. Globally, the World Conservation Union (IUCN) has placed thousands of species on its list of endangered and vulnerable species, and more are added every month. The International Council for Bird Preservation has announced that more than one thousand of the nearly ten thousand species of birds are endangered. Fish, especially freshwater fish, are among the most immediately threatened types of animals. About one-fourth of the worldwide number of species is in a state of dangerous decline. Causes of Species Endangerment The destruction of animal species is caused in four major ways: Humans have hunted other species out of existence; habitats, the environments in which plants or animals grow and develop, have been destroyed; new species, such as rats, cats, goats, or ground-covering plants, have been introduced into a region and displaced native species; and nonnative plants and animals have introduced diseases into an environment, killing the existing species. For much of history, hunting was the major cause of species extinction. However, hunting has become less of a factor because governments and conservation authorities have imposed strict controls on the practice. In the second half of the twentieth century, habitat destruction and invasion by exotics (nonnative plants and animals) and the diseases they carry caused the most damage. Most biologists agree that whatever the factors involved, the rate of extinction has increased rapidly since the 1950’s. Some people have argued that the destruction of a single species of fish, bird, or flower would make little or no difference to the future of human life or the earth. They also suggest that extinctions have always taken place, even before human beings existed, and therefore are simply part of the natural process of existence. Who, for instance, would really want to have “saved” the dinosaurs? We should be glad they are gone. At least ten 196
Endangered animal species million species exist, so who would miss a few dozen or a few hundred of them? These arguments ignore an important point. Each species inhabits a small part of an entire ecosystem, a community of plants and animals that are closely associated in a chain of survival. For example, plants absorb chemicals and minerals from the soil that are essential to their health. Animals then eat the plants—grasses, fruits, leaves, or flowers—and digest the nutrients they need for energy. Other animals, meat eaters (carnivores), then eat these plant eaters and get their energy from them. If a single species is removed from this chain, the whole ecosystem will experience consequences that are difficult to predict and often negative or disastrous. The death of an entire species constitutes a loss that cannot always be measured in economic terms. The American biologist William Beebe made the point that any species that is lost diminishes the quality of life for everyone: The beauty and genius of a work of art may be reconceived, though its first material expression can be destroyed; a vanished harmony may yet inspire the composer, but when the last individual of a race of living things breathes no more, another heaven and another earth must pass before such a one can be again.
The bald eagle, and other bird populations, became endangered partly as a result of the widespread use of DDT, a pesticide whose toxicity becomes concentrated as it makes its way up the food chain. Agricultural runoff into streams and lakes causes such pesticides to accumulate in the microorganisms on which fish feed, then the fish, and finally the predators that eat the fish, from birds to humans. (PhotoDisc) 197
Endangered animal species How Species Are Lost The passenger pigeon is one example of species loss, a bird so numerous in the 1820’s that John James Audubon, the famous American painter and collector, wrote that the flapping of wings of flocks numbering in the hundreds of millions on the Great Plains sounded like the roar of thunder. More than nine billion of the pigeons were alive in 1850, yet slightly more than sixty years later, exactly one bird, Martha, survived in the Cincinnati Zoo, where she had been taken in 1912. The population fell from nine billion to one in little more than half a century, then to zero when Martha died on September 1, 1917. People had found these pigeons delicious to eat and easy to kill. They formed hundreds of hunting parties, killing more than fifty thousand birds a week. No one dreamed the passenger pigeon could ever be exterminated. The same fate almost befell the American bison, often called the buffalo. Before the coming of railroads and white settlers in the 1860’s and 1870’s, the bison numbered more than 100 million. Native Americans hunted the bison, eating their flesh and using the skins for clothing and shelter, but
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Endangered animal species they killed only what they needed. The settlers, however, saw the bison as a problem that needed to be solved. Huge herds of bison crossed railroad tracks, forcing passenger trains to stop, and the animals interfered with farming, knocking down fences and trampling grain fields. Railroad companies and the U.S. Army sent out hunting parties to get rid of the bison. By 1890 fewer than one thousand bison survived in a herd that had managed to escape far into northern Canada. The extermination ended only after this small herd was given protection by the Canadian government. Stories of other near extinctions are numerous and frightening but demonstrate that action can be taken to save some if not all of the endangered species. Whales, which had been hunted since the 1600’s, faced possible extinction until action was taken to reduce hunting in the 1970’s. Whales were easy to kill and provided oil and bone. Whale oil was the major substance burned in lamps until the electric light largely replaced oil-burning lamps in the 1880’s. Europeans hunted the Atlantic whale, called the right whale because it was the “right” one to kill, into virtual extinction by the 1860’s. When the right whale became too hard to find, hunters turned to the Pacific right whale and then the bowhead whale before action was taken by the world community to save remaining whales. Greed and Ignorance Human greed has brought death or near death to many species. The desire for fur coats has nearly killed all jaguars, snow leopards, and various species of fur seals. Pribilof Island fur seals were nearly hunted into extinction in the late 1800’s. A treaty between the United States, Canada, and Russia established limits on killing the species in its remote northern Pacific island habitat, but enforcement has proved difficult, and thousands of seals have been slaughtered despite international protection. The belief that some animals are nuisances has led to the near extinction of wolves, grizzly bears, cougars, and coyotes. These predators have been poisoned and shot by the thousands and have become endangered species as a result. Attempts to kill insects with pesticides in order to control the spread of disease and improve crop yields were successful but had an unfortunate side effect. Chemicals from the pesticides worked their way into ecosystems, killing millions of other forms of life. In the 1950’s, dichlorodiphenyl-trichloroethane, or DDT, was used to kill malaria-carrying mosquitoes, but the chemical infested the whole food chain. It entered plants that were eaten by animals and affected birds, fish, and butterflies. Pesticide poisoning also diminished the numbers of the bald eagle and peregrine falcon, which started to come back only after rigid controls on pesticides were established. 199
Endangered animal species Events on the island of Madagascar, a large island in the Indian Ocean off the east coast of Africa, demonstrate most fully the deadly consequences of habitat destruction. About 180 million years ago, the island was attached to the African continent, then was split off after a series of geological catastrophes and ended up 250 miles to the east. The split occurred just at the time mammals were emerging as a class of animals in Africa. One mammal species, the monkeylike lemur, became isolated on Madagascar and increased abundantly. Other animals caught on the island included several kinds of giant birds, one weighing one thousand pounds and standing ten feet tall. The island was isolated for millions of years, allowing hundreds of species found nowhere else in the world to evolve in the diverse island ecosystems. Madagascar had deserts, rain forests, dry forests, and seashores. About 99 percent of its reptiles, 81 percent of its plants, and 99 percent of its frogs were unique and tied specifically to the island’s food chain. About nine thousand years ago, the Malagasy people began to arrive on the island. They hunted, fished, began to grow crops, and in the process destroyed more than 90 percent of the forests that covered Madagascar. Dozens of species died as a result, including the giant elephant bird, which was gone by 1700. Ten out of thirty-one species of lemur died out by 1985. The loss of Madagascar’s forests caused terrible erosion, which resulted in flooding and the destruction of more trees. Madagascar’s entire ecological system is now threatened, and hundreds of unique species are listed as endangered. Only major restrictions on farming and habitat destruction can save these animals. Endangered Species Acts The implications of species and habitat destruction were first described in books such as Rachel Carson’s Silent Spring (1962). Carson, a biologist with the U.S. Department of Interior, wrote about the effects of DDT and insecticides on birds and other animals. Her book inspired Congress to pass the Endangered Species Preservation Act in 1966. This law authorized the secretary of the interior to protect certain fish and wildlife through the creation of a National Wildlife Refuge System. Congress strengthened the law in 1969 by restricting importation of threatened species and adding more domestic species to the list of those deserving protection. The U.S. Department of the Interior published its first list of endangered species in 1967. The list included seventy-two native species of animals, including grizzly bears, certain butterflies, bats, crocodiles, and trout. No plants were on this list. In 1973, President Richard M. Nixon signed into law an Endangered Species Act that gave the secretaries of the interior and of commerce responsibility for creating a list of endangered animals and 200
Endangered animal species
Endangered Animal Species U.S.
Foreign
Total
Mammals
65
251
316
Birds
78
175
253
Reptiles
14
64
78
Amphibians
12
8
20
Fishes
71
11
82
Clams
62
2
64
Snails
21
1
22
Insects
35
4
39
Arachnids
12
0
12
Crustaceans
18
0
18
388
516
904
Total
Source: Data are from U.S. Fish & Wildlife Service, Threatened and Endangered Species System (TESS), http://ecos.fws.gov/tess/html/boxscore.html, accessed on March 22, 2003.
plants, or species in immediate danger of extinction. Another list would include species threatened with extinction, or those likely to become endangered in the foreseeable future. Once an animal or plant was on either of the lists, no one could kill, capture, or harm it. Penalties for violators were increased, and international or interstate trade of listed species was prohibited. Fines up to ten thousand dollars could be imposed for knowingly violating the act and one thousand dollars for unwittingly violating it. A separate provision of the law mandated that federal agencies could not engage in projects that would destroy or modify a habitat critical to the survival of a threatened or endangered plant or animal. This provision became a very important tool in the battle to save species. Friends of wildlife used it to block highway and dam projects, at least until government officials could prove that construction would have no major impact on a fragile ecosystem. The law even called for affirmative measures to aid in the recovery of listed species. The secretaries of the interior and of commerce were required to produce recovery plans detailing steps necessary to bring a species back to a point where it no longer needed protection. Money was appropriated for states to design recovery programs, and most states established plans of their own to deal with local crises. 201
Endangered animal species A major threat to the 1973 law arose in 1978 during the Tellico Dam controversy. The Tennessee Valley Authority, a federal government agency, proposed building a hydroelectric dam on the Tennessee River in Loudon County, Tennessee, in the late 1970’s. Shortly after plans were made public, a scientist from the University of Tennessee discovered a three-inch-long fish, the snail darter, that was unique to that area. Building the dam, a $250 million project, would destroy that snail darter’s habitat and eliminate the fish. Environmentalists successfully argued in federal court that the dam had to be abandoned. The U.S. Supreme Court supported the ruling of the lower court, arguing that when Congress passed the law, it had intended that endangered species be given the highest priority regardless of the cost or other concerns involved. However, in 1981, Congress enacted a special exemption that excluded “economically important” federal projects from the act. A federal judge then found the Tellico Dam to be without economic importance, and construction was again halted. Congressmen friendly to dam interests then slipped an amendment directing completion of the dam onto an unrelated environmental bill, which passed, and Tellico was constructed. However, the principle of protection remained intact, and the power of the 1973 act remained in force. The snail darter apparently survived, too, as scientists found it living in a river not far from the spot where it was originally discovered. International Trade Bans The 1973 act also made the United States a partner in the Convention on International Trade in Endangered Species of Wild Flora and Fauna. This treaty came out of a conference in Washington, D.C., attended by representatives from eighty nations. It created an international system for control of trade in endangered species. Enforced by the World Conservation Union (IUCN) headquartered in Switzerland, the convention has more than one hundred members. The IUCN publishes a series of lists in its Red Data Book designating three categories of species. Category one consists of those in immediate danger and therefore absolutely banned from international hunting and trading. Animals and plants in categories two and three are not immediately threatened but require special export permits before they can be bought and sold because their numbers have been seriously reduced. This convention has a major flaw, a loophole that can be exploited by any member. A nation can make a “reservation” on any listed species, exempting itself from the ban on trade. Japan has been the most frequent user of the reservation, exempting itself from controls on the fin whale, the hawksbill turtle, and the saltwater crocodile, all on the IUCN’s most en202
Endangered animal species dangered list. Unless this loophole is closed, the IUCN can do little to save extremely threatened species. Restoring Endangered Species Several species in the United States—the California condor, the blackfooted ferret, whooping cranes, and a bird called the Guam rail—have been saved from extinction because of the 1973 Endangered Species Act. The road to extinction has also been reversed for the brown pelican, found in the southeastern states, the American alligator, which had almost been hunted to extinction in Florida, and the perigrine falcon in the eastern states. Other species, however, such as the dusky seaside sparrow and the Palos Verdes butterfly, have totally disappeared. The spotted owl found in parts of the rain forest in Oregon and Washington has attracted a good deal of attention because of efforts to save it. The case of the owl points to the most difficult questions raised by the act: Which comes first, the welfare of the plant or animal, or the economic needs of people? Each pair of spotted owls needs six to ten square miles of forest more than 250 years old in which to hunt and breed. The owls also need large hollow trees for nesting, as well as large open fields in which to search for mice and other small animals. A suitable ecosystem that meets all these needs is found only in parts of twelve national forests in the region. At the same time, loggers in the areas need jobs. When the two interests, represented by the lumber industry and environmentalists, collide, it is left to the courts to determine which interest will prevail or whether a compromise can be arranged. Outside the United States, the future of endangered species appears much grimmer. Scientists at IUCN think several hundred thousand species will disappear by the end of the second decade of the twenty-first century. Many of these species have never even been identified or named. The most endangered habitats in the world are the tropical rain forests, which were reduced by half, nearly 3.5 million square miles, during the twentieth century. About 43,000 square miles are destroyed each year, mainly to provide farms and cattle ranches. The most threatened large animal species in these forests are the large cats, including tigers, jaguars, and leopards; fifteen of the twenty-five species of cats that live in the forests are on the most endangered list. One solution to forest destruction has been the creation of large wildlife refuges. Several African nations have created one or more of these, but there are limits to the amount of land available for conservation efforts. Another solution is the establishment of more wildlife zoos. Several zoos have successful programs for saving species on the very edge of extinction. 203
Endangered animal species However, capacity is limited, and the very small numbers of animals in a zoo’s herd create problems of interbreeding and the handing down of recessive genes. For many species, it is too late to do very much, so scientists and biologists divide populations into three groups: those that can survive without help, those that would die regardless of whether help is provided, and those species that might survive with help and would certainly die without it. Environmentalisms and restoration ecologists focus their efforts on the plants and animals that fall into the third category. Resources are limited, however, and much work needs to be done, or extinctions will take place at a pace as yet unseen in the history of living things. Leslie V. Tischauser See also: Balance of nature; Biodiversity; Communities: ecosystem interactions; Conservation biology; Deforestation; Ecosystems: definition and history; Ecosystems: studies; Endangered plant species; Extinctions and evolutionary explosions; Genetic diversity; Habitats and biomes; Nonrandom mating, genetic drift, and mutation; Old-growth forests; Pollution effects; Reefs; Reforestation; Restoration ecology; Species loss; Sustainable development; Trophic levels and ecological niches; Urban and suburban wildlife; Wildlife management; Zoos. Sources for Further Study Beacham, Walton, and Kirk H. Beets, eds. Beacham’s Guide to International Endangered Species. Osprey, Fla.: Beacham, 1998. Disilvestro, Roger L. The Endangered Kingdom: The Struggle to Save America’s Wildlife. New York: John Wiley & Sons, 1989. Endangered Species of the World. 2 vols. Detroit: Gale Research, 1994. Endangered Wildlife of the World. 11 vols. New York: Marshall Cavendish, 1993. Sherry, Clifford J. Endangered Species: A Reference Handbook. Santa Barbara, Calif.: ABC-Clio, 1998. Wilson, Edward O. The Diversity of Life. New York: W. W. Norton, 1993.
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ENDANGERED PLANT SPECIES Type of ecology: Restoration and conservation ecology The World Conservation Union defines “endangered species” as those in immediate danger of extinction and “threatened species” as those at a high risk of extinction but not yet endangered. Vulnerable species are considered ones that are likely to become extinct at some point in the foreseeable future. Rare species are at risk but not yet at the vulnerable, threatened, or endangered levels.
W
orldwide, the number of endangered plant species was estimated at more than 33,418 in 1999. This number is much higher than that of all of the endangered or threatened animal species combined. Although extinction is a natural process, and all species will eventually be extinct, human activities threaten the existence of plant and animal life worldwide. Humans use plants for food; medicine; building materials; energy; to clean water, air, and soil of pollutants; to control erosion; and to convert carbon dioxide to oxygen. The process of extinction increased dramatically during the nineteenth and twentieth centuries because of habitat destruction or loss, deforestation, competition from introduced species, pollution, global warming, and plant hunting, collecting, and harvesting. Over time, pollutants and contaminants accumulate in the soil and remain in the environment, some for many decades. Pollution in the atmosphere also contributes to long-term changes in climate. Habitat loss By far the most significant threat to plant species is habitat loss or destruction. Habitat loss can occur because of resource harvesting for food, medicine, and other products; deforestation; and the conversion of wilderness for agricultural, industrial, or urban uses. Wood consumption and tree clearing for agriculture and development threaten the world’s forests, especially the tropical forests, which may disappear by the mid-twenty-first century if sufficient preventive action is not taken. Natural disasters, such as climatic changes, meteorites, floods, volcanic eruptions, earthquakes, hurricanes, drought, and tornados, also can be devastating to a habitat. In Europe and Asia, the plant distribution is complex, with isolated populations of plants spread across a large area. The plants are greatly influenced by the cold climate and by humans. Plant species are disappearing, especially in Europe and the Mediterranean, because of habitat destruction and disturbances including urbanization, road construction, 205
Endangered plant species
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overgrazing, cultivation, forest plantation, fire, pollution, and overexploitation of resources or for use in horticulture. Mountain plants are threatened by development for industry and tourism, pollution, strip mining, walkers, and skiers. The wetlands are threatened by removal of peat for fuel, water extraction which lowers the water table, and increased drainage for building or agriculture or fear of malaria. Recreational use and susceptibility to pollution such as acid rain or fertilizer run-off present further threats. In North America, the major causes of endangerment include loss of habitat, overexploitation of resources, introduction of invasive species, and pollution. A massive loss of wilderness has occurred through the clearing of forests, plowing of prairies, and draining of swamplands. For example, in the northeastern United States there are only 13 square miles of alpine habitat, an area in which grow thirty-three at-risk species. This area is heavily used by hikers and mountain bikers. The Florida Everglades are threatened because the water supply is diverted to supply cities, industry, and agriculture. In California, the Channel Islands are home to seventy-six flowering plants which do not exist on the mainland. Eighteen species are located on 206
Endangered plant species just one island. These plants, including the San Clemente broom, bush mallow (Malacothamnus Greene), a species of larkspur, and the San Clemente Island Indian paintbrush (Castilleja grisea), have been devastated by introduced grazers, browsers, and by invasive other plants. In Hawaii, more than 90 percent of native plants and almost all land birds and invertebrates are found nowhere else in world. The Hawaiian red-flowered geranium Geranium arboreum is threatened by introduced feral pigs, agricultural livestock, and competition by nonnative plants. In developing or highly populated nations in Asia, Africa, Central and South America, the Caribbean, the Pacific Ocean islands, Australia, and New Zealand, habitat loss occurs because of population needs. Land is cleared for agriculture, development, and population resettlement. In Central America and the Caribbean, the Swietenia mahogany is found only in a few protected or remote areas. The Caoba tree (Persea theobromifolia) was newly identified as a species as recently as 1977. The lumber is commercially important, and habitat loss has occurred due to the conversion of forests to banana and palm plantations. In Ecuador, only 6 percent of the original rain forest remains standing, because the rest has been converted to farmland. In Asia, including the Philippines, population pressures bring about deforestation and the clearing of land for agriculture. In southern Africa, land is used for crops, livestock, and firewood production. Overgrazing and the introduction of agriculture have caused the Sahara Desert area to grow rapidly. The island of Madagascar has between ten thousand and twelve thousand plant species, of which 80 percent grow nowhere else in the world. Because of conversion to grassland through farming methods, only about one-fifth of the original species survive. In Australia there are 1,140 rare or threatened plants, and logging, clearing for grazing animals and crops, building developments, and mining have threatened many native species. Plant Hunting, Collecting, and Harvesting Habitat damage, the construction of facilities, and the opening of remote areas for human population have made many plants vulnerable to gathering and collecting. Some plants have been overharvested by gardeners, botanists, and horticulturists. One species of lady’s slipper orchid (Cypripedium calceolus) is rare over much of its natural range except in parts of Scandinavia and the Alps because of collecting. Additionally, many mountain flowers or bulbs such as saxifrages, bellflowers, snowdrops, and cyclamen are endangered. In France and Italy, florulent saxifrage (Saxifraga florulenta), an alpine plant, has been overcollected by horticulturists and poachers. 207
Endangered plant species Parts of the southeastern United States have poor soil that is home to the carnivorous or insectivorous plants—those that eat insects. These plants include sundews, bladderworts, Venus’s flytrap, and pitcher plants. Collectors or suppliers have stripped many areas of all of these plants. In the Southwest, rare cacti are harvested for sale nationwide and worldwide. Endangered cacti include the Nellie Cory cactus (which has one remaining colony), Epithelantha micromeres bokei, Ancistrocactus tubuschii, saguaro cactus (Carnegiea gigantea), and Coryphantha minima. Near the Sierra Madre, two tree species—Guatemalan fir, or Pinabete, and the Ayuque—are endangered because of harvesting for use as Christmas trees or for the making of hand looms. Additionally, sheep eat the seedlings. In New Mexico, the gypsum wild buckwheat habitat is limited to one limestone hill, and the plants are threatened by cattle, off-road vehicles, and botanists. In southern Mexico, there are 411 species of epiphytes (air plants or bromeliads in the genus Tillandsia), of which several are extremely rare. These plants are threatened by overcollection for the houseplant trade or conservatories. The African violet (Saintpaulia ionantha) of Tanzania may soon be extinct in the wild because of the horticultural trade and habitat loss due to encroaching agriculture. Worldwide, orchids are overcollected for horticulture. Several species have been collected to extinction, are extremely rare, or have been lost because of habitat destruction. Examples include the extremely rare blue vanda (Vanda caerulea); Paphiopedilum druryi, believed extinct in its native habitat; Dendrobium pauciflorum, endangered and possibly extinct—only a single plant was known to exist in the wild in 1970; and the Javan phalaenopsis orchid, Phalaenopsis javanica. The latter was believed extinct. When
Endangered Plant Species
Flowering plants Conifers and cycads Ferns and allies Lichens Totals
U.S.
Foreign
Total
570
1
571
2
0
2
24
0
24
2
0
2
598
1
599
Source: Data are from U.S. Fish & Wildlife Service, Threatened and Endangered Species System (TESS), http://ecos.fws.gov/tess/html/boxscore.html, accessed on March 22, 2003.
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Endangered plant species it was rediscovered in 1960’s, it was overcollected by commercial orchid dealers and thereby exterminated. There are no other known wild populations. About 80 percent of the human populations in developing countries rely on traditional medicine, of which 85 percent of ingredients come from plant extracts. In Western medicine, one in four prescription medicines contain one or more plant products. Some at-risk species contain chemicals used in treating medical conditions, such as the African Prunus africana tree, whose bark has chemicals used to treat some prostate gland conditions, and the Strophanthus thollonii, a root parasite with chemicals used in heart drugs. The Madagascan periwinkle (Catharanthus roseus) is commonly cultivated (its close relative Catharanthus coriaceus is rare and its medicinal importance unknown) and produces about seventy chemicals, some of which are useful in the treatment of cancer. The Indian podophyllum (Podophyllum hexandrum), a threatened species, is used to treat intestinal worms, constipation, and cancer. Rauwolfia (Rauvolfia serpentina), also a threatened species, is used to treat mental disorders, hypertension, and as a sedative. The lily Amorphopahllus campanulatus is used to treat stomachaches, and a fig, Ficus sceptica, is used to treat fever; both of these species are vulnerable because of habitat destruction. The Micronesian dragon tree is believed to have magical and medicinal properties. It has been overharvested and is now extinct on several islands. In the United States’ Appalachian Mountains, American ginseng is being overcollected because of an escalating demand for this plant’s health benefits. Conservation The conservation of endangered plant species employs several compelling arguments: Plants enhance the world’s beauty, have the right to exist, and are useful to people. The most persuasive argument may be that the survival of the human species depends on a healthy worldwide ecosystem. Three major goals of conservation are recovery, protection, and reintroduction. Conservation methods depend on increasing public awareness by providing information about endangered or threatened species so that people can take action to reverse damage to the ecosystems. Other important strategies include achieving a widespread commitment to conservation and obtaining funding to protect rare or endangered species. Conservation efforts include setting aside protected areas, such as reserves, wilderness areas, and parks, and recognizing that humans must integrate and protect 209
Endangered plant species biodiversity where they live and work. Many countries are actively conserving species through protected areas, endangered-species acts, detailed studies of species and habitat, and information campaigns directed to the public. Virginia L. Hodges See also: Balance of nature; Biodiversity; Communities: ecosystem interactions; Conservation biology; Deforestation; Ecosystems: definition and history; Ecosystems: studies; Endangered animal species; Extinctions and evolutionary explosions; Genetic diversity; Habitats and biomes; Nonrandom mating, genetic drift, and mutation; Old-growth forests; Pollution effects; Reefs; Reforestation; Restoration ecology; Species loss; Sustainable development; Trophic levels and ecological niches; Urban and suburban wildlife; Wildlife management; Zoos. Sources for Further Study Burton, John A., ed. Atlas of Endangered Species. New York: Macmillan, 1999. Crawford, Mark. Habitats and Ecosystems: An Encyclopedia of Endangered America. Santa Barbara, Calif.: ABC-CLIO, 1999. Freedman, Bill, ed. Encyclopedia of Endangered Species. Vol. 2. Detroit: Gale Research, 1999. Wilson, Edward O. The Future of Life. New York: Alfred A. Knopf, 2001.
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EROSION AND EROSION CONTROL Types of ecology: Agricultural ecology; Ecosystem ecology; Restoration and conservation ecology; Soil ecology Erosion is the loss of topsoil through the action of wind and water. Erosion control is vital because soil loss from agricultural land is a major contributor to nonpointsource pollution and desertification and represents one of the most serious threats to world food security.
I
n the United States alone some two billion tons of soil erode from cropland on an annual basis. About 60 percent, or 1.2 billion tons, is lost through water erosion, while the remainder is lost through wind erosion. This is equivalent to losing 0.3 meter (1 foot) of topsoil from two million acres of cropland each year. Although soil is a renewable resource, soil formation occurs at rates of just a few inches per hundred years, which is much too slow to keep up with erosive forces. The loss of soil fertility is incalculable, as are the secondary effects of polluting surrounding waters and increasing sedimentation in rivers and streams. Erosion removes the topsoil, the most productive soil zone for crop production and the plant nutrients it contains. Erosion thins the soil profile, which decreases a plant’s rooting zone in shallow soils, and can disturb the topography of cropland sufficiently to impede farm equipment operation. It carries nitrates, phosphates, herbicides, pesticides, and other agricultural chemicals into surrounding waters, where they contribute to cultural eutrophication. Erosion causes sedimentation in lakes, reservoirs, and streams, which eventually require dredging. Water Erosion The common steps in water erosion are detachment, transport, and deposition. Detachment releases soil particles from soil aggregates, transport carries the soil particles away and, in the process, scours new soil particles from aggregates. Finally, the soil particles are deposited when water flow slows. In splash erosion, raindrops impacting the soil can detach soil particles and hurl them considerable distances. In sheet erosion, a thin layer of soil is removed by tiny streams of water moving down gentle slopes. This is one of the most insidious forms of erosion because the effects of soil loss are imperceptible in the short term. Rill erosion is much more obvious be211
Erosion and erosion control cause small channels form on a slope. These small channels can be filled in by tillage. In contrast, ephemeral gullies are larger rills that cannot be filled by tillage. Gully erosion is the most dramatic type of water erosion. It leaves channels so deep that even equipment operation is prevented. Gully erosion typically begins at the bottom of slopes where the water flow is fastest and works its way with time to the top of a slope as more erosion occurs. Wind Erosion Wind erosion generally accounts for less soil loss than water erosion, but in states such as Arizona, Colorado, Nevada, New Mexico, and Wyoming, it is actually the dominant type of erosion. Wind speeds 0.3 meter (1 foot) above the soil that exceed 16 to 21 kilometers per hour (10 to 13 miles per hour) can detach soil particles. These particles, typically fine- to mediumsize sand fewer than 0.5 millimeter (0.02 inch) in diameter, begin rolling and then bouncing along the soil, progressively detaching more and more soil particles by impact. The process, called saltation, is responsible for 50 to 70 percent of all wind erosion. Larger soil particles are too big to become suspended and continue to roll along the soil. Their movement is called surface creep.
Topsoil erosion is one of the most economically devastating forms of erosion, caused not only by wind and water erosion but also by human disturbance resulting from agriculture, overgrazing, deforestation, and soil compaction. (PhotoDisc) 212
Erosion and erosion control The most obvious display of wind erosion is called suspension, when very fine silt and clay particles detached by saltation are knocked into the air and carried for enormous distances. The Dust Bowl of the 1930’s was caused by suspended silt and clay in the Great Plains of the United States. It is also possible to see the effects of wind erosion on the downward side of fences and similar obstacles. Wind passing over these obstacles deposits the soil particles it carries. Other effects of wind erosion are tattering of leaves, filling of road and drainage ditches, wearing of paint, and increasing incidence of respiratory ailments. Erosion Control The four most important factors affecting erosion are soil texture and structure, roughness of the soil surface, slope steepness and length, and soil cover. There are several passive and active methods of erosion control that involve these four factors. Wind erosion, for example, is controlled by creating windbreaks, rows of trees or shrubs that shorten a field and reduce the wind velocity by about 50 percent. Tillage perpendicular to the wind direction is also a beneficial practice, as is keeping the soil covered by plant residue as much as possible. Water erosion is controlled by similar cultural practices. For example, highly erosive, steeply sloped land can be protected by placing it in the U.S.-government-sponsored Conservation Reserve Program. Tillage can be done along the contour of slopes. Long slopes can be shortened by terracing, which also reduces the slope steepness. Permanent grass waterways can be planted in areas of cropland that are prone to water flow. Likewise, grass filter strips can be planted between cropland and adjacent waterways to impede the velocity of surface runoff and cause suspended soil particles to sediment and infiltrate before they can become contaminants. Conservation tillage practices, such as minimal tillage and no-tillage, are being widely adapted by farmers as a simple means of erosion control. As the names imply, these are tillage practices in which as little disruption of the soil as possible occurs and in which any crop residue remaining after harvest is left on the soil surface to protect the soil from the impact of rain and wind. The surface residue also effectively impedes water flow, which causes less suspension of soil particles. Because the soil is not disturbed, practices such as no-tillage also promote rapid water infiltration, which also reduces surface runoff. No-tillage is rapidly becoming the predominant tillage practice in southeastern states such as Kentucky and Tennessee, where high rainfall and erodible soils occur. Mark S. Coyne 213
Erosion and erosion control See also: Desertification; Grazing and overgrazing; Integrated pest management; Multiple-use approach; Rangeland; Reforestation; Slash-andburn agriculture; Soil; Soil contamination. Sources for Further Study Gershuny, Grace, and Joseph Smillie. The Soul of Soil: A Guide to Ecological Soil Management. 3d ed. Davis, Calif.: agAccess, 1995. Morgan, R. P. C. Soil Erosion and Conservation. New York: Wiley, 1995. Plaster, Edward. Soil Science and Management. Albany, N.Y.: Delmar, 1997. Schwab, Glenn O., et al., eds. Soil and Water Conservation Engineering. 4th ed. New York: Wiley, 1993.
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ETHOLOGY Type of ecology: Behavioral ecology Ethology is the study of animal behavior from the perspective of zoology. The information acquired through ethology has helped scientists better understand animals in all their variety.
E
thology is the branch of zoology that investigates the behavior of animals. Behavior may be defined as all the observable responses an animal makes to internal or external stimuli. Responses may be either movements or secretions; however, the study of behavior is much more than a descriptive account of what an animal does in response to particular stimuli. The ethologist is interested in the “how” and “why” of the behaviors they observe. Answering such questions requires an understanding of the physiology and ecology of the species studied. Those who study animal behavior are also interested in the ultimate or evolutionary factors affecting behavior. The Roots of Ethology Ethology is a young science, yet it is also a science with a long history. Prior to the late nineteenth century, naturalists had accumulated an abundance of information about the behavior of animals. This knowledge, although interesting, lacked a theoretical framework. In 1859, Charles Darwin published On the Origin of Species by Means of Natural Selection, and with it provided a perspective for the scientific study of behavior. Behavior was more central to two of Darwin’s later books, The Descent of Man and Selection in Relation to Sex (1871) and Expression of the Emotions of Man and Animals (1873). By 1973, the science of ethology was sufficiently well developed to be acknowledged by the presentation of the Nobel Prize for Physiology or Medicine to Nikolaas Tinbergen, Konrad Lorenz, and Karl von Frisch for their contributions to the study of behavior. The work of these men was central to the development of modern ethology. The experimental studies of Frisch revealed the dance language of the honeybee and ways in which the sensory perception of the bees differs from the human sensory world. An awareness of species-specific sensory abilities has provided an important research area and has emphasized a factor that must be considered in the experimental design and interpretation of many types of behavioral research. Tinbergen studied behavior in a variety of vertebrate and invertebrate organisms. He was good both at observation of animals in their natural 215
Ethology habitat and in the design of simple but elegant experiments. His 1951 book The Study of Instinct is a classic synthesis of the knowledge that had been gained through the scientific study of animal behavior of that time. Konrad Lorenz is considered by many to be the founder of ethology, because he discovered and effectively publicized many of the classic phenomena of ethology. Pictures of Lorenz being followed by goslings are almost a standard feature of texts that discuss the specialized form of learning known as imprinting. In natural settings, imprinting allows young animals to identify their parents appropriately. Another contribution of Lorenz was his book King Solomon’s Ring: New Light on Animal Ways, published in 1952. This extremely readable book raised public awareness of the scientific study of animal behavior and kindled the interest of many who eventually joined the ranks of ethologists. Ethology and Neurobiology Many of the features of ethological research characteristic of the work of Lorenz, Tinbergen, and von Frisch have continued to be characteristic of the field. They were concerned that the behavior of animals be understood in the context of the species’ natural habitat and that both proximate and ultimate levels of explanation would be examined. Their research strategies have been supplemented by an increase in laboratory-based research and by the introduction of new types of experimental design. These developments have softened the distinctions between ethology and another field of behavioral study, comparative psychology. The focus of comparative psychology is comparative studies of the behavior of nonhuman animals. Initially, questions about learning and development were the major problems investigated in comparative psychology. Although the animals most frequently studied were primates and rodents, those doing the research were interested in gaining insight into the behavior of humans. Comparative psychology was long dominated by behaviorism, a school of thought that assumes that the ultimate basis of behavior is learning. The behaviorists employed rigorous experimental methods. Because such methods require carefully controlled conditions, behavioral research is typically laboratory based, and animals are therefore tested in surroundings remote from their natural environment. Over time, comparative psychology has broadened both the questions it asks and the organisms it studies. The boundaries between comparative psychology and ethology have been further blurred by the rising number of scientists crossing disciplinary lines in their research. Each discipline has learned from the other, and both have also profited from knowledge introduced through neurobiology and behavioral genetics. 216
Ethology Neurobiology investigates the structure and function of the nervous system. One area of ethology that has been directly enriched through neurobiology is the study of sensory perception in animals. The techniques developed in neurobiology allow the investigator to record the response of many individual neurons simultaneously. The neurobiologist examines phenomena such as stimulus filtering at the level of the cell. Stimulus filtering refers to the ability of nerve cells to be selective in their response to stimuli. For example, moths are highly sensitive to sounds in the pitch range of sounds made by the bats that are their chief predators. Neurobiology provides a powerful tool for understanding behavior at the proximate level. Behavioral Genetics Another source of information for the ethologist is behavioral genetics. Because of the evolutionary context of ethology, it is important to have an understanding of the genetic basis of behavior. If there were no genetic component in behavior, behavior would not be subject to natural selection. (Natural selection refers to the process by which some genes increase in frequency in a population while alternates decrease because the favored genes have contributed to the reproductive success of those organisms that have them.) While the ethological approach to behavior assumes that behavior patterns are the result of interactions between genes and environment, investigators often ask questions about the genetic programming of behavior. Early ethologists performed isolation and cross-fostering experiments to discover whether behaviors are learned or instinctive. If a behavior appears in an individual that has been reared in isolation without the opportunity to learn, the behavior is considered instinctive. Observing the behavior of an individual reared by parents of a different species is similarly revealing. When behavior patterns of conspecifics appear in such crossfostered individuals, such behaviors are regarded as instinctive. Instinctive behaviors typically are innate behaviors that are important for survival. For example, one very common instinctive behavior is the begging call of a newly hatched bird. Isolation and cross-fostering experiments are still a part of the experimental repertoire of ethologists, but behavioral genetics permits the asking of more complex questions. For example, a behavior may accurately be labeled instinctive, but it is more revealing to determine the developmental and physiological processes linking a gene or genes to the instinctive behavior. Behavioral Ecology The ethologist is also interested in determining whether behavior is adaptive. It is not sufficient to identify what seems to be a commonsense advan217
Ethology tage of the behavior. It is important to show that the behavior does in fact contribute to reproductive success in those that practice the behavior and that the reasons the behavior is adaptive are those that are hypothesized. When behaviors are tested, they frequently do turn out to be adaptive in the ways hypothesized. This type of research, however, has provided many surprises. Research on the adaptive value of behaviors in coping with environmental problems that affect reproductive success is known as behavioral ecology, a major subdiscipline of both ethology and ecology. Behavioral ecology addresses a variety of questions, in part because the process of evolution is opportunistic. For any environmental problem there are alternate solutions, and the solution a particular species adopts is dependent upon the possibilities inherent in its genes. Questions addressed include such things as whether a species is using the optimum strategy or how a species benefits from living in a group. Because alternate strategies are possible even within a species, behavioral ecologists are interested in evolutionarily stable strategies. An evolutionarily stable strategy is a set of behavioral rules that, when used by a particular proportion of a population, cannot be replaced by any alternative strategy. For example, the sex ratio present in a particular population will determine the optimum sex ratio for the offspring of any individual. Sociobiology Sociobiology is another major area of modern ethology. Sociobiology examines animal social behavior within the framework of evolution. Animal species vary in the degree of social behavior they exhibit; other variables include group size and the amount of coordination of activities occurring within the group. The sociobiologist is interested in a number of questions, but prominent among them are the reasons for grouping. Hypotheses such as defense against predators or facilitation of reproduction can be tested. The particular advantage or advantages gained by grouping varies among species. Two important concepts in sociobiology are kin selection and inclusive fitness. Kin selection refers to the differential reproduction of genes that affect the survival of offspring or closely related kin. Behavior such as the brokenwing display of the killdeer is an example. The behavior carries risk but would be promoted by selection if the offspring of individuals using the display were protected from predators often enough to compensate for the risk. Inclusive fitness is the term used to recognize the concept that fitness includes the total genotype, including those genes that may lower the individual’s survival as the price of leaving more genes in surviving kin. The 218
Ethology concepts of kin selection and inclusive fitness help to address one problem raised by Darwin, the question of altruistic behavior. Ethology is a young science but a very exciting one, because there are so many questions that can be asked about animal behavior within the context of evolution. Studying Ethology The methods and tools of ethology cover the entire spectrum of complexity. One simple, but demanding, method is to collect normative data about a species. In its simplest form, the scientist observes what an animal does and writes it down in a field notebook. Finding and following the animal, coping with field conditions such as bad weather and rugged terrain, and keeping field equipment in operating condition add challenge and variety to this approach. The ethologist uses various techniques to get data as unbiased as possible. One of these is to choose a focal animal at random (or on a rotation) and observe the focal animal for a specific amount of time before switching observation to another member of the population. This prevents bias in which individuals and which behaviors are observed. The sampling of an individual’s behavior at timed intervals is an even more effective way of avoiding bias. When all or most of an animal’s behavioral repertoire is known, a list known as an ethogram can be constructed. This catalog can be organized into appropriate categories based on function. Ethograms provide useful baseline information about the behavior of a species. For animals that are difficult or impossible to follow, radio-tracking techniques have been developed. Collars that emit radio signals have been designed for many animals. Miniaturization has made it possible for radio tracking to be used even on relatively small animals. In field studies, animals are often marked in some way so that observers are able to follow individual animals. A number of techniques have been developed, including banding birds with colored acrylic bands. Color combinations can be varied so that each member of the population has a unique combination. Marking allows the observer to get information such as individual territory boundaries and to determine which animals interact. Models are frequently used in experiments. For example, a model can be used to determine whether individuals in a species need to learn to identify certain classes of predators. Models were used in many of the classic experiments in ethology. Modern technology has allowed the development of much more sophisticated models. One of the most interesting is a “bee” that can perform a waggle dance (used by bees to indicate location) so effectively that its hivemates can find the food source. Whether a model 219
Ethology is simple or sophisticated, it can provide a tool to determine the cues that trigger an animal’s response. Neurobiologists use electrodes and appropriate equipment to stimulate and record the responses of neurons. They can also stimulate specific regions of the nervous system by using tiny tubes to deliver hormones or neurotransmitters. Genetic technology has made it possible to examine the deoxyribonucleic acid (DNA) of individuals in a species. This tool can be used, for example, to determine whether females in monogamous species are completely monogamous or whether some of their offspring are fathered by males other than their mates. Tape recorders have become very important in studies of animal vocalizations. Recorders are used in two ways. The animal’s vocalizations may be recorded and the recording used to make sound spectrographs for analysis. The recordings may also be used to determine whether individuals can discriminate between the vocalizations of neighboring and nonneighboring individuals in their species. Playbacks can also be used to simulate intruders in the territory of an individual and can be applied to many other experimental situations in both the field and laboratory. The methods used by ethologists are as varied as the problems they investigate. Because the skill of the observer is still a vital link in the investigation of animal behavior, ethology remains one of the more approachable areas of scientific investigation. Uses of Ethology The investigation of animal behavior has a number of benefits, both practical and abstract. Some animals are pests, and knowledge of their behavior can be used to manage them. For example, synthetic pheromones have been used to attract members of some insect species. The insects may then be sampled or killed, depending upon the application. To the extent that researchers develop behaviorally based pest management strategies and reduce pesticide use, they will be promoting our own safety as well as that of other species. It is sometimes important for humans to be able to understand the communication signals of other species and the characteristics of their sensory perception. The knowledgeable individual can recognize the cues that indicate risk that a dog might bite, for example, and can also avoid behavior that the dog will regard as threatening. Understanding the behavior of the wild animals most likely to be encountered in one’s neighborhood is an important factor in peaceful coexistence. The study of animal behavior is providing one of the more fascinating areas of evolutionary biology. Ethology has demonstrated more effectively 220
Ethology than most fields of study how diverse the solutions to a given problem can be and has provided insight into human behavior from a biological perspective. Knowledge of animal behavior also enriches human lives simply by satisfying some of our natural curiosity about animals. Donna Janet Schroeder See also: Altruism; Communication; Defense mechanisms; Displays; Habituation and sensitization; Herbivores; Hierarchies; Insect societies; Isolating mechanisms; Mammalian social systems; Migration; Mimicry; Omnivores; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study Allen, Colin, and Mark Bekoff. Species of Mind: The Philosophy and Biology of Cognitive Ethology. Cambridge, Mass.: MIT Press, 1997. Barrows, Edward M. Animal Behavior Desk Reference. 2d ed. Boca Raton, Fla.: CRC Press, 2000. Clutton-Brock, T. H., and Paul Harvey, eds. Readings in Sociobiology. San Francisco: W. H. Freeman, 1978. Davies, Nicholas B., and John R. Krebs. An Introduction to Behavioral Ecology. 4th ed. Boston, Mass.: Blackwell Scientific Publications, 1997. Goldsmith, Timothy H. The Biological Roots of Human Nature: Forging Links Between Evolution and Behavior. New York: Oxford University Press, 1991. Krebs, J. R., and N. B. Davies, eds. Behavioral Ecology: An Evolutionary Approach. 4th ed. Boston: Blackwell Scientific Publications, 1997. Lehner, Philip N. Handbook of Ethological Methods. 2d ed. New York: Cambridge University Press, 1996. Wilson, Edward O. Sociobiology. Cambridge, Mass.: The Belknap Press of Harvard University Press, 1975.
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EUTROPHICATION Type of ecology: Ecotoxicology The overenrichment of water by nutrients, eutrophication causes excessive plant growth and stagnation, which leads to the death of fish and other aquatic life.
T
he word “eutrophic” comes from the Greek eu, which means “well,” and trophikos, which means “food” or “nutrition.” Eutrophic waters are well nourished, that is, rich in nutrients; they therefore support abundant life. Eutrophication refers to a condition in aquatic systems (ponds, lakes, and streams) in which nutrients are so abundant that plants and algae grow uncontrollably and become a problem. The plants die and decompose, and the water becomes stagnant. This ultimately causes the death of other aquatic animals, particularly fish, that cannot tolerate such conditions. Eutrophication is a major problem in watersheds and waterways, such as the Great Lakes and Chesapeake Bay, that are surrounded by urban populations. The stagnation that occurs during eutrophication is attributable to the activity of microorganisms growing on the dead and dying plant material in water. As they decompose the plant material, microbes consume oxygen faster than it can be resupplied by the atmosphere. Fish, which need oxygen in the water to breathe, become starved for oxygen and suffocate. In addition, noxious gases such as hydrogen sulfide (H2S) can be released during the decay of the plant material. The hallmark of a eutrophic environment is one that is plant-filled, littered with dead aquatic life, and smelly. Eutrophication is actually a natural process that occurs as lakes age and fill with sediment, as deltas form, and as rivers seek new channels. The main concern with eutrophication in natural resource conservation is that human activity can accelerate the process and can cause it to occur in previously clean but nutrient-poor water. This is sometimes referred to as cultural eutrophication. For example, there is great concern with eutrophication in Lake Tahoe. Much of Lake Tahoe’s appeal is its crystal-clear water. Unfortunately, development around Lake Tahoe is causing excess nutrients to flow into the lake and damaging the very thing that attracts people to the lake. Roles of Nitrogen and Phosphorus Nitrogen and phosphorus are the key nutrients involved in eutrophication, although silicon, calcium, iron, potassium, and manganese can be im222
Eutrophication portant. Nitrogen and phosphorus are essential in plant and animal growth. Nitrogen compounds are used in the synthesis of amino acids and proteins, whereas phosphate is found in nucleic acids and phospholipids. Nitrogen and phosphorus are usually in limited supply in lakes and rivers. Plants and animals get these nutrients through natural recycling in the water column and sediments and during seasonal variations, as algae and animals decompose, fall to the lower depths, and release their nutrients to be reused by other organisms in the ecosystem. A limited supply of nutrients—as well as variations in optimal temperature and light conditions—prevents any one species of plants or animals from dominating a water ecosystem. Although nutrient enrichment can have detrimental effects on a water system, an increased supply of nitrogen and phosphorus can have an initial positive effect on water productivity. Much like fertilizers added to a lawn, nutrients added to lakes, rivers, or oceans stimulate plant and animal growth in the entire food chain. Phytoplankton—microscopic algae that grow on the surface of sunlit waters—take up nutrients directly and are able to proliferate. Through photosynthesis, these primary producers synthesize organic molecules that are used by other members of the ecosystem. Increased algal growth thus stimulates the growth of zooplankton—microscopic animals that feed on algae and bacteria—as well as macroinvertebrates, fish, and other animals and plants in the food web. Indeed, many fisheries have benefitted from lakes and oceans that are productive. Oxygen Depletion When enough nutrients are added to a lake or river to disrupt the natural balance of nutrient cycling, however, the excess nutrients effectively become pollutants. The major problem is that excess nutrients encourage profuse growth of algae and rooted aquatic weeds, species that can quickly take advantage of favorable growth conditions at the expense of slower-growing species. Algae convert carbon dioxide and water into organic molecules during photosynthesis, a process that produces oxygen. When large blooms of algae and other surface plants die, however, they sink to the bottom of the water to decompose, a process that consumes large amounts of oxygen. The net effect of increased algae production, therefore, is depletion of dissolved oxygen in the water, especially during midsummer. Reduced oxygen levels (called hypoxia) can have dire consequences for lakes and rivers that support fish and bottom-dwelling animals. Oxygen depletion is greatest in the deep bottom layers of water, because gases from the oxygen-rich surface cannot readily mix with the lower layers. During 223
Eutrophication summer and winter, oxygen depletion in eutrophic waters can cause massive fish kills. In extreme cases of eutrophication, the complete depletion of oxygen (anoxia) occurs, leading to ecosystem crashes and irreversible damage to plant and animal life. Oxygen depletion also favors the growth of anaerobic bacteria, which produce hydrogen sulfide and methane gases, leading to poor water quality and taste. Excessive algal and plant growth has other negative effects on a water system. Algae and plants at the surface block out sunlight to plants and animals at the lower depths. Loss of aquatic plants can affect fish-spawning areas and encourage soil erosion from shores and banks. Eutrophication often leads to loss of diversity in a water system, as high nutrient conditions favor plants and animals that are opportunistic and short-lived. Native sea grasses and delicate sea plants often are replaced by hardier weeds and rooted plants. Carp, catfish, and bluegill fish species replace more valuable coldwater species such as trout. Thick algal growth also increases water turbidity and gives lakes and ponds an unpleasant pea-soup appearance. As algae die and decay, they wash up on shores in stinking, foamy mats. Algal blooms of unfavorable species can produce toxins that are harmful to fish, animals, and humans. These toxins can accumulate in shellfish and have been known to cause death if eaten by humans. So-called red tides and brown tides are caused by the proliferation of unusual forms of algae, which give water a reddish or tealike appearance and in some cases produce harmful chemicals or neurotoxins. Assessing Eutrophication While eutrophication effects are generally caused by nutrient enrichment of a water system, not all cases of nutrient accumulation lead to increased productivity. Overall productivity is based on other factors in the water system, such as grazing pressure on phytoplankton, the presence of other chemicals or pollutants, and the physical features of a body of water. Eutrophication occurs mainly in enclosed areas such as estuaries, bays, lakes, and ponds, where water exchange and mixing are limited. Rivers and coastal areas with abundant flushing generally show less phytoplankton growth from nutrient enrichment because their waters run faster and mix more frequently. On the other hand, activities that stir up nutrient-rich sediments from the bottom, such as development along coastal waters, recreational activities, dredging, and storms, can worsen eutrophication processes. The nutrient status of a lake or water system is often used as a measure of the extent of eutrophication. For example, lakes are often classified 224
Eutrophication as oligotrophic (nutrient-poor), eutrophic (nutrient-rich), or mesotrophic (moderate in nutrients) based on the concentrations of nutrients and the physical appearance of the lake. Oligotrophic lakes are deep, clear, and unproductive, with little phytoplankton growth, few aquatic rooted plants, and high amounts of dissolved oxygen. In contrast, eutrophic lakes are usually shallow and highly productive, with extensive aquatic plants and sedimentation. These lakes have high nutrient levels, low amounts of dissolved oxygen, and high sediment accumulation on the lake bottom. They often show sudden blooms of green or blue-green algae (or blue-green bacteria, cyanobacteria) and support only warm-water fish species. Mesotrophic lakes show characteristics in between those of unproductive oligotrophic waters and highly productive eutrophic waters. Mesotrophic lakes have moderate nutrient levels and phytoplankton growth and some sediment accumulation; they support primarily warm-water fish species. As a lake naturally ages over hundreds of years, it usually (but not always) gets progressively more eutrophic, as sediments fill in and eventually convert it to marsh or dryland. Nutrient enrichment from human sources can speed this process greatly. Limiting Damage The negative effects of eutrophication can be reduced by limiting the amount of nutrients—in most cases nitrogen and phosphorus—from entering a water system. Nutrients can enter water bodies through streams, rivers, groundwater flow, direct precipitation, and dumping and as particulate fallout from the atmosphere. While natural processes of eutrophication are virtually impossible to control, eutrophication from human activity can be reduced or reversed. Phosphorus enrichment into water systems occurs primarily as the result of wastewater drainage into a lake, river, or ocean. Phosphate is common in industrial and domestic detergents and cleaning agents. Mining along water systems is also a major source of phosphorus. When phosphorus enters a water system, it generally accumulates in the sediments. Storms and upwelling can stir up sediments, releasing phosphorus. Treatment of wastewater to remove phosphates and the reduction of phosphates in detergents have helped to reduce phosphorus enrichment of water systems. Nitrogen enrichment is harder to control; it is present in many forms, as ammonium, nitrates, nitrites, and nitrogen gas. The major sources of nitrogen eutrophication are synthetic fertilizers, animal wastes, and agricultural runoff. Some algae species can also fix atmospheric nitrogen directly, converting it to biologically usable forms of nitrogen. Since the atmosphere 225
Eutrophication contains about 78 percent nitrogen, this can be a major source of nitrogen enrichment in waters that already have significant algal populations. Efforts to control nitrogen and phosphorus levels have examined both point and nonpoint sources of nutrient loading. Point sources are concentrated, identifiable sites of nutrients that include municipal sewage-treatment plants, feed lots, food-processing plants, pulp mills, laundry detergents, and domestic cleaning agents. Nonpoint, or diffuse, sources of nutrients include surface runoff from rainwater, fertilizer from agricultural land and lawns, eroded soil, and roadways. Linda Hart and Mark S. Coyne See also: Acid deposition; Biomagnification; Erosion and erosion control; Food chains and webs; Invasive plants; Lakes and limnology; Nutrient cycles; Ocean pollution and oil spills; Pesticides; Phytoplankton; Pollution effects; Slash-and-burn agriculture; Waste management. Sources for Further Study Brönmark, Christer. The Biology of Lakes and Ponds. New York: Oxford University Press, 1998. Cole, Gerald A. Textbook of Limnology. 4th ed. Prospect Heights, Ill.: Waveland Press, 1994. Harper, David. Eutrophication of Freshwaters: Principles, Problems, and Restoration. London: Chapman & Hall, 1992. Hinga, Kenneth, Heeseon Jeon, and Noelle F. Lewis. Marine Eutrophication Review. Silver Springs, Md.: U.S. Department of Commerce, National Oceanic and Atmospheric Administration, Coastal Ocean Office, 1995. Horne, Alexander J., and Charles R. Goldman. Limnology. 2d ed. New York: McGraw-Hill, 1994. Schramm, Winfrid, and Pieter H. Nienhuis, eds. Marine Benthic Vegetation: Recent Changes and the Effects of Eutrophication. Berlin: Springer, 1996. Wetzel, Robert G. Limnological Analyses. 3d ed. New York: Springer, 2000.
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EVOLUTION: DEFINITION AND THEORIES Types of ecology: Evolutionary ecology; Paleoecology; Speciation Evolution is change in species through time. From a one-celled ancestor, many billions of species have evolved into a grand diversity of life-forms that populate earth and interact in ways that will affect the evolution of future life-forms. Inheritance and Natural Selection “Evolution” comes from the Latin word meaning “to unroll.” In a general sense, it refers to any change through time, but it is often restricted to biological change. For most of human history, the universe was thought to be unchanging. Then, in the eighteenth century, expeditions to new continents and the discovery of extinct fossil animals convinced many people that the biological world was not as unchanging as had been thought. There could be no proof for this hypothesis, however, until an explanation of how such change occurred could be found. In 1809, Jean-Baptiste Lamarck became the first to propose an explanation; his theory was based on the inheritance of acquired traits. According to this theory, giraffes, for example, obtained long necks because individual giraffes stretched their neck muscles more and more to reach ever higher leaves, and the longer necks were passed on to the offspring. This idea was quickly shown to be false by experiment. Traits acquired during an individual’s lifetime (such as larger muscles acquired through weightlifting) are not passed on to offspring. It was 1859 when Charles Darwin proposed what is now known to be the actual process by which evolution occurs: natural selection. This process can be divided into three steps: Individuals in a species vary in their traits; some individuals will have more offspring than others, depending on how advantageous their particular traits are; advantageous traits will increase in a species, and disadvantageous traits will be lost through time and as the environment changes. For example, climatic change may cause a forested environment to become a snowy tundra. Creatures with dark coats are best off in a forest because of the concealment of the dark, shadowy environment, but as the lighter, snowy environment becomes dominant, lighter individuals will have an advantage because they are more easily concealed. Over a long period, enough changes will accumulate in a group that an observer might say that a new species had been created. This process has often been called “survival of the fittest,” but the “fittest” or227
Evolution: definition and theories ganisms are not always the fastest, fiercest, or even most competitive. For example, animals that cooperate with other animals or are the most timid and conceal themselves readily may survive more often and produce more offspring. When the whole species changes at once, “nonbranching” evolution occurs. Many species, however, have wide ranges and occur in many different geographic areas, so often only some populations of a species are subjected to environmental changes. That is an important point because it explains how so many species can be created from one ancestral species. “Branching” evolution is especially common when one of the populations becomes cut off from the others by a barrier of some kind. For example, a new river may form. This river prevents interbreeding and allows each population to form its own pool of traits. In time, differences between the two environments will cause the two populations to become so distinct that they form two different species. Species have hitherto been described as groups that are visibly distinct enough to be distinguishable from one another; however, there is a much more objective definition of species, based on the criterion of interbreeding. To a biologist, members of a species can produce fertile offspring only when they breed with other members. Therefore, a new species has evolved not when it “looks” sufficiently different from its ancestors or neighboring populations but when it can no longer successfully interbreed with them. This definition of reproductive isolation is important because many closely related species look quite similar yet cannot successfully interbreed. Evolution by natural selection explains not only how species have changed but also why they are so well adapted to their surroundings: The best-adapted individuals have the most offspring. Further, it explains some crucial aspects of basic anatomy, such as why vestigial, or “remnant,” organs exist: They are in the process of being lost. For example, the nowuseless human appendix was once an important part of the human digestive tract. Also, it explains why many organisms have similar organs that are used for different purposes, such as five-fingered hands on humans and five-digit organs on bat wings. Such “homologous” organs have been modified from a common ancestor. This modification also explains why many organisms pass through similar embryonic stages; human embryos, for example, have tails and gills like a fish. Laws of Heredity After Darwin proposed natural selection as the process of evolution, it was readily accepted, and most scientists have accepted it ever since. The ex228
Evolution: definition and theories planation was incomplete, however, in one major area: Darwin could not explain how variation was produced or passed on. The laws of heredity were discovered by Gregor Mendel in 1866 while Darwin was wrestling with this problem. Mendel’s work lay unnoticed until the early twentieth century, when other scientists independently discovered the gene as the basic unit of heredity. Genes are now known to be molecular “blueprints” that are repeatedly copied within each cell. They contain instructions on how to build the organism and how to maintain it. Genes are passed on to the offspring when a sperm and an egg cell unite. The resulting fertilized egg consists of one cell that contains all the genes on strands, or chromosomes, in the cell nucleus. The chromosomes occur in pairs such that one member of each pair is from the father and one is from the mother. As growth occurs, certain genes in each cell will be biochemically “read” and will give instructions on what happens next. Genes are composed of the molecule deoxyribonucleic acid (DNA), which is shaped like a twisted ladder and is copied when the “ladder” splits in half at the middle of the “rungs.” Once the instructions are copied, they are carried outside the cell nucleus by messenger molecules, which proceed to build proteins (such as enzymes and muscle tissue) using the rungs as a blueprint. With this added knowledge of genes as the units of heredity, evolutionists could see that natural selection acting on individuals selects not only traits but also the genes that serve as blueprints for those traits. Therefore, as well as being a change in a species’ traits through time, evolution is also often defined as a change in the “gene pool” of a species. The gene pool is the total of all the genes contained in a species. Individual variation in a gene pool originally arises via mutations, errors made in the DNA copying process. Usually, mutation involves a change in the DNA sequence that causes a change in the genetic instructions. Most mutations have little effect, which is fortunate because those that are expressed generally kill or handicap the offspring. That occurs since any organism is a highly integrated, complex system, and any major alterations to it are therefore likely to disrupt it. Nevertheless, rare improvements do occur, and it is these that are passed on and become part of the breeding gene pool. Although mutations provide the ultimate source of variation, the sexual recombination of genes provides the more immediate source. Each organism has a unique combination of genes, and it is the fitness of this combination that determines how well those genes survive and are passed on. Although brothers and sisters have the same parents, they are not alike because genes are constantly shuffled and reshuffled in the production of each sperm and egg cell. 229
The Geologic Time Scale MYA Eon
Era
Period
Epoch
Quaternary Holocene (1.8 mya-today) (11,000 ya-today)
0.01
Pleistocene Ice Age in northwest Europe, Siberia, (1.8 mya-11,000 ya) and North America. Plants migrate in response. New speciations lead to modern plants. Modern humans evolve. Cenozoic (65 mya-today)
1.8 5 23 38
Tertiary (65-1.8 mya)
Pliocene (5-1.8 mya)
Cooling period leads to Ice Age.
Miocene (23-5 mya)
Erect-walking human ancestors
Oligocene (38-23 mya)
Primate ancestors of humans
Eocene (54-38 mya)
Intense mountain building occurs (Alps, Himalaya, rockies); modern mammals appear (rodents, hoofed animals); diverse conferous forests
Paleocene (65-54 mya)
Cretaceous-Tertiary even leads to dinosarus’ extinction c. 65 mya; seed ferns; bennettites and caytonias dief off; ginkgoes decline; decidous plants rise.
54
Mesozoic (245-208 mya)
Phanerozoic Eon (544 mya-today)
65
146
Cretaceous (146-65 mya)
Breakup of supercontinents into tosay’s form; birds appear. Cycads, other gymnosperms still widespread, but angiosperms dominate by 90 mya; animal-aided pollination begins to evolve.
Jurassic (208-146 mya)
Earliest mammals; ginkgoes thrive in moister areas; drier climates in North and South America, parts of Africa, central Asia; rise of modern gymnosperms, such as junipers, pine trees. Earliest angiosperm fossil (from China) dates from end of this period.
Triassic (245-208 mya)
Diminished land vegetation, with lack of variation reflecting global frost-free climate; gymnosperms dominate, bennettites and gnetophytes appear; dinosaurs develop.
Permian (286-245 mya)
Permian extinction even initiates drier, colder period; supercontinent Pangaea has formed; tree-sized lycophytes, club mosses, cordaites die off; horsetails, peltasperms, cycads, conifers dominate.
Carboniferous (360-286 mya)
Gymnosperms, ferns, calamites, lycopods thrive (first seed plants); reptiles appear. Plant life diverse, from small creeping forms to tall forest trees. coal beds form in swamp forests from the dominant seedless vascular plants.
208
325
Paleozoic (544-245 mya)
245
286
Pennsylvanian (325-286 mya) Mississippian (360-325 mya)
360
Developments Ice Age ends. Human activities begin to impact biosphere.
Evolution: definition and theories MYA Eon
Era
Epoch
Developments Club mosses, early ferns, lycophytes, progymnosperms; amphibians, diverse insects; horsetails, gymnosperms present by end of period.
Silurian (440-410 mya)
Early land plants: nonvascular bryophytes (mosses, hornworts), followed by seedless vascular plants in now-extinct phyla Rhyniophyta, Zosterophyllophyta, Trimerophytophyta.
505
Ordovician (505-440 mya)
Life colonizes land; earliest vertebrates appear in fossil record.
544
Cambrian (544-505 mya)
Tommotian (530-527 mya)
Cambrian diversification of life
900
Neoproterozoic (900-544 mya)
Vendian (650-544 mya)
Age of algae, earliest invertebrates
2500
3800 4500
Proterozoic (2,500-544 mya)
1600
Precambrian Time (4,500-544 mya)
440
Paleozoic (544-245 mya)
Devonian (410-360 mya)
Phanerozoic Eon (244 mya-today)
410
Period
Mesoproterozoic (1,600-900 mya)
Eukaryotic life established.
Paleoproterozoic (2,500-1,600 mya)
Transition from prokaryotic to eukaryotic life leads to multicellular organisms
Archaean (3,800-2,500 mya)
Microbial life (anaerobic and cyanobacteria) as early as 3.5 bya.
Hadean (4,500-3,800 mya)
Earth forms 4.5 bya.
Source: Data on time periods in this version of the geologic time scale are based on new findings in the last decade of the twentieth century as presented by the Geologic Society of America, which notably moves the transition between the Precambrian and Cambrian times from 570 mya to 544 mya. Notes: bya=billions of years ago; mya = millions of years ago; ya = years ago.
Rates and Patterns of Evolution A major area of debate is how fast evolution occurs. Some scientists believe that most evolution occurs rapidly. This view has been called “punctuated” evolution. Another group argues that evolution is more often gradual, as Darwin originally proposed. To some extent, this disagreement is a matter of different perspectives. A geneticist working with flies in a laboratory would see the evolution of a new species in ten thousand years as very slow. To a paleontologist, however, who often deals with fossil species lasting millions of years, ten thousand years is brief indeed. Nevertheless, there is more to the debate than perspective alone. Punctuationists argue not only that evolution is rapid but also that species have such tightly integrated gene pools that virtually no change at all occurs during most of a species’ existence. In contrast, gradualists view species as being much less integrated, so that change can be a continuous process. The fossil record at first glance 231
Evolution: definition and theories seems to support the punctuated view. The majority of species show very little change for long spans of time and then either disappear or rapidly give rise to another species. The fossil record is very incomplete, however, being full of gaps where no fossils were deposited. As a result, it is often impossible to tell whether the “rapid” change in species is real or only follows a gap in what was actually a gradual sequence. Also, fossils represent only part of the original organism—usually only the hard parts, such as shells, bones, or teeth. Therefore, any changes in soft anatomy, such as tissues or biochemistry, are lost, making it impossible to say with certainty that no change occurred. Whatever the outcome of the debate, all scientists agree that evolutionary rates vary. In addition to the rate of evolution, much has also been written about the patterns produced by evolution since life arose about 3.5 million years ago. Evolutionary trends are directional changes seen in a group. The most common trend, found in many groups, is an increase in size. Another trend, seen mainly in mammals, is an increase in brain size. Life as a whole has shown an increase in total diversity and complexity. These trends, however, are only statistical tendencies. They are not inevitable “laws,” as many have misinterpreted them in the past. Often, groups do not show them, and in those that do, the change is not constant and may reverse itself at times. Finally, trends are often interrupted by mass extinctions. At least five times in the past 600 million years, more than 50 percent of all the species on the earth have been wiped out by catastrophes of different kinds, from temperature changes to impacts of huge meteorites. Study of Fossils Fossils, the remains of former life, provide the only record of most evolution, because more than 99 percent of all species that have ever existed are now extinct. Paleontology is the study of fossils. Such study begins with identification of the remains—usually hard parts, such as bones—and ends with measurement of fossil size, shape, and abundance. The extreme incompleteness of the fossil record is a major obstacle to this method, since only some parts are preserved, and these are from strictly limited periods of the evolutionary past. Nevertheless, many evolutionary lineages can be traced through time. Indeed, refined measurements of rate and direction of anatomical change are often possible when used in conjunction with dating techniques. The study of living organisms permits observation of the complete organism. Comparative anatomy reveals similarities among related species and shows how evolution has modified them since they separated from their common ancestor. For example, humans and chimpanzees are ex232
Evolution: definition and theories tremely similar in their organ and muscle anatomy. This method is not limited to comparison of adults but includes earlier stages of development as well. Comparative embryology often shows anatomical similarities, such as those between humans and other vertebrates. For example, the human embryo goes through a stage with gills and a tail, resembling stages of an amphibian embryo. Comparative biochemistry is also very useful, revealing similarities in proteins and many other molecules. Such comparisons are based on differences in molecular sequences, such as amino acids. Molecular “clocks” are sometimes calculated in this manner. More distantly related species are thought to have more differences. The accuracy of such clocks, however, is hotly debated. A major technique is DNA sequencing, whereby the exact genetic information is read directly from the gene. This method will greatly add to knowledge of evolutionary relationships, although it is expensive and time-consuming. Biogeography, or the distribution of organisms in nature, is a method that Darwin used and that is still important today. This technique often reveals populations (races) within a species’ overall range that differ from one another because they inhabit slightly different geographic areas. These populations give the scientist a “snapshot” of evolution in progress. Given more time, many of these races would eventually become different species. Artificial breeding is a method of directly manipulating evolution. The most widely used experimental organism for this purpose is the fruit fly, which is used in part because of its exceptionally large chromosomes; they make the genes easy to identify. A common experiment is to subject the flies to radiation or chemicals that cause mutations and then to analyze the effects. The gene pool is then subjected to extreme artificial selection as the experimenter allows only certain individuals to breed. For example, only those with a gene for a certain kind of wing may reproduce. Although such experiments have often altered the organisms’ gene pools and created new varieties within the species, no truly new species has ever been created in the laboratory. Apparently, more time is needed to produce a new species. Outside the laboratory, artificial breeding has been done for thousands of years. Food plants and domesticated animals have had much of their evolution controlled by humans. Analysis of the effect of this breeding on the organisms’ gene pools is the most complete and direct method of studying evolution. Significance The study of fossils has been a major tool in understanding Earth’s history. This understanding has allowed more efficient exploitation of the earth’s 233
Evolution: definition and theories resources. For example, petroleum and coal provide the major energy resources today and were both formed by organisms of the past. Petroleum comes from the biochemicals of marine organisms, and coal comes from fossilized plants. Most paleontologists are employed in the costly search for these “fossil fuels,” and knowing the evolutionary history of these groups helps to determine the most productive places to search. Fossils also form nonenergy resources. Limestone is used in many processes, from making cement to making steel. Most limestone is composed of the fossilized remains of seashells and other marine skeletons. Phosphate minerals, essential for fertilizers in almost all forms of agriculture, come from marine fossil deposits as well. Darwin’s theory of natural selection caused a violent reaction throughout much of the world when it was applied in social contexts (to which Darwin himself disagreed) as “social Darwinism.” The notion that humans evolved from lower life-forms such as the ape was truly revolutionary. Instead of creatures of a divine plan, humans were now seen as products of natural, sometimes “random,” processes. The impact of this realization on ethics, the arts, and society in general is still being felt. Evolution, however, does not necessarily conflict with religion, as is often thought. Science seeks to find out only how things happen, not the ultimate reasons why they happen. Therefore, most major religions have reconciled their tenets with the fact of evolution by viewing natural selection as simply a mechanism employed by God to meet his ends. Michael L. McKinney See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Development and ecological strategies; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Genetically modified foods; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Paleoecology; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Species loss. Sources for Further Study Dawkins, Richard. The Blind Watchmaker: Why the Evidence of Evolution Reveals a Universe Without Design. New York: W. W. Norton, 1988. Futuyma, Douglas J. Evolutionary Biology. Sunderland, Mass.: Sinauer Associates, 1986. McNamara, K. J. Shapes of Time: The Evolution of Growth and Development. Baltimore: Johns Hopkins University Press, 1997. 234
Evolution: definition and theories Schopf, J. William, ed. Major Events in the History of Life. Boston: Jones and Bartlett, 1992. Stanley, Steven M. The New Evolutionary Timetable: Fossils, Genes, and the Origin of Species. New York: Basic Books, 1981. Stebbins, G. Ledyard. Darwin to DNA, Molecules to Humanity. New York: W. H. Freeman, 1982.
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EVOLUTION: HISTORY Types of ecology: Evolutionary ecology; History of ecology Evolution is the theory that biological species undergo sufficient change with time to give rise to new species. The development of the theory of evolution has contributed much to two later scientific disciplines, genetics and ecology, by providing explanations for the adaptations and interrelationships of species from early times to the present.
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he concept of evolution has ancient roots. Anaximander suggested in the sixth century b.c.e. that life had originated in the seas and that humans had evolved from fish. Empedocles (c. 450 b.c.e.) and Lucretius (c. 96-55 b.c.e.), in a sense, grasped the concepts of adaptation and natural selection. They taught that bodies had originally formed from the random combination of parts, but that only harmoniously functioning combinations could survive and reproduce. Lucretius even said that the mythical centaur, half horse and half human, could never have existed because the human teeth and stomach would be incapable of chewing and digesting the kind of grassy food needed to nourish the horse’s body. Early Biological Theory For two thousand years, however, evolution was considered an impossibility. The theory of forms (also called his theory of ideas) proposed by Plato (c. 428-348 b.c.e.) gave rise to the notion that each species had an unchanging “essence” incapable of evolutionary change. As a result, most scientists from Aristotle (384-322 b.c.e.) to Carolus Linnaeus (1707-1778) insisted upon the immutability of species. Many of these scientists tried to arrange all species in a single linear sequence known as the scale of being (also called the great chain of being or scala naturae), a concept supported well into the nineteenth century by many philosophers and theologians. The sequence in this scale of being was usually interpreted as a static “ladder of perfection” in God’s creation, arranged from higher to lower forms. The scale had to be continuous, for any gap would detract from the perfection of God’s creation. Much exploration was devoted to searching for missing links in the chain, but it was generally agreed that the entire system was static and incapable of evolutionary change. Pierre-Louis Moreau de Maupertuis and JeanBaptiste Lamarck (1744-1829) were among the scientists who tried to reinterpret the scale of being as an evolutionary sequence, but this single236
Evolution: history sequence idea was later replaced by the concept of branching evolution proposed by Charles Darwin (1809-1882). Georges Cuvier (1769-1832) finally showed that the major groups of animals had such strikingly different anatomical structures that no possible scale of being could connect them all; the idea of a scale of being lost most of its scientific support as a result. The theory that new biological species could arise from changes in existing species was not readily accepted at first. Linnaeus and other classical biologists emphasized the immutability of species under the PlatonicAristotelian concept of essentialism. Those who believed in the concept of evolution realized that no such idea could gain acceptance until a suitable mechanism of evolution could be found. Many possible mechanisms were therefore proposed. Étienne Geoffroy Saint-Hilaire (1805-1861) proposed that the environment directly induced physiological changes, which he thought would be inherited, a theory now known as Geoffroyism. Lamarck proposed that there was an overall linear ascent of the scale of being but that organisms could also adapt to local environments by voluntary exercise, which would strengthen the organs used; unused organs would deteriorate. He thought that the characteristics acquired by use and disuse would be passed on to later generations, but the inheritance of acquired characteristics was later disproved. Central to both these explanations was the concept of adaptation, or the possession by organisms of characteristics that suit them to their environments or to their ways of life. In eighteenth century England, the Reverend William Paley (1743-1805) and his numerous scientific supporters believed that such adaptations could be explained only by the action of an omnipotent, benevolent God. In criticizing Lamarck, the supporters of Paley pointed out that birds migrated toward warmer climates before winter set in and that the heart of the human fetus had features that anticipated the changes of function that take place at birth. No amount of use and disuse could explain these cases of anticipation, they claimed; only an omniscient God who could foretell future events could have designed things with their future utility in mind. Darwin’s Theory The nineteenth century witnessed a number of books asserting that living species had evolved from earlier ones. Before 1859, these works were often more geological than biological in content. Most successful among them was the anonymously published Vestiges of the Natural History of Creation (1844), written by Robert Chambers (1802-1871). Books of this genre sold well but contained many flaws. They proposed no mechanism to account for evolutionary change. They supported the outmoded concept of a scale 237
Evolution: history of being, often as a single sequence of evolutionary “progress.” In geology, they supported the outmoded theory of catastrophism, an idea that the history of the earth had been characterized by great cataclysmic upheavals. From 1830 on, however, that theory was being replaced by the modern theory of uniformitarianism, championed by Charles Lyell (1797-1875). Darwin read these books and knew their faults, especially their lack of a mechanism that was compatible with Lyell’s geology. In his own work, Darwin carefully tried to avoid the shortcomings of these theories. Eventually, he brought about the greatest revolution in biological thought by proposing both a theory of branching evolution and a mechanism of natural selection to explain how it occurred. Much of Darwin’s evidence was gathered during his voyage around the world aboard HMS Beagle between 1831 and 1836. Darwin’s stop in the Galápagos Islands and his study of tortoises and finchlike birds on these islands is usually credited with convincing him that evolution was a branching process and that adaptation to local environments was an essential part of the evolutionary process. Adaptation, he later concluded, came about through natural selection, a process that led to the deaths of maladapted variations and allowed only the well-adapted ones to survive and pass on their hereditary traits. After returning to England from his voyage, Darwin raised pigeons, consulted with various animal breeders about changes in domestic breeds, and investigated other phenomena that later enabled him to demonstrate natural selection and its power to produce evolutionary change. Darwin delayed the publication of his book for seventeen years after he wrote his first manuscript version. He might have waited even longer, except that his hand was forced. From the East Indies, another British scientist, Alfred Russel Wallace (1823-1913), had written a description of an identical theory and submitted it to Darwin for his comments. Darwin showed Wallace’s letter to Lyell, who urged that both Darwin’s and Wallace’s contributions be published, along with documented evidence showing that both had arrived at the same ideas independently. Darwin’s great book, On the Origin of Species by Means of Natural Selection, was published in 1859, and it quickly won most of the scientific community’s support of the concept of branching evolution. In his later years, Darwin also published The Descent of Man and Selection in Relation to Sex (1871), in which he outlined his theory of sexual selection. According to this theory, the agent that determines the composition of the next generation may often be the opposite sex. An organism may be well adapted to live, but unless it can mate and leave offspring, it will not contribute to the next or to future generations. 238
Evolution: history After Darwin In the early 1900’s, the rise of Mendelian genetics (named for botanist Gregor Mendel, 1822-1884) initially resulted in challenges to Darwinism. Hugo de Vries (1848-1935) proposed that evolution occurred by random mutations, which were not necessarily adaptive. This idea was subsequently rejected, and Mendelian genetics was reconciled with Darwinism during the period from 1930 to 1942. According to this modern synthetic theory of evolution, mutations initially occur at random, but natural selection eliminates most of them and alters the proportions among those that survive. Over many generations, the accumulation of heritable traits produces the kind of adaptive change that Darwin and others had described. The process of branching evolution through speciation is also an important part of the modern synthesis. The branching of the evolutionary tree has resulted in the proliferation of species from the common ancestor of each group, a process called adaptive radiation. Ultimately, all species are believed to have descended from a single common ancestor. Because of the branching nature of the evolutionary process, no one evolutionary sequence can be singled out as representing any overall trend; rather, there have been different trends in different groups. Evolution is also an opportunistic process, in the sense that it follows the path of least resistance in each case. Instead of moving in straight lines toward a predetermined goal, evolving lineages often trace meandering or circuitous paths in which each change represents a momentary increase in adaptation. Species that cannot adapt to changing conditions die out and become extinct. Evolutionary biology is itself the context into which all the other biological sciences fit. Other biologists, including physiologists and molecular biologists, study how certain processes work, but it is evolutionists who study the reasons that these processes came to work in one way and not another. Organisms and their cells are built one way and not another because their structures have evolved in a particular direction and can only be explained as the result of an evolutionary process. Not only does each biological system need to function properly, but it also must have been able to achieve its present method of functioning as the result of a long, historical, evolutionary process in which a previous method of functioning changed into the present one. If there were two or more ways of accomplishing the same result, a particular species used one of them because its ancestors were more easily capable of evolving this one method rather than another. Eli C. Minkoff
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Evolution: history See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Development and ecological strategies; Ecology: history; Ecosystems: definition and history; Evolution: definition and theories; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Genetically modified foods; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Paleoecology; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Species loss. Sources for Further Study Bowler, Peter J. Evolution: The History of an Idea. Rev. ed. Berkeley: University of California Press, 1989. _______. Life’s Splendid Drama: Evolutionary Biology and the Reconstruction of Life’s Ancestry, 1860-1940. Chicago: University of Chicago Press, 1996. Brandon, Robert N. Concepts and Methods in Evolutionary Biology. New York: Cambridge University Press, 1996. Grant, Verne. The Evolutionary Process: A Critical Study of Evolutionary Theory. 2d ed. New York: Columbia University Press, 1991. Minkoff, Eli C. Evolutionary Biology. Reading, Mass.: Addison-Wesley, 1983. Zimmer, Carl. Evolution: The Triumph of an Idea. New York: HarperCollins, 2001.
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EVOLUTION OF PLANTS AND CLIMATES Types of ecology: Evolutionary ecology; Paleoecology; Speciation As a result of prehistoric events such as the Permian-Triassic extinction event and the Cretaceous-Tertiary mass extinction event, many plant families and some ancestors of extant plant were extinct before the beginning of recorded history.
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he general trend of earth’s plant diversification involves four major plant groups that rose to dominance from about the Middle Silurian period to present time. The first major group providing land vegetation comprised the seedless vascular plants, represented by the phyla Rhyniophyta, Zosterophyllophyta, and Trimerophytophyta. The second major group appearing in the late Devonian period was made up of the ferns (Pterophyta). The third group, the seed plants (sometimes called the Coal Age plants), appeared at least 380 million years ago (mya). This third group includes the gymnosperms (Gymnospermophyta), which dominated land flora for most of the Mesozoic era until 100 mya. The last group, the flowering angiosperms (Anthophyta), appeared in the fossil record 130 mya. The fossil record also shows that this group of plants was abundant in most parts of the world within 30 million to 40 million years. Thus, the angiosperms have dominated land vegetation for close to 100 million years. The Paleozoic Era The Proterozoic and Archean eons have restricted fossil records and predate the appearance of land plants. Seedless, vascular land plants appeared in the middle of the Silurian period (437-407 mya) and are represented by the rhyniophytes or rhyniophytoids and possibly the Lycophyta (lycophytes or club mosses). From the primitive rhyniophytes and lycophytes, land vegetation rapidly diversified during the Devonian period (407-360 mya). Pre-fern ancestors and maybe true ferns (Pterophyta) were developed by the mid-Devonian. By the Late Devonian the horsetails (Sphenophyta) and gymnosperms (Gymnospermophyta) were present. By the end of the period, all major divisions of vascular plants had appeared except the angiosperms. Development of vascular plant structures throughout the Devonian allowed for greater geographical diversity of plants. One such structure was flattened, planated leaves, which increased photosynthetic efficiency. An241
Evolution of plants and climates other was the development of secondary wood, allowing plants to increase significantly in structure and size, thus resulting in trees and probably forests. A gradual process was the reproductive development of the seed; the earliest structures are found in Upper Devonian deposits. Ancestors of the conifers and cycads appeared in the Carboniferous period (360-287 mya), but their documentation is poor in the fossil record. During the early Carboniferous in the high and middle latitudes, vegetation shows a dominance of club mosses and progymnosperms (Progymnospermophyta). In the lower latitudes of North America and Europe, a greater diversity of club mosses and progymnosperms are found, along with a greater diversity of vegetation. Seed ferns (lagenostomaleans, calamopityaleans) are present, along with true ferns and horsetails (Archaeocalamites). Late Carboniferous vegetation in the high latitudes was greatly affected by the start of the Permo-Carboniferous Ice Age. In the northern middle latitudes, the fossil record reveals a dominance of horsetails and primitive seed ferns (pteridosperms) but few other plants. In northern low latitudes, landmasses of North America, Europe, and China were covered by shallow seas or swamps and, because they were close to the equator, experienced tropical to subtropical climatic conditions. The first tropical rain forests appeared there, known as the Coal Measure Forests or the Age of Coal. Vast amounts of peat were laid down as a result of favorable conditions of year-round growth and the giant club mosses’ adaptation to the wetland tropical environments. In drier areas surrounding the lowlands, forests of horsetails (calamites, sphenophylls), seed ferns (medullosans, callistophytes, lagenostomaleans), cordaites, and diverse ferns (including marattialean tree ferns) existed in great abundance. The Permian period (287-250 mya) marks a major transition of the conifers, cycads, glossopterids, gigantopterids, and the peltasperms from a poor fossil record in the Carboniferous to significantly abundant land vegetation. The two most prevalent plant assemblages of the Permian were the horsetails, peltasperms, cycadophytes, and conifers. The second most prevalent were the gigantopterids, peltasperms, and conifers. These two plant assemblages are considered the typical paleo-equatorial lowland vegetation of the Permian. Other plants, such as the tree ferns and giant club mosses, were present in the Permian but not abundant. As a result of the Permian-Triassic extinction event, tropical swamp forests disappeared, with the extinction of the club mosses; the cordaites and glossopterids disappeared from higher latitudes; and 96 percent of all plant and animal species became extinct. 242
Evolution of plants and climates The Mesozoic Era At the beginning of the Triassic period (248-208 mya), a meager fossil record reveals diminished land vegetation (that is, no coal formed). By the middle to late Triassic, the modern family of ferns, conifers, and a now-extinct group of plants, the bennettites (cycadeoids), inhabited most land surfaces. After the mass extinction, the bennettites moved into vacant lowland niches. They may be significant because of the similarity of their reproductive organs to the reproductive organs of the angiosperms. Late Triassic flora in the equatorial latitudes are represented by a wide range of ferns, horsetails, pteriosperms, cycads, bennettites, leptostrobaleans, ginkgos, and conifers. The plant assemblages in the middle latitudes are similar but not as species-rich. This lack of plant variation in low and middle latitudes reflects a global frost-free climate. In the Jurassic period (208-144 mya), land vegetation similar to modern vegetation began to appear, and the ferns of this age can be assigned to modern families: Dipteridaceae, Matoniaceae, Gleicheniaceae, and Cyatheaceae. Conifers of this age can also be assigned to modern families: Podocarpaceae, Araucariaceae (Norfolk pines), Pinaceae (pines), and Taxaceae (yews). These conifers created substantial coal deposits in the Mesozoic. During the Early to Middle Jurassic, diverse vegetation grew in the equatorial latitudes of western North America, Europe, Central Asia, and the Far East and comprised the horsetails, pteridosperms, cycads, bennettites, leptostrobaleans, ginkgos, ferns, and conifers. Warm, moist conditions also existed in the northern middle latitudes (Siberia and northwest Canada), supporting Ginkgoalean forests and leptostrobaleans. Desert conditions existed in central and eastern North America and North Africa, and the presence of bennettites, cycads, peltasperms, and cheirolepidiacean conifers there are plant indicators of drier conditions. The southern latitudes had vegetation similar to that of the equatorial latitudes, but owing to drier conditions, cheirolepidiacean conifers were abundant, ginkgos scarce. This southern vegetation spread into very high latitudes, including Antarctica, because of the lack of polar ice. In the Cretaceous period (144-66.4 mya), arid, subdesert conditions existed in South America, Central and North Africa, and central Asia. Thus, the land vegetation was dominated by cheirolepidiacean conifers and matoniacean ferns. The northern middle latitudes of Europe and North America had a more diverse vegetation comprising bennettites, cycads, ferns, peltasperms, and cheirolepidiacean conifers with the southern middle latitudes dominated by bennettites and cheirolepidiaceans. A major change in land vegetation took place in the late Cretaceous with the appearance and proliferation of flowering seed plants, the angio243
Evolution of plants and climates sperms. The presence of the angiosperms marked the end of the typical gymnosperm-dominated Mesozoic flora and a definite decline in the leptostrobaleans, bennettites, ginkgos, and cycads. During the late Cretaceous in South America, central Africa, and India, arid conditions prevailed, resulting in tropical vegetation dominated by palms. The southern middle latitudes were also affected by desert conditions, and the plants that fringed these desert areas were horsetails, ferns, conifers (araucarias, podocarps), and angiosperms, specifically Nothofagus (southern beech). The high-latitude areas were devoid of polar ice; owing to the warmer conditions, angiosperms were able to thrive. The most diverse flora was found in North America, with the presence of evergreens, angiosperms, and conifers, especially the redwood, Sequoia. The Cretaceous-Tertiary (K/T) mass extinction event occurred at about 66.4 mya. This event has been hypothesized to be a meteoritic impact; whatever the cause, at this time an event took place that suddenly induced global climatic change and initiated the extinction of many species, notably the dinosaurs. The K/T had a greater effect on plants with many families than it did on plants with very few families. Those that did become extinct, such as the bennettites and caytonias, had been in decline. The greatest shock to land vegetation occurred in the middle latitudes of North America. The pollen and spore record just above the K/T boundary in the fossil record shows a dominance of ferns and evergreens. Subsequent plant colonization in North America shows a dominance of deciduous plants. The Cenozoic Era Increased rainfall at the beginning of the Paleogene-Neogene period (66.41.8 mya) supported the widespread development of rain forests in southerly areas. Rain forests are documented by larger leaf size and drip tips at leaf edge, typical characteristics of modern rain-forest floras. Notable in this period was the polar Arcto-Tertiary forest flora found in northwest Canada at paleolatitudes of 75-80 degrees north. Mild, moist summers alternated with continuous winter darkness, with temperatures ranging from 0 to 25 degrees Celsius. These climatic conditions supported deciduous vegetation that included Platanaceae (sycamore), Judlandaceae (walnut), Betulaceae (birch), Menispermaceae, Cercidophyllaceae, Ulmaceae (elm), Fagaceae (beech), Magnoliaceae; and gymnosperms such as Taxodiaceae (redwood), Cypressaceae (cypress), Pinaceae (pine), and Ginkgoaceae (gingko). This flora spread across North America to Europe via a land bridge between the continents. About eleven million years ago, during the Miocene epoch, a marked change in vegetation occurred, with the appearance of grasses and their 244
Evolution of plants and climates subsequent spread to grassy plains and prairies. The appearance of this widespread flora supported the development and evolution of herbivorous mammals. The Quaternary period (1.8 mya to present) began with continental glaciation in northwest Europe, Siberia, and North America. This glaciation affected land vegetation, with plants migrating north and south as a response to glacial and interglacial fluctuations. Pollen grains and spores document the presence of Aceraceae (maple), hazel, and Fraxinus (ash) during interglacial periods. Final migrations of plant species at the close of the last ice age (about eleven thousand years ago), formed the modern geographical distribution of land plants. Some areas, such as mountain slopes or islands, have unusual distribution of plant species as a result of their isolation from the global plant migrations. Mariana Louise Rhoades See also: Adaptations and their mechanisms; Adaptive radiation; Biomes: determinants; Biomes: types; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Evolution: definition and theories; Evolution: history; Extinctions and evolutionary explosions; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Paleoecology; Punctuated equilibrium vs. gradualism; Speciation. Sources for Further Study Cleal, Christopher J., and Barry A. Thomas. Plant Fossils: The History of Land Vegetation. Suffolk, England: Boydell Press, 1999. Stewart, Wilson N., and Gar A. Rothwell. Paleobotany and the Evolution of Plants. New York: Cambridge University Press, 1993.
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EXTINCTIONS AND EVOLUTIONARY EXPLOSIONS Types of ecology: Evolutionary ecology; Paleoecology; Population ecology; Speciation The history of life has been punctuated by episodes of great change, some marked by the loss of large numbers of organisms, others by explosive development. Explanations proposed for these fluctuations have a bearing on current extinction levels and the extent to which they can be controlled.
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xtinction of species is a continuous process, and evidence of its occurrence abounds in the fossil record. It has been estimated that marine species persist for about four million years, which translates into an overall loss of about two or three species each year. This is the “background” extinction rate, and it is balanced by speciation events that result in the development of new species. Mass extinctions are events during which the rate of extinction rises dramatically above this background rate, and a number of these have been recognized in the Phanerozoic era. In each of these events, at least 40 percent of the genera of shallow marine organisms were eliminated. Using statistical methods, it has been estimated that at least 65 percent of species became extinct at each of these events, with 77 percent being eliminated at the event at the end of the Cretaceous period and 95 percent at the event at the end of the Permian period. These mass extinctions were balanced by periods of explosive development that often followed, as organisms moved into vacant adaptive zones during periods of adaptive radiation. The most important of these was at the base of the Cambrian period, 544 million years ago, when all the major groups in existence originated, but other radiations occurred in the Early Triassic period and at the start of the Tertiary period. Causes of Mass Extinctions Attempts to explain the causes of mass extinctions have centered on terrestrial phenomena such as sea-level changes, climatic changes, or volcanic activity. The sea level has shown regular fluctuations on a global level during the Phanerozoic era, and these appear to be related to the melting or formation of polar ice caps or to major tectonic events such as continental splits or the collision and uplift or subsidence of ocean ridges. Extinction events appear to be correlated mostly with periods of marine regression. 246
Extinctions and evolutionary explosions During such a regression, the withdrawal of the ocean leaves a much smaller habitat for shallow marine organisms. This leads to increased crowding and competition and ultimately to an increased extinction rate. Reduction of large terrestrial vertebrates during these regressions, as happened during the events at the end of the Permian and Cretaceous periods, may be related to increased seasonality caused by the loss of the ameliorating influence of the shallow epicontinental seas. It has also been shown that some extinctions are related to transgressive events (the spread of the sea over land areas), possibly resulting from the spread of anoxic (oxygen-poor) waters across epicontinental areas. Climatic changes seem to be correlated with eustatic events (worldwide changes in sea level), and the evidence implicating temperature as the main cause of extinctions seems weak. For example, the most important extinction event at the end of the Permian period occurred at a time of climatic amelioration marked by the disappearance of the Gondwanaland ice sheet. Volcanic activity has been presented as a possible cause of the extinctions that occurred at the end of the Cretaceous period. The Deccan Traps of northern India were erupting at that time and would have produced large quantities of volatile emissions that could have resulted in global cooling, ozone-layer depletion, and changes in ocean chemistry. However, no evidence exists as yet for the involvement of volcanic activity in other extinction events. Although various extraterrestrial causes for mass extinction events have been suggested in the past, these ideas have gained greater credence since the publication in the early 1980’s of work by Luis and Walter Alvarez, who ascribe the end-Cretaceous extinction event to the effects of the impact of a large bolide, or extraterrestrial object, perhaps ten kilometers in diameter. The impact of such a large object would have resulted in some months of darkness because of the global dust clouds generated, and this would have halted photosynthesis and resulted in the collapse of both terrestrial and marine food chains. Although cold would initially have accompanied the darkness, greenhouse effects and global warming would follow as atmospheric gases and water vapor trapped infrared energy radiating from the earth. Physical evidence for an impact rests on the presence in the period boundary layers of high concentrations of iridium and other elements generally rare at the earth’s surface but abundant in asteroids. In addition, these layers often contain shocked quartz grains, otherwise found only in impact craters and at nuclear test sites, and microtectites, glassy droplets formed by impact. Although the evidence for extraterrestrial impacts having caused the other major extinction events is slight, this causal factor has been linked with the apparently regular 26-million-year 247
Extinctions and evolutionary explosions periodicity exhibited by extinctions. Scientists suggest that the regular passage of an unidentified planetary body by the Oort Cloud of comets and the subsequent perturbation could result in increased asteroid impacts and extinction events on earth. Historical Mass Extinctions The first mass extinction event that can be recognized in the fossil record occurred in the Middle Vendian period, about 650 million years ago, when microorganisms underwent a severe decline. This event has been linked to climatic cooling related to glaciation. The extinction in the Late Ordovician period was a major event in which 22 percent of marine families became extinct. As there were two main pulses of extinction and no iridium anomaly was found, an extraterrestrial cause seems unlikely. However, sea-level and temperature changes have been cited as likely causes. In addition, biologically toxic bottom waters might have been brought to the surface during periods of climatic change. The event at the end of the Devonian period had a devastating effect on brachiopods, which lost about 86 percent of genera, and on reef-building organisms such as corals. Shallow-water faunas were most severely affected; only 4 percent of species survived, although 40 percent of deeper-water species did, and cool-water faunas also survived better. This event has been linked to a significant drop in global temperatures of unknown cause. The mass extinction event at the end of the Permian period was the most severe of the Phanerozoic era and resulted in the extinction of up to 95 percent of all marine invertebrate species. On land, amphibians and mammal-like reptiles were both badly affected, and plant diversity fell by 50 percent. No iridium anomaly was found, and the most likely explanation is climatic instability caused by continental amalgamation and the simultaneous occurrence of marine regressions. These occurrences would have disrupted food webs on a major scale. The event that occurred at the end of the Triassic period was much less severe but still involved extensive reductions in marine invertebrates and reptiles. On land, a major faunal turnover took place. Primitive amphibians, early reptile groups, and mammal-like reptiles died out and were replaced by advanced reptiles and mammals. No evidence of an impact event has been found, and the extinctions are generally correlated with widespread marine regressions. The extinction that took place at the end of the Cretaceous period has become the most hotly debated, in large part because of the bolide impact hypothesis. Although the broad pattern of extinction among marine organisms is known, the detailed picture only encompasses microorganisms 248
Extinctions and evolutionary explosions such as planktonic foraminifera and calcareous nannoplankton. Study of the ranges of these microorganisms shows that the extinctions occurred over an extended period, starting well before and finishing well after the boundary. Although much has been made of the extinction of ammonites at the end of the Cretaceous period, there are too few ammonite-bearing sections to show if it was gradual or abrupt. On land, evidence of an increase in the population of ferns just above the boundary suggests the presence of wildfires, as ferns are usually the first plants to recolonize an area devastated by fire. However, in many sections, a return of the Cretaceous vegetation is seen above the fern increase, indicating little extinction. Post-Extinction Recoveries Among the vertebrates, a picture of gradual change is seen for mammals, with drastic reductions occurring only in the marsupials. The boundary also does not seem to have been a barrier for turtles, crocodiles, lizards, and snakes, all of which came through virtually unscathed. The dinosaurs did become extinct, and much argument has centered on whether this was abrupt or occurred after a slow decline. In this context, it must be noted that there is only one area where a dinosaur-bearing sedimentary transition across the boundary can be seen, and that is in Alberta, Canada, and the northwestern United States. Records of dinosaurs in this area during the upper part of the Cretaceous period show a gradual decline in diversity, with a drop from thirty to seven genera over the last eight million years. Although explanations of the extinction of dinosaurs have ranged from mammals eating their eggs to terminal allergies caused by the rise of flowering plants to the current ideas about bolide impacts, the answer may be climate related. A major regression of the oceans occurred at this point, resulting in a drop in mean annual temperatures and an increase in seasonality. The bolide impact may have served as the death blow to taxa (animals in classification groups) that were already declining. The main period of evolutionary expansion in the Phanerozoic era is at the base of the Cambrian period, 544 million years ago. Termed the “Cambrian explosion,” it marks the development of all the modern phyla of organisms, and as many as one hundred phyla may have existed during the Cambrian period. This period seems to have lasted only about 5 million years, and the subsequent history of animal life consists mainly of variations on the anatomical themes developed during this short period of intense creativity. This period is represented in the fossil record by the remarkably well-preserved Burgess Shale fauna of British Columbia, which has been extensively described, and faunas of similar age from China and Greenland. Why the Cambrian explosion could establish all major anatom249
Extinctions and evolutionary explosions ical designs so quickly is not clear. Some scientists believe that the lack of complex organisms before the explosion had left large areas of ecological space open, and when experimentation took place, particularly with the advent of hard skeletons, any novelty could find a niche. Also, the earliest multicellular organisms may have maintained a genetic flexibility that became greatly reduced as organisms became locked into stable and successful designs. Why some of the innovations were successful in the long term and others were not is unknown, as no recognized traits unite the successful taxa. It has even been suggested that success may be due to no more than the luck of the draw. In contrast, the recoveries after the major extinctions at the end of the Permian and Cretaceous periods did not result in the development of new phyla. The earliest Triassic ecosystems were more vacant than at any time since the Cambrian period, yet no new phyla or classes appear in the Triassic period. This suggests that despite the overwhelming nature of the extinctions, the pattern was insufficient to permit major morphological innovations, in part probably because no adaptive zone was entirely vacant. Hence, despite the fact that the mass extinction at the end of the Permian period triggered an explosion in marine diversity described as the Mesozoic marine revolution, persisting species may have limited the success of broad evolutionary jumps. Reading the Fossil Records All understanding of extinction events or of evolutionary explosions depends on the fossil record. The study of the diversity of organisms through time—the number of different types of organisms that occur at a particular time and place—is therefore very important. The basic data consists of compilations of extinctions of taxa plotted against similar compilations of origination of taxa. Periods when either extinction or origination were unusually high show as peaks or troughs on a graph. Unfortunately, biases in the preservation, collection, and study of fossils have conspired to obscure patterns of change in diversity. The geological history of patterns of diversity are obscured by a variety of filters, many of which are sampling biases that cause the observed fossil record to differ from the actual history of the biosphere. The most severe bias is the loss of sedimentary rock volume and area as the age of the record increases because the volume and area correlate strongly with the diversity of organisms described from a stratigraphic interval. The quality of the record also tends to fall with increasing age because the rocks are exposed to changes that may destroy the fossils they contain. The differences in levels of representation among the paleoenvironments in the 250
Extinctions and evolutionary explosions stratigraphic record also influences the composition of the fossil record; for example, shallow-marine faunas are much better represented than are terrestrial faunas. Diversity patterns are studied at a variety of levels, from the species upward, that vary in their quality and inclusiveness. A basic problem is that many of the processes that are of interest occur at the species level or even below it, but the biases of the fossil record mean that data is best at higher levels. Diversity of shallow-marine organisms for the Phanerozoic era cannot be read directly at the species level because the record is too fragmentary. The record at the family level is much more complete because the preservation of one species in a family allows the family to be recorded. For this reason, paleodiversity studies are often conducted at the family level. However, higher taxon diversity is a poor predictor of species diversity. For example, an analysis of the mass extinction at the end of the Permian period indicates that the 17 percent reduction in marine orders and 52 percent reduction in marine families probably represents a 95 percent reduction in the number of species. Another problem with the study of fossils is that soft-bodied and poorly skeletonized groups may leave little or no record. It has generally been assumed that the ratio of heavily skeletonized to non-skeletonized species has remained approximately constant through the Phanerozoic era; however, there is no data to support this and some evidence that skeletons have become more robust through time in response to newly evolving predators. The net result of these biases is severe. Only 10 percent of the skeletonized marine species of the geologic past and far fewer of the soft-bodied species are known. Despite these problems, it has been possible to show that diversity of organisms has varied in a number of ways during the Phanerozoic era. Tabulations of classes, orders, and families have been used to show that there were significant periods of increased extinction or increased evolutionary rates. One of the most important uses of this data has been the tabulation at the family level that appears to show a regular periodicity of about 26 million years for extinction events and that has been used to support ideas about periodic extraterrestrial events. However, although fluctuations occurred, it has also been possible to show that the number of marine orders increased rapidly to the Late Ordovician period and has remained approximately constant since then. The Ebb and Flow of Life on Earth Mass extinctions and evolutionary explosions are the opposite faces of the pattern of diversity of organisms through time. During periods of mass extinction, the diversity of organisms on earth has dropped drastically 251
Extinctions and evolutionary explosions and in some cases entire lineages have been wiped out. Evolutionary explosions, on the other hand, resulted in enormous innovation, particularly at the beginning of the Cambrian period, and the development of new variations on established morphotypes (animal and plant forms and structures) later in the geologic record. Understanding the processes that caused these events is of major importance because people have reached the point where they are capable of influencing their environment in drastic ways. Studies of extinction events have shown that they have a variety of causes, some of which appear to be environmental changes brought about by natural processes while others may be the result of extraterrestrial forces. The most severe of these extinction events occurred at the end of the Permian period, 245 million years ago, and resulted in the loss of up to 95 percent of marine invertebrate species. The cause of this extinction appears primarily to be that continents were amalgamating and oceans were retreating, which resulted in a major reduction in the habitat of shallowmarine organisms. Terrestrial habitats were also affected as the increase in continental area and loss of the ameliorating effect of extensive areas of shallow ocean brought about climatic changes. Although climatic changes are thought to be the main culprit in the majority of extinction events, some scientists believe that large bolides, or extraterrestrial bodies, struck the earth with such force as to create major changes in the environment that significantly reduced diversity. This theory has enjoyed the most popularity as the explanation for the event at the end of the Cretaceous period, during which the dinosaurs became extinct, but evidence for an extraterrestrial body’s involvement in any of the other events is slight. Whatever the cause, environmental change that results in habitat reduction is the main reason for species decline. As humans have risen to dominance over other species, the extinction rate has accelerated, and in the last half-century, this rate has climbed considerably above natural attrition as populations have increased and habitats have been altered. Although the levels of extinction have not yet reached those recorded during major extinction events of the past, some scientists believe people may be facing an ecological disaster. A better understanding of the processes surrounding past extinction events and the rebounds that followed them will help people prepare for and deal with the future. David K. Elliott See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Development and ecological strategies; Evolution: definition 252
Extinctions and evolutionary explosions and theories; Evolution: history; Evolution of plants and climates; Gene flow; Genetic drift; Genetically modified foods; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Paleoecology; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Species loss. Sources for Further Study Allen, Keith C., and Derek E. Briggs, eds. Evolution and the Fossil Record. Washington, D.C.: Smithsonian Press, 1989. Alvarez, W. T. Rex and the Crater of Doom. Princeton, N.J.: Princeton University Press, 1997. Archibald, J. D. Dinosaur Extinction and the End of an Era. New York: Columbia University Press, 1996. Bakker, Robert T. The Dinosaur Heresies. New York: William Morrow, 1986. Briggs, Derek E., and Peter R. Crowther, eds. Palaeobiology: A Synthesis. Oxford, England: Blackwell Scientific Publications, 1990. Donovan, Stephen K., ed. Mass Extinctions: Processes and Evidence. London: Belhaven Press, 1989. Drury, Stephen. Stepping Stones: Evolving the Earth and Its Life. New York: Oxford University Press, 1999. Erwin, Douglas H. The Great Paleozoic Crisis. New York: Columbia University Press, 1993. Frankel, Charles. The End of the Dinosaurs: Chicxulub Crater and Mass Extinctions. New York: Cambridge University Press, 1999. Gould, Stephen J. Wonderful Life: The Burgess Shale and the Nature of History. New York: W. W. Norton, 1989. Leakey, Richard E., and Roger Lewin. The Sixth Extinction: Patterns of Life and the Future of Humankind. New York: Doubleday, 1995. McGhee, George R. The Late Devonian Mass Extinction. New York: Columbia University Press, 1996. McMenamin, Mark A., and Dianna L. McMenamin. The Emergence of Animals: The Cambrian Breakthrough. New York: Columbia University Press, 1989. Martin, Paul S., and Richard G. Klein, eds. Quaternary Extinctions: A Prehistoric Revolution. Tucson: University of Arizona Press, 1984. Muller, Richard. Nemesis: The Death Star. New York: Weidenfeld & Nicolson, 1988. Officer, Charles, and Jake Page. The Great Dinosaur Extinction Controversy. Boston: Addison-Wesley, 1996. Raup, David M. Extinction: Bad Genes or Bad Luck? New York: W. W. Norton, 1991. 253
Extinctions and evolutionary explosions Runnegar, Bruce, and James W. Schopf, eds. Major Events in the History of Life. Boston: Jones and Bartlett, 1992. Stanley, Steven M. Extinction. New York: Scientific American Library, 1987. Stearns, Beverly Petersen, and Stephen C. Stearns. Watching, from the Edge of Extinction. New Haven, Conn.: Yale University Press, 1999. Ward, Peter D., and Don Brownlee. Rare Earth: Why Complex Life Is Uncommon in the Universe. New York: Copernicus, 2000.
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FOOD CHAINS AND WEBS Types of ecology: Community ecology; Ecoenergetics The concept of food chains and webs allows ecologists to interconnect the organisms living in an ecosystem and to trace mathematically the flow of energy from plants through animals to decomposers.
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he food chain concept provides the basic framework for production biology and has major implications for agriculture, wildlife biology, and calculating the maximum amount of life that can be supported on the earth. As early as 1789, naturalists such as Gilbert White described the many sequences of animals eating plants and themselves being eaten by other animals. However, the use of the term “food chain” dates from 1927, when Charles Elton described the implications of the food chain and food web concept in a clear manner. His solid exposition advanced the study of two important biological concepts: the complex organization and interrelatedness of nature, and energy flow through ecosystems. Food Chains in Ecosystem Description Stephen Alfred Forbes, founder of the Illinois Natural History Survey, contended in 1887 that a lake comprises a system in which no organism or process can be understood unless its relationship to all the parts is understood. Forty years later, Elton’s food chains provided an accurate way to diagram these relationships. Because most organisms feed on several food items, food chains were cross-linked into complex webs with predictive power. For instance, algae in a lake might support an insect that in turn was food for bluegill. If unfavorable conditions eliminated this algae, the insect might also disappear. However, the bluegill, which fed on a wider range of insects, would survive because the loss of this algae merely increases the pressure on the other food sources. This detailed linkage of food chains advanced agriculture and wildlife management and gave scientists a solid overview of living systems. When Arthur George Tansley penned the term ecosystem in the 1930’s, it was food-chain relationships that described much of the equilibrium of the ecosystem. Today most people still think of food chains as the basis for the “balance of nature.” This phrase dates from the controversial 1960 work of Nelson G. Hairston, Frederick E. Smith, and Lawrence B. Slobodkin. They proposed that if only grazers and plants are present, grazing limits the plants. With predators present, however, grazers are limited by predation, and the 255
Food chains and webs plants are free to grow to the limits of the nutrients available. Such explanations of the “balance of nature” were commonly taught in biology books throughout the 1960’s and 1970’s. Food Chains in Production Biology Elton’s explanation of food chains came just one year after Nelson Transeau of Ohio State University presented his calculations on the efficiency with which corn plants converted sunlight into plant tissue. Ecologists traced this flow of stored chemical energy up the food chain to herbivores that ate plants and on to carnivores that ate herbivores. Food chains therefore undergirded the new “production biology” that placed all organisms at various trophic levels and calculated the extent to which energy was lost or preserved as it passed up the food chain. With data accumulating from many ecologists, Elton extended food chains into a pyramid of numbers. The food pyramid, in which much plant tissue supports some herbivores that are in turn eaten by fewer carnivores, is still referred to as an Eltonian pyramid. In 1939 August Thienemann added decomposers to reduce unconsumed tissues and return the nutrients of all levels back to the plants. Early pyramids were based on the amount of living tissues, or biomass. Calculations based on the amount of chemical energy at each level, as measured by the heat released when food is burned (calories), provided even more accurate budgets. Because so much energy is lost at each stage in a food chain, it became obvious that this inefficiency was the reason food chains are rarely more than five or six links long and why large, fierce animals are uncommon. It also became evident that because the earth intercepts a limited amount of sunlight energy per year, there is a limit on the amount of plant life—and ultimately upon the amount of animal life and decomposers—that can be fed. Food chains are also important in the accounting of carbon, nitrogen, and water cycling. Value of Food Chains in Environmental Science Unlike calories, which are dramatically reduced at each step in a food chain, some toxic substances become more concentrated as the molecules are passed along. The concentration of molecules along the food chain was first noticed by the Atomic Energy Commission, which found that radioactive iodine and strontium released in the Columbia River were concentrated in tissue of birds and fish. However, the pesticide DDT provided the most notorious example of biological magnification: DDT was found to be deposited in animal body fat in ever-increasing concentrations as it moved up the food chain to ospreys, pelicans, and peregrine falcons. High levels 256
Food chains and webs of DDT in these birds broke down steroid hormones and interfered with eggshell formation. Because humans are omnivores, able to feed at several levels on the food chain (that is, both plants and other animals), it has been suggested that a higher world population could be supported by humans moving down the food chain and becoming vegetarians. A problem with this argument is that much grazing land worldwide is unfit for cultivation, and therefore the complete cessation of pig or cattle farming does not necessarily free up substantial land to grow crops. While the food chain and food web concepts are convenient theoretical ways to summarize feeding interactions among organisms, real field situations have proved far more complex and difficult to measure. Animals often switch diet between larval and adult stages, and they are often able to shift food sources widely. It is often difficult to draw the boundaries of food chains and food webs. John Richard Schrock See also: Balance of nature; Biomass related to energy; Geochemical cycles; Herbivores; Hydrologic cycle; Nutrient cycles; Omnivores; Phytoplankton; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Colinvaux, Paul A. Why Big Fierce Animals Are Rare. New York: Penguin Books, 1990. Elton, Charles. Animal Ecology. New York: October House, 1966. Golley, Frank B. A History of the Ecosystem Concept in Ecology. New Haven, Conn.: Yale University Press, 1993. Quamman, David. The Song of the Dodo: Island Biogeography in an Age of Extinction. New York: Simon & Schuster, 1997. “Something’s Fishy.” Science News 146, no. 1 (July 2, 1994): 8. Svitil, Kathy A. “Collapse of a Food Chain.” Discover 16, no. 7 (July, 1995): 36.
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FOREST FIRES Type of ecology: Ecosystem ecology Whether natural or caused by humans, fires destroy life and property in forestlands but are also vital to the health of forests.
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vidence of forest fires is routinely found in soil samples and tree borings. The first major North American fires in the historical record were the Miramichi and Piscataquis fires of 1825. Together, they burned 3 million acres in Maine and New Brunswick. Other U.S. fires of significance were the Peshtigo fire in 1871, which raged over 1.28 million acres and took fourteen hundred human lives in Wisconsin; the fire that devastated northern Idaho and northwestern Montana in 1910 and killed at least seventynine firefighters; and a series of fires that joined forces to sweep across onethird of Yellowstone National Park in 1988. Fire Behavior Fires need heat, fuel, and oxygen. They spread horizontally by igniting particles at their edge. At first, flames burn at one point, then move outward, accumulating enough heat to keep burning on their own. Topography and weather affect fire behavior. Fires go uphill faster than downhill because warm air rises and preheats the uphill fuels. Vegetation on southand west-facing slopes receives maximal sunlight and so is drier and burns more easily. Heat is pulled up steep, narrow canyons, as it is up a chimney, increasing heat intensity. For several reasons, only one-third of the vegetation within a large fire usually burns. This mosaic effect may be caused by varied tree species that burn differently, old burns that stop fire, strong winds that blow the fire to the leeward side of trees, and varied fuel moisture. Ecological Benefits Some plant species require very high temperatures for their seed casings to split for germination. After fire periodically sweeps through the forest, seeds will germinate. Other species, such as the fire-resistant ponderosa pine, require a shallow layer of decaying vegetable matter in which to root. Fires burn excess debris and small trees of competing species and leave an open environment suitable for germination. Dead material on the forest floor is processed into nutrients more quickly by fire than by decay, and in 258
Forest fires a layer of rich soil, plants will sprout within days to replace those destroyed in the fire. Ecological Destruction Erosion is one of the devastating effects of a fire. If the fuels burn hot, tree oils and resins can be baked into the soil, creating a hard shell that will not absorb water. When it rains, the water runoff gathers mud and debris, creating flash floods and extreme stream sedimentation. Culverts and storm drains fill with silt, and streams flood and change course. Fish habitat is destroyed, vegetation sheltering stream banks is ripped away, and property many miles downstream from the forest is affected. When a fire passes through timber it generally leaves pockets of green, although weakened, stands. Forest pests, such as the bark beetle, are attracted to the burned trees and soon move to the surviving trees, weakening them further. Healthy trees outside the burn area may also fall to pest infestation unless the burned trees are salvaged before pests can take hold.
During the twentieth century, low fires that otherwise would have burned through the forest at ground level every five to twenty-five years were suppressed. As a result, the natural cycle of frequent fires moving through an area was broken, and when fire did erupt, accumulated kindling burned hot and fast, exploding into devastating crown fires and completely destroying the local community’s habitat. (PhotoDisc) 259
Forest fires The ash and smoke from hot, fast-burning forest fires can be transported for miles, affecting air quality many miles from the actual fire. Ecological Impact of Fire Suppression One of the early criteria of forest management was fire protection. In the second quarter of the twentieth century, lookout towers, firebreaks, and trails were built to locate fires as quickly as possible. Low fires that otherwise would have burned through the forest at ground level and cleared out brush every five to twenty-five years were suppressed. As a result, the natural cycle of frequent fires moving through an area was broken. Fallen trees, needles, cones, and other debris collected as kindling on the forest floor, rather than being incinerated every few years. It took foresters and ecologists fifty years to realize that too much fire suppression was as bad as too little. Infrequent fires cause accumulated kindling to burn hot and fast and explode into treetops. The result is a devastating crown fire, a large fire that advances as a single front. Burning embers of seed cones and sparks borne by hot, strong winds created within the fire are tossed into unburned areas to start more fires. Prescribed Burns In the 1970’s prescribed burning was added to forest management techniques used to keep forests healthy. Fires set by lightning are allowed to burn when the weather is cool, the area isolated, and the risk of the fire exploding into a major fire low. More than 70 percent of prescribed burning takes place in the southeastern states, where natural fires burn through an area more frequently than in the West. In some areas, prescribed fires are set in an attempt to re-create the natural sequence of fire. In Florida, prescribed burns provide wildlife habitat by opening up groves to encourage healthy growth. Other fires start accidentally but are allowed to burn until they reach a predetermined size. Although a prescribed fire is an attempt to duplicate natural fire, it is not as efficient, because private and commercial property within the fire path must be protected. Once a fire has occurred, burned timber deteriorates quickly, either through insect infestation or blueing—a mold that stains the wood. Private landowners can move quickly to salvage firedamaged trees and plant new seedlings to harness erosion. On federal land, regulations governing the salvage of trees can delay logging of the burned snags until deterioration makes it uneconomical to harvest them. Causes Forest fires may be caused by natural events or human activity. Most natu260
Forest fires ral fires are started by lightning strikes. Dozens of strikes can be recorded from one lightning storm. When a strike seems likely, fire spotters watch for columns of smoke, and small spotter planes will fly over the area, looking for smoke. Many of the small fires simply smoulder and go out, but if the forest is dry, multiple fires can erupt from a single lightning storm. The majority of forest fires are human-caused, and most are the result of carelessness rather than arson. Careless campers may leave a campsite without squelching their campfire completely, and winds may then whip the glowing embers into flames. A smoker may toss a cigarette butt from a car window. Sparks from a flat tire riding on the rim may set fire to vegetation alongside the highway. The sun shining through a piece of broken glass left by litterers may ignite dry leaves. Fire Fighting In fire fighting, bulldozers are used to cut fire lines ahead of the approaching fire, and fuels between fire lines and the fire are backburned. Helicopters and tanker planes drop water with a fire-retardant additive, or bentonite, a clay, at the head of the fire to smother fuels. Firefighters are equipped with fire shelters in the form of aluminized pup tents, which they can pull over themselves if a fire outruns them. Despite technological advances, one of the best tools for fighting fires—along with the shovel—remains the pulaski, a combination ax and hoe, first produced commercially in 1920. This tool, in the hands of on-the-ground firefighters, is used to cut fire breaks and to throw dirt on smoldering debris. Public Policy and Public Awareness Since the early twentieth century, forest fires have engendered public policy in the United States. In the aftermath of major fires in 1903 and 1908 in Maine and New York, state fire organizations and private timber protective associations were formed to provide fire protection. These, in turn, contributed to the Weeks Act of 1911, which permitted cooperative fire protection between federal and state governments. People who make their homes in woodland settings in or near forests face the danger of forest fire, and government agencies provide information to help people safeguard themselves and their property. Homes near forests should be designed and landscaped with fire safety in mind, using fire-resistant or noncombustible materials on the roof and exterior. Landscaping should include a clear safety zone around the house. Hardwood trees, less flammable than conifers, and other fire-resistant vegetation should be planted. J. A. Cooper 261
Forest fires See also: Communities: structure; Erosion and erosion control; Forest management; Forests; Mediterranean scrub; Mountain ecosystems; Oldgrowth forests; Paleoecology; Rain forests; Savannas and deciduous tropical forests; Taiga; Trophic levels and ecological niches. Sources for Further Study Fuller, Margaret. Forest Fires: An Introduction to Wildland Fire Behavior, Management, Firefighting, and Prevention. New York: Wiley, 1991. Johnson, Edward A. Fire and Vegetation Dynamics: Studies from the North American Boreal Forest. New York: Cambridge University Press, 1992. Kasischke, Eric S., and Brian J. Stocks, eds. Fire, Climate Change, and Carbon Cycling in the Boreal Forest. New York: Springer, 2000. Pringle, Laurence P. Fire in the Forest: A Cycle of Growth and Renewal. New York: Simon and Schuster, 1995. Pyne, Stephen J. Fire in America: A Cultural History of Wildland and Rural Fire. 2d ed. Seattle: University of Washington Press, 1997. Whelan, Robert J. The Ecology of Fire. New York: Cambridge University Press, 1995.
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FOREST MANAGEMENT Type of ecology: Restoration and conservation ecology Forest management includes reforestation programs as well as techniques to manage logging practices, provide grazing lands, support mining operations, maintain infrastructure networks, or slow the destruction of rain forests.
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orests provide lumber for buildings, wood fuel for cooking and heating, and raw materials for making paper, latex rubber, resin, dyes, and essential oils. Forests are also home to millions of plants and animal species and are vital in regulating climate, purifying the air, and controlling water runoff. A 1993 global assessment by the United Nations Food and Agriculture Organization (FAO) found that three-fourths of the forests in the world still have some tree cover, but less than one-half of these have intact forest ecosystems. Deforestation is occurring at an alarming rate, and management practices are being sought to try to halt this destruction. Thousands of years ago, forests and woodlands covered almost 15 billion acres of the earth. Approximately 16 percent of the forests have been cleared and converted to pasture, agricultural land, cities, and nonproductive land. The remaining 11.4 billion acres of forests cover about 30 percent of the earth’s land surface. Clearing forests has severe environmental consequences. It reduces the overall productivity of the land, and nutrients and biomass stored in trees and leaf litter are lost. Soil once covered with plants, leaves, and snags becomes prone to erosion and drying. When forests are cleared, habitats are destroyed and biodiversity is greatly diminished. Destruction of forests causes water to drain off the land instead of being released into the atmosphere by transpiration or percolation into groundwater. This can cause major changes in the hydrologic cycle and ultimately in the earth’s climate. Because forests remove a large amount of carbon dioxide from the air; the clearing of forests causes more carbon dioxide to remain, thus upsetting the delicate balance of atmospheric gases. Rain Forests Rain forests provide habitats for at least 50 percent (some estimates are as high as 90 percent) of the total stock of plant, insect, and other animal species on earth. They supply one-half of the world’s annual harvest of hardwood and hundreds of food products, such as chocolate, spices, nuts, coffee, and tropical fruits. Tropical rain forests also provide the main ingredients in 25 percent of prescription and nonprescription drugs, as well as 75 per263
Forest management cent of the three thousand plants identified as containing chemicals that fight cancer. Industrial materials, such as natural latex rubber, resins, dyes, and essential oils, are also harvested from tropical forests. Tropical forests in Asia, Africa, and Latin America are rapidly being cleared to produce pastureland for large cattle ranches, establish logging operations, construct large plantations, grow narcotic plants, develop mining operations, or build dams to provide power for mining and smelting operations. In 1985 the FAO’s Committee on Forest Development in the Tropics developed the Tropical Forestry Action Plan to combat these practices, develop sustainable forest methods, and protect precious ecosystems. Fifty nations in Asia, Africa, and Latin America have adopted the plan. Management Techniques Several management techniques have been successfully applied to slow the destruction of tropical forests. Sustainable logging practices and reforestation programs have been established on lands that allow timber cutting, with complete bans of logging on virgin lands. Certain regions have set up extractive reserves to protect land for the native people who live in the forest and gather latex rubber and nuts from mature trees. Sections of some tropical forests have been preserved as national reserves, which attract tourists while preserving trees and biodiversity. Developing countries have been encouraged to protect their tropical forests by using a combination of debt-for-nature swaps and conservation easements. In debt-for-nature swaps, tropical countries act as custodians of the tropical forest in exchange for foreign aid or relief from debt. Conservation easement involves having another country, private organization, or consortium of countries compensate a tropical country for protecting a specific habitat. Another management technique involves putting large areas of the forest under the control of indigenous people who use slash-and-burn agriculture (also known as swidden or milpa agriculture). This traditional, productive form of agriculture follows a multiple-year cycle. Each year farmers clear a forest plot of several acres in size to allow the sun to penetrate to the ground. Leaf litter, branches, and fallen trunks are burned, leaving a rich layer of ashes. Fast-growing crops, such as bananas and papayas, are planted and provide shade for root crops, which are planted to anchor the soil. Finally, crops such as corn and rice are planted. Crops mature in a staggered sequence, thus providing a continuous supply of food. Use of mixed perennial polyculture helps prevent insect infestations, which can destroy monoculture crops. After one or two years, the forest begins to 264
Forest management take over the agricultural plot. The farmers continue to pick the perennial crops but essentially allow the forest to reclaim the plot for the next ten to fifteen years before clearing and planting the area again. Slash-and-burn agriculture can, however, post hazards: A drought in Southeast Asia in 1997 caused such fires to burn for months when monsoon rains did not materialize, polluting the air and threatening the health of millions of Indonesians. In 1998, previous abuse of the technique resulted in flooding and mudslides in Honduras after the onset of Hurricane Mitch. U.S. Forest Management Forests cover approximately one-third of the land area of the continental United States and comprise 10 percent of the forests in the world. Only about 22 percent of the commercial forest area in the United States lies within national forests. The rest is primarily managed by private companies that grow trees for commercial logging. Land managed by the U.S. Forest Service provides inexpensive grazing lands for more than three million cattle and sheep every year, supports multimillion-dollar mining operations, and consists of a network of roads eight times longer than the U.S. interstate highway system. Almost 50 percent of national forest land is open for commercial logging. Nearly 14 percent of the timber harvested in the United States each year comes from national forest lands. Total wood production in the United States has caused the loss of more than 95 percent of the old-growth forests in the lower forty-eight states. This loss includes not only high-quality wood but also a rich diversity of species not found in early-growth forests. National forests in the United States are required by law to be managed in accordance with principles of sustainable yield. Congress has mandated that forests be managed for a combination of uses, including grazing, logging, mining, recreation, and protection of watersheds and wildlife. Healthy forests also require protection from pathogens and insects. Sustainable forestry, which emphasizes biological diversity, provides the best management. Other management techniques include removing only infected trees and vegetation, cutting infected areas and removing debris, treating trees with antibiotics, developing disease-resistant species of trees, using insecticides and fungicides, and developing integrated pest management plans. Two basic systems are used to manage trees: even-aged and unevenaged. Even-aged management involves maintaining trees in a given stand that are about the same age and size. Trees are harvested, then seeds are replanted to provide for a new even-aged stand. This method, which tends toward the cultivation of a single species or monoculture of trees, empha265
Forest management
Environmental Effects of Select Silvicultural Methods Long-term effects Soil acidification
Silvicultural methods Converting mixed forest stands to monoculture Fertilizing Forest machines leave the residues in heaps, often on wet sites
Soil erosion
Clear-cutting
Short-term effects
Increased leaching of nutrients, especially nitrogen
Increased water runoff
Soil scarification Decreased number of plant and animal species of the forests, mires, and fens Decreased number of forest plant and animal species
Draining Short rotation intervals Decreased number of old and dead trees
Increased amount of organic material and metals (Fe, Al, Hg) in water and ecosystems; secondary effects on fish
Foreign species
Source: Adapted from I. Stjernquist, “Modern Wood Fuels,” in Bioenergy and the Environment, edited by Pasztor and Kristoferson, 1990.
sizes the mass production of fast-growing, low-quality wood (such as pine) to give a faster economic return on investment. Even-aged management requires close supervision and the application of both fertilizer and pesticides to protect the monoculture species from disease and insects. Uneven-aged management maintains trees at many ages and sizes to permit a natural regeneration process. This method helps sustain biological diversity, provides for long-term production of high-quality timber, allows for an adequate economic return, and promotes a multiple-use approach to forest management. Uneven-aged management also relies on selective cutting of mature trees and reserves clear-cutting for small patches of tree species that respond favorably to such logging methods. Harvesting Methods The use of a particular tree-harvesting method depends on the tree species involved, the site, and whether even-aged or uneven-aged management is being applied. Selective cutting is used on intermediate-aged or mature 266
Forest management trees in uneven-aged forests. Carefully selected trees are cut in a prescribed stand to provide for a continuous and attractive forest cover that preserves the forest ecosystem. Shelterwood cutting involves removing all the mature trees in an area over a period of ten years. The first harvest removes dying, defective, or diseased trees. This allows more sunlight to reach the healthiest trees in the forest, which will then cast seeds and shelter new seedlings. When the seedlings have turned into young trees, a second cutting removes many of the mature trees. Enough mature trees are left to provide protection for the younger trees. When the young trees become well established, a third cutting harvests the remaining mature trees, leaving an even-aged stand of young trees from the best seed trees to mature. When done correctly, this method leaves a natural-looking forest and helps reduce soil erosion and preserve wildlife habitat. Seed-tree cutting harvests almost every tree at one site, with the exception of a few high-quality seed-producing and wind-resistant trees, which will function as a seed source to generate new crops. This method allows a variety of species to grow at one time and aids in erosion control and wildlife conservation. Clear-cutting removes all the trees in a single cutting. The clear-cut may involve a strip, an entire stand, or patches of trees. The area is then replanted with seeds to grow even-aged or tree-farm varieties. More than two-thirds of the timber produced in the United States, and almost onethird of the timber in national forests, is harvested by clear-cutting. A clearcut reduces biological diversity by destroying habitat. It can make trees in bordering areas more vulnerable to winds and may take decades to regenerate. Forest Fires Forest fires can be divided into three types: surface, crown, and ground fires. Surface fires tend to burn only the undergrowth and leaf litter on the forest floor. Most mature trees easily survive, as does wildlife. These fires occur every five years or so in forests with an abundance of ground litter and help prevent more destructive crown and ground fires. Such fires can release and recycle valuable mineral nutrients, stimulate certain plant seeds, and help eliminate insects and pathogens. Crown fires are very hot fires that burn both ground cover and tree tops. They normally occur in forests that have not experienced fires for several decades. Strong winds allow these fires to spread from deadwood and ground litter to treetops. They are capable of killing all vegetation and wildlife, leaving the land prone to erosion. 267
Forest management Ground fires are more common in northern bogs. They can begin as surface fires but burn peat or partially decayed leaves below the ground surface. They can smolder for days or weeks before anyone notices them, and they are difficult to douse. Natural forest fires can be beneficial to some plant species, including the giant sequoia and the jack pine trees, which release seeds for germination only after being exposed to intense heat. Grassland and coniferous forest ecosystems that depend on fires to regenerate are called fire climax ecosystems. They are managed for optimum productivity with prescribed fires. The Society of American Foresters has begun advocating a concept called new forestry, in which ecological health and biodiversity, rather than timber production, are the main objectives of forestry. Advocates of new forestry propose that any given site should be logged only every 350 years, wider buffer zones should be left beside streams to reduce erosion and protect habitat, and logs and snags should be left in forests to help replenish soil fertility. Proponents also wish to involve private landowners in the cooperative management of lands. Toby R. Stewart and Dion Stewart See also: Communities: structure; Conservation biology; Deforestation; Erosion and erosion control; Forest fires; Forests; Grazing and overgrazing; Integrated pest management; Multiple-use approach; Old-growth forests; Reforestation; Restoration ecology; Species loss; Sustainable development; Urban and suburban wildlife; Wildlife management. Sources for Further Study Davis, Kenneth P. Forest Management. New York: McGraw-Hill, 1996. Davis, Lawrence S., and K. Norman Johnson. Forest Management. 3d ed. New York: McGraw-Hill, 1987. Hunter, Malcolm L., Jr. Wildlife, Forests, and Forestry. Englewood Cliffs, N.J.: Prentice-Hall, 1990. McNeely, Jeffrey A. Conserving the World’s Biological Diversity. Washington, D.C.: WRI, 1990. Nyland, Ralph D. Silviculture: Concepts and Applications. 2d ed. Boston: McGraw-Hill, 2002. Robbins, William G. American Forestry. Lincoln: University of Nebraska Press, 1985. Smith, David M. The Practice of Silviculture. 9th ed. New York: Wiley, 1997. Spurr, Stephen H., and Burton V. Barnes. Forest Ecology. 4th ed. New York: Wiley, 1998.
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FORESTS Types of ecology: Biomes; Ecosystem ecology Forests are complex ecosystems in which trees are the dominant type of plant. There are three main forest biomes: tropical, temperate, and boreal.
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oth humans and animals depend on forests for food, shelter, and other resources. Forests once covered much of the world and are still found from the equator to the Arctic regions. A forest may vary in size from only a few acres to thousands of square miles, but generally any natural area in which trees are the dominant type of plant can be considered a forest. For a plant to be called a tree, the standard definition requires that the plant must attain a mature height of at least 8 feet (about 3 meters), have a woody stem, and possess a distinct crown. Thus, size makes roses shrubs and apples trees, even though apples and roses are otherwise close botanical relatives. Foresters generally divide the forests of the world into three general categories: tropical, temperate, and boreal. Tropical Rain Forest The tropical rain forest is a forest consisting of a dizzying variety of trees, shrubs, and other plants that remain green year-round. The growth is lush and usually includes both a dense canopy formed by the crowns of the largest trees and a thick understory of smaller trees and shrubs. Growth is often continuous, rather than broken into periods of dormancy and active growth, so that fruiting trees are occasionally seen bearing blossoms and mature fruit simultaneously. Temperate Forest The temperate forest lies between the tropical forest and the boreal, or northern, forest. The forests of the Mediterranean region of Europe as well as the forests of the southern United States are temperate forests. Trees in temperate forests can be either deciduous or coniferous. Although coniferous trees are generally thought of as evergreen, the distinction between types is actually based on seed production and leaf shape. Coniferous trees, such as spruces, pines, and hemlocks, produce seeds in cones and have needle-like leaves. Deciduous trees, such as maples, poplars, and oaks, have broad leaves and bear seeds in other ways. Some conifers, such as tamarack, do change color and drop their needles in the autumn, while 269
Forests some deciduous trees, particularly in the southerly regions of the temperate forest, are evergreen. Deciduous trees are also referred to as hardwoods, while conifers are softwoods, a classification that refers more to the typical density of the wood than to how difficult it is to nail into it. Softwoods are lower in density and will generally float in water while still green. Hardwoods are higher in density on average and will sink. Like tropical forests, temperate forests can be quite lush. While the dominant species vary from area to area, depending on factors such as soil types and available rainfall, a dense understory of shade-tolerant species often thrives beneath the canopy. Thus, a mature temperate forest may have thick stands of rhododendrons 20 to 30 feet (6 to 9 meters) high thriving in the shade of 80-foot (24-meter) oaks and tulip poplar. As the temperate forest approaches the edges of its range and the forest makes the transition to boreal, the understory thins out, disappearing almost completely or consisting only of low shrubs. Even in temperate forests, the dominant species may prevent an understory from forming. Stands of southern loblolly pine, for example, often have a parklike feel, as the thick mulch created by fallen needles chokes out growth of other species. Boreal Forest The boreal forest, which lies in a band across the northern United States, Canada, northern Europe, and northern Asia, is primarily a coniferous forest. The dominant species are trees such as white spruce, hemlock, and white pine. Mixed stands of northern hardwoods, such as birch, sugar maple, and red oak, may be found along the southern reaches of the boreal forest. As the forest approaches the Arctic, trees are fewer in type, becoming primarily spruce, birch, and willows, and smaller in size. The understory is generally thin or nonexistent, consisting of seedlings of shadetolerant species, such as maple, and low shrubs. Patches of boreal-type forest can be found quite far south in higher elevations in the United States, such as the mountains of West Virginia. The edge of the temperate forest has crept steadily northward following the retreat of the glaciers at the end of the Ice Age twenty thousand years ago. Forest Ecology and Resources In all three types of forest a complex system of interrelationships governs the ecological well-being of the forest and its inhabitants. Trees and animals have evolved to fit into particular environmental niches. Some wildlife may need one resource provided by one species of tree in the forest during one season and a resource provided by another during a different 270
Forests
Forest Areas by Region temperate/boreal North America, 13.2% (457 million hectares; 1,129 million acres)
Latin America and the Caribbean, 27.5% (950 million hectares; 2,347 million acres)
Europe, 4.2% (146 million hectares; 361 million acres)
Africa, 15.1% (520 million hectares; 1,284 million acres)
former USSR, 23.6% (816 million hectares; 2,016 million acres) Asia/Oceania, 16.4% (565 million hectares; 1,396 million acres)
1995: total area = 3,454 million hectares; 8,533 million acres Source: Data are from United Nations Food and Agriculture Organization (FAOSTAT Database, 2000)
time of year, while other animals become totally dependent on one specific tree. Whitetail deer, for example, browse on maple leaves in the summer, build reserves of fat by eating acorns in the fall, and survive the winter by eating evergreens. Deer are highly adaptable in contrast with other species, such as the Australian koala, which depends entirely on eucalyptus leaves for its nutritional needs. Just as the animals depend on the forest, the forest depends on the animals to disperse seeds and thin new growth. Certain plant seeds, in fact, will not sprout until being abraded as they pass through the digestive tracts of birds. Humans also rely on the forest for food, fuel, shelter, and other products. Forests provide wood for fuel and construction, fibers for paper, and chemicals for thousands of products often not immediately recognized as deriving from the forest, such as plastics and textiles. In addition, through the process of transpiration, forests regulate the climate by releasing water vapor into the atmosphere while removing harmful carbon compounds. Forests play an important role in the hydrology of a watershed. Rain that falls on a forest will be slowed in its passage downhill and is often absorbed into the soil rather than running off into rivers 271
Forests and lakes. Thus, forests can moderate the effects of severe storms, reducing the dangers of flooding and preventing soil erosion along stream and river banks. Threats to the Forest The primary threat to the health of forests around the world comes from humans. As human populations grow, three types of pressure are placed on forests. First, forests are cleared to provide land for agriculture or for the construction of new homes. This process has occurred almost continuously in the temperate regions for thousands of years, but it did not become common in tropical regions until the twentieth century. Often settlers level the forest and burn the fallen trees to clear land for farming (slash-and-burn agriculture) without the wood itself being utilized in any way. Tragically, the land thus exposed can become infertile for farming within a few years. After a few years of steadily diminishing crops, the land is abandoned. With the protective forest cover removed, it may quickly become a barren, eroded wasteland. Second, rising or marginalized populations in developing nations often depend on wood or charcoal as their primary fuel for cooking and for home heat. Forests are destroyed as mature trees are removed for fuel wood faster than natural growth can replace them. As the mature trees disappear, younger and younger growth is also removed, and eventually the forest is gone completely. Finally, growing populations naturally demand more products derived from wood, which can include everything from lumber for construction to chemicals used in cancer research. Market forces can drive forest products companies to harvest more trees than is ecologically sound as stockholders focus on short-term individual profits rather than long-term environmental costs. The challenge to foresters, ecologists, and other scientists is to devise methods that allow humanity to continue to utilize the forest resources needed to survive without destroying the forests as complete and healthy ecosystems. Nancy Farm Männikkö See also: Biomes: types; Deforestation; Erosion and erosion control; Forest fires; Forest management; Grazing and overgrazing; Mountain ecosystems; Multiple-use approach; Old-growth forests; Paleoecology; Rain forests; Rain forests and the atmosphere; Reforestation; Restoration ecology; Savannas and deciduous tropical forests; Species loss; Sustainable development; Taiga; Trophic levels and ecological niches; Tundra and highaltitude biomes; Urban and suburban wildlife; Wildlife management. 272
Forests Sources for Further Study Holland, Israel I. Forests and Forestry. 5th ed. Danville, Ill.: Interstate, 1997. Kimmins, J. P. Balancing Act: Environmental Issues in Forestry. 2d ed. Vancouver: UBC Press, 1997. Page, Jake. Forest. Rev. ed. Alexandria, Va.: Time-Life Books, 1987. Walker, Laurence C. The Southern Forest. Austin: University of Texas Press, 1991.
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GENE FLOW Types of ecology: Community ecology; Evolutionary ecology; Population ecology; Speciation Gene flow represents a recurrent exchange of genes between populations. This exchange results when immigrants from one population interbreed with members of another.
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harles Darwin published On the Origin of Species by Means of Natural Selection in 1859. Since then, scientists have modified and added new concepts to the theory of evolution by natural selection. One of those concepts, which was only dimly understood in Darwin’s lifetime, is the importance of genetics in evolution, especially the concepts of migration and gene flow. Genes Genes are elements within the cells of a living organism that control the transmission of hereditary characteristics by specifying the structure of a particular protein or by controlling the function of other genetic material. Within any species, the exchange of genes via reproduction is constant among its members, ensuring genetic similarity. If a new gene or combination of genes appears in the population, it is rapidly dispersed among all members of the population through inbreeding. New alleles (forms of a gene) may be introduced into the gene pool of a breeding population (thus contributing to the evolution of that species) in two ways: mutation and migration. Gene flow is integral to both processes. A mutation occurs when the DNA code of a gene becomes modified so that the product of the gene will also be changed. Mutations occur constantly in every generation of every species. Most of them, however, are either minor or detrimental to the survival of the individual and thus are of little consequence. A very few mutations may prove valuable to the survival of a species and are spread to all of its members by migration and gene flow. Separation and Migration In nature, gene flow occurs on a more or less regular basis between demes, geographically isolated populations, races, and even closely related species. Gene flow is more common among the adjacent demes of one species. The amount of migration between such demes is high, thus ensuring that 274
Gene flow their gene pools will be similar. This sort of gene flow contributes little to the evolutionary process, as it does little to alter gene frequencies or to contribute to variation within the species. Much more significant for the evolutionary process is gene flow between two populations of a species that have not interbred for a prolonged period of time. Populations of a species separated by geographical barriers (as a result, for example, of seed dispersal to a distant locale) often develop very dissimilar gene combinations through the process of natural selection. In isolated populations, dissimilar alleles become fixed or are present in much different frequencies. When circumstances do permit gene flow to occur between populations, it results in the breakdown of gene complexes and the alteration of allele frequencies, thereby reducing genetic differences in both. The degree of this homogenization process depends on the continuation of interbreeding among members of the two populations over extended periods of time. Hybridization The migration of a few individuals from one breeding population to another may, in some instances, also be a significant source of genetic variation in the host population. Such migration becomes more important in the evolutionary process in direct proportion to the differences in gene frequencies—for example, the differences between distinct species. Biologists call interbreeding between members of separate species hybridization. Hybridization usually does not lead to gene exchange or gene flow, because hybrids are not often well adapted for survival and because most are sterile. Nevertheless, hybrids are occasionally able to breed (and produce fertile offspring) with members of one or sometimes both the parent species, resulting in the exchange of a few genes or blocks of genes between two distinct species. Biologists refer to this process as introgressive hybridization. Usually, few genes are exchanged between species in this process, and it might be more properly referred to as “gene trickle” rather than gene flow. Introgressive hybridization may, however, add new genes and new gene combinations, or even whole chromosomes, to the genetic architecture of some species. It may thus play a role in the evolutionary process, especially in plants. Introgression requires the production of hybrids, a rare occurrence among highly differentiated animal species but quite common among closely related plant species. Areas where hybridization takes place are known as contact zones or hybrid zones. These zones exist where populations overlap. In some cases of hybridization, the line between what constitutes different species and what constitutes different populations of 275
Gene flow the same species becomes difficult to draw. The significance of introgression and hybrid zones in the evolutionary process remains an area of some contention among life scientists. Speciation Biologists often explain, at least in part, the poorly understood phenomenon of speciation through migration and gene flow—or rather, by a lack thereof. If some members of a species become geographically isolated from the rest of the species, migration and gene flow cease. Such geographic isolation can occur, for example, when populations are separated by water (as occurs on different islands or other landmasses) or valleys (different hillsides). The isolated population will not share in any mutations, favorable or unfavorable, nor will any mutations that occur among its own members be transmitted to the general population of the species. Over long periods of time, this genetic isolation will result in the isolated population becoming so genetically different from the parent species that its members can no longer produce fertile progeny should one of them breed with a member of the parent population. The isolated members will have become a new species, and the differences between them and the parent species will continue to grow as time passes. Scientists, beginning with Darwin, have demonstrated that this sort of speciation has occurred on the various islands of the world’s oceans and seas. Paul Madden See also: Adaptive radiation; Clines, hybrid zones, and introgression; Convergence and divergence; Evolution: definition and theories; Evolution of plants and climates; Extinctions and evolutionary explosions; Genetic diversity; Genetic drift; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Punctuated equilibrium vs. gradualism; Speciation. Sources for Further Study Christiansen, Freddy B. Population Genetics of Multiple Loci. New York: Wiley, 2000. Endler, John A. Geographic Variation, Speciation, and Clines. Princeton, N.J.: Princeton University Press, 1977. Foster, Susan A., and John A. Endler, eds. Geographic Variation in Behavior: Perspectives on Evolutionary Mechanisms. New York: Oxford University Press, 1999. Leapman, Michael. The Ingenious Mr. Fairchild: The Forgotten Father of the Flower Garden. New York: St. Martin’s Press, 2001. 276
Gene flow Mousseau, Timothy A., Barry Sinervo, and John A. Endler, eds. Adaptive Genetic Variation in the Wild. New York: Oxford University Press, 2000. Real, Leslie A., ed. Ecological Genetics. Princeton, N.J.: Princeton University Press, 1994. Stuessy, Tod F., and Mikio Ono, eds. Evolution and Speciation of Island Plants. New York: Cambridge University Press, 1998.
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GENETIC DIVERSITY Types of ecology: Community ecology; Ecosystem ecology; Population ecology; Restoration and conservation ecology Genetic diversity includes the inherited traits encoded in the DNA of all living organisms and can be examined on four levels: among species, among populations (in communities), within populations, and within individuals. Populations with higher levels of diversity are better able to adapt to changes in the environment and are more resistant to the deleterious effects of inbreeding.
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enetic diversity is the most fundamental level of biological diversity because genetic material is responsible for the variety of life. For new species to form, genetic material must change. Changes in the inherited properties of populations occur deterministically through gene flow (mating between individual organisms representing formerly separated populations) and through natural or artificial selection (which occurs when some types of individuals breed more successfully than others). Change can also occur randomly through mutations or genetic drift (when the relative proportions of genes change by chance in small populations). Populations with higher levels of diversity tend to do better—to have more survival options—as surroundings change than do populations (particularly smaller ones) with lower levels of genetic diversity. Preservation Efforts Conservation efforts directed at maintaining genetic diversity involve both germ plasm preservation (germ plasm kept in a steady state for periods of time) and germ plasm conservation (germ plasm kept in a natural, evolving state). The former usually involves ex situ laboratory techniques in which genetic resources are removed from their natural habitats. They include seminatural strategies such as botanical gardens, arboreta, nurseries, zoos, farms, aquaria, and captive fisheries, as well as completely artificial methods such as seed reserves or “banks,” microbial cultures (preserving bacteria, fungi, viruses, and other microorganisms), tissue cultures of parts of plants and animals (including sperm storage), and gene libraries (involving storage and replication of partial segments of plant or animal DNA, or deoxyribonucleic acid). Conservation areas are the preferred in situ (at the natural or original place) means of protecting genetic resources. Ideally these include preserving the number and relative proportions of species and the genetic diver278
Genetic diversity sity they represent, the physical features of the habitat, and all ecosystem processes. It is not always enough, however, to maintain the ecosystem which the threatened species inhabits. It is sometimes necessary to take an active interventionist position in order to save a species. Controversial strategies can include reintroduction of captive species into the wild, sometimes after they have been genetically manipulated. Direct management of the ecosystem may also be attempted by either lessening human exploitation and interference or by reducing the number of natural predators or competitors. However, management of a specific conservation area varies in terms of what is valued and how preservation is accomplished. Crop Diversity One area of keen interest that illustrates the issues involved with the preservation of any kind of genetic diversity is how to preserve crop germ plasm. Largely conserved in gene banks, crop germ plasm was historically protected by farmers who selected for success in differing environments and other useful traits. Traditionally cultivated varieties (landraces) diversified as people spread into new areas. Colonial expansion produced new varieties as farmers adapted to new conditions and previously separated plant species interbred; other species were lost when some societies declined and disappeared. By the early 1900’s field botanists and agronomists were expressing concern about the rapidly escalating loss of traditionally cultivated varieties. This loss accelerated after the 1940’s as high yielding hybrids of cereal and vegetable crops replaced local landraces. Wild relatives of these landraces are also disappearing as their habitats are destroyed through human activity. Gene banks preserve both kinds of plants because, as argued by Nikolai I. Vavilov in 1926, crop plant improvement can best be accomplished by taking advantage of these preserved genetic stocks. Vavilov also noted that genetic variation for most cultivated species was concentrated in specific regions, his “centers of diversity,” most of which are regions where crop species originated. The vulnerability to parasites and climate of an agriculture that relies on one or a few varieties of crops necessitates the maintenance of adequate reserves of genetic material for breeding. In addition to the preservation of species known to be useful, many people advocate preservation of wild species for aesthetic reasons as well as for their unknown future potential. Maintenance of Productivity Farmers in developed nations change crop varieties every four to ten years in order to maintain consistent levels of food production. This necessitates 279
Genetic diversity an ongoing search for new breeds with higher yields and an ability to withstand several environmental challenges, including resistance to multiple pests and drought. Over time, older varieties mutate, become less popular at the marketplace, or are unable to adapt to new conditions. However, farmers from poorer nations are not always able to take advantage of the new breeds or afford the expensive support systems, including chemical fertilizers. Moreover, not all types of crops have benefited equally from conservation efforts. Another tension between the world’s poor and rich nations concerns ownership of genetic diversity. The Convention on Biodiversity, signed by 167 nations in 1992, states that genetic materials are under the sovereign control of the countries in which they are found. This policy is particularly controversial regarding medicinal plants, because “biodiversity prospecting” for new drugs has economically benefited either individuals or corporations based in the developed countries. Joan C. Stevenson See also: Adaptive radiation; Clines, hybrid zones, and introgression; Convergence and divergence; Evolution: definition and theories; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Isolating mechanisms; Natural selection; Punctuated equilibrium vs. gradualism; Speciation. Sources for Further Study Hawkes, John G. The Diversity of Crop Plants. Cambridge, Mass.: Harvard University Press, 1983. Fundamentals of Conservation Biology. Cambridge, Mass.: Blackwell Science, 1996. Krattiger, Anatole F., et al., eds. Widening Perspectives on Biodiversity. Geneva, Switzerland: International Academy of the Environment, 1994. Orians, Gordon H., et al., eds. The Preservation and Valuation of Biological Resources. Seattle: University of Washington Press, 1990.
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GENETIC DRIFT Types of ecology: Evolutionary ecology; Population ecology Genetic drift refers to random changes in the genetic composition of a population. It is one of the evolutionary forces that cause biological evolution, the others being natural selection, mutation, and migration, or gene flow.
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rift occurs because the genetic variants, or alleles, present in a population are a random sample of the alleles that adults in the previous generation would have been predicted to pass on, where predictions are based on expected migration rates, expected mutation rates, and the direct effects of alleles on fitness. If this sample is small, then the genetic composition of the offspring population may deviate substantially from expectation, just by chance. This deviation is called genetic drift. Drift becomes increasingly important as population size decreases. The key feature of drift that distinguishes it from the other evolutionary forces is the unpredictable direction of evolutionary change. Anything that generates fitness variation among individuals (that is, variation in the ability of individuals to survive and reproduce) will increase the magnitude of drift for all genes that do not themselves cause the fitness variation. Because of their indeterminate growth, plants often vary greatly in reproductive potential because of local environmental variation, and this magnifies genetic drift. For example, the magnitude of drift in most annual plants is more than doubled by size variation among adults. This makes sense if one considers that larger individuals contribute a larger number of offspring to the next generation, so any alleles they carry will tend to be overrepresented. Fitness variation caused by selection will also increase the magnitude of drift at any gene not directly acted upon by the selection. If an individual has high fitness because it possesses one or more favorable alleles, then all other alleles it possesses will benefit. This is called genetic hitchhiking. This is a potent source of evolution because the direction of change at a hitchhiking gene will remain the same for multiple generations. However, it is not possible to predict in advance what that direction will be because where and when a favorable mutation will occur cannot be predicted. The opportunities for drift to occur are greatly influenced by gene flow. Most terrestrial plants are characterized by highly localized dispersal. Thus, even in large, continuous populations, the pool of potential mates for an individual, and the pool of seeds that compete for establishment at a 281
Genetic drift site, are all drawn from a small number of nearby individuals known as the neighborhood. If the neighborhood is sufficiently small, genetic drift will have a significant impact on its genetic composition. For these and other reasons, population size alone is not sufficient to predict the magnitude of drift. The effective size of a population, Ne , is a number that is directly related to the magnitude of drift through a simple equation. Thus, Ne incorporates all characteristics of a population that influence drift. Loss of Variability The long-term consequence of drift is a loss of genetic variation. As alleles increase and decrease in frequency at random, some will be lost. In the absence of mutation and migration, such losses are permanent. Eventually, only one allele remains at each gene, which is said to be fixed. Thus, all else being equal, smaller populations are expected to harbor less genetic variation than larger populations. An important way in which different plant populations are not equal is in their reproductive systems. With self-fertilization (selfing), or asexual reproduction, genetic hitchhiking becomes very important. In the extreme cases of 100 percent selfing or 100 percent asexual reproduction, hitchhiking will determine the fates of most alleles. Thus, as a new mutation spreads or is eliminated by selection, so too will most or all of the other alleles carried by the individual in which the mutation first arose. This is called a selective sweep, and the result is a significant reduction in genetic variation. Which alleles will be swept to fixation or elimination cannot be predicted in advance, so the loss of variation reflects a small Ne. Consistent with this expectation, most populations of flowering plants that reproduce partly or entirely by selfing contain significantly less genetic variation than populations of related species that do not self-fertilize. Extinction Mutations that decrease fitness greatly outnumber mutations that increase fitness. In a large population in which drift is weak, selection prevents most such mutations from becoming common. In very small populations, however, alleles that decrease fitness can drift to fixation, causing a decrease in average fitness. This is one manifestation of a phenomenon called inbreeding depression. In populations with very small Ne , this inbreeding depression can be significant enough to threaten the population with extinction. If a population remains small for many generations, mean fitness will continue to decline as new mutations become fixed by drift. When fitness declines to the point where offspring are no longer overproduced, 282
Genetic drift population size will decrease further. Drift then becomes stronger, mutations are fixed faster, and the population heads down an accelerating trajectory toward extinction. This is called mutational meltdown. Creative Potential By itself, drift cannot lead to adaptation. However, drift can enhance the ability of selection to do so. Because of diploidy and sexual recombination, some types of mutations, either singly or in combinations, will increase fitness when common but not when rare. Genetic drift can cause such genetic variants to become sufficiently common for selection to promote their fixation. A likely example is the fixation of new structural arrangements of chromosomes that occurred frequently during the diversification of flowering plants. New chromosome arrangements are usually selected against when they are rare because they disrupt meiosis and reduce fertility. The initial spread of such a mutation can therefore only be caused by strong genetic drift, either in an isolated population of small effective size or in a larger population divided into small neighborhoods. John S. Heywood See also: Biodiversity; Clines, hybrid zones, and introgression; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Population genetics; Punctuated equilibrium vs. gradualism; Speciation. Sources for Further Study Denny, Mark, and Steven Gaines. Chance in Biology: Using Probability to Explore Nature. Princeton, N.J.: Princeton University Press, 2000. Futuyma, Douglas J. Evolutionary Biology. 3d ed. Sunderland, Mass.: Sinauer Associates, 1998.
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GENETICALLY MODIFIED FOODS Types of ecology: Agricultural ecology; Chemical ecology; Ecotoxicology; Evolutionary ecology Applications of genetic engineering in agriculture and the food industry could increase world food supplies, reduce environmental problems associated with food production, and enhance the nutritional values of certain foods. However, these benefits are countered by food-safety concerns, the potential for ecosystem disruption, and fears of unforeseen consequences resulting from altering natural selection.
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umans rely on plants and animals as food sources and have long used microbes to produce foods such as cheese, bread, and fermented beverages. Conventional techniques such as cross-hybridization, production of mutants, and selective breeding have resulted in new varieties of crop plants or improved livestock with altered genetics. However, these methods are relatively slow and labor-intensive, are generally limited to intraspecies crosses, and involve a great deal of trial and error. Transgenic Technology Recombinant DNA techniques, which manipulate cells’ deoxyribonucleic acid (DNA), were developed in the 1970’s and enabled researchers to make specific, predetermined genetic changes in a variety of organisms. Because the technology also allows for the transfer of genes across species and kingdom barriers, an infinite number of novel genetic combinations are possible. The first animals and plants containing genetic material from other organisms (transgenics) were developed in the early 1980’s. By 1985 the first field trials of plants engineered to be pest-resistant were conducted. In 1990 the U.S. Food and Drug Administration (FDA) approved chymosin as the first substance produced by modified organisms to be used in the food industry for dairy products such as cheese. That same year the first transgenic cow was developed to produce human milk proteins for infant formula. The well-publicized Flavr Savr tomato, modified to delay ripening and rotting, obtained FDA approval in 1994. Goals and Uses By the mid-1990’s, more than one thousand genetically modified crop plants were approved for field trials. The goals for altering food crop plants by genetic engineering fall into three main categories: to create 284
Genetically modified foods plants that can adapt to specific environmental conditions to make better use of agricultural land, increase yields, or reduce losses; to increase nutritional value or flavor; and to alter harvesting, transport, storage, or processing properties for the food industry. Many genetically modified crops are sources of ingredients for processed foods and animal feed. Herbicide-resistant plants, such as the Roundup Ready soybean, can be grown in the presence of glyphosphate, an herbicide that normally destroys all plants with which it comes in contact. Beans from these plants were approved for food-industry use in several countries, but there has been widespread protest by activists such as Jeremy Rifkin and environmental organizations such as Greenpeace. Frost-resistant fruit containing a fish antifreeze gene, insect-resistant plants with a bacterial gene that encodes for a pesticidal protein (Bacillus thuringiensis), and a viral disease-
Genetically Modified Crop Plants Unregulated by the U.S. Department of Agriculture Crop
Patent Holder
Genetically Engineered Trait
Canola
AgrEvo
herbicide tolerance
Corn
AgrEvo Ciba-Geigy DeKalb Monsanto Northrup King
herbicide tolerance insect resistance herbicide tolerance; insect resistance herbicide tolerance; insect resistance insect resistance
Cotton
Calgene DuPont Monsanto
herbicide tolerance; insect resistance herbicide tolerance herbicide tolerance; insect resistance
Papaya
Cornell
virus resistance
Potato
Monsanto
insect resistance
Squash
Asgrow Upjohn AgrEvo DuPont Monsanto
virus resistance virus resistance herbicide tolerance altered oil profile herbicide tolerance
Agritope Calgene Monsanto Zeneca
altered fruit ripening altered fruit ripening altered fruit ripening altered chemical content in fruit
Soybean
Tomato
Source: U.S. Department of Agriculture and Plant Health Inspection Service (APHIS).
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Genetically modified foods resistant squash are examples of other genetically modified food crops that have undergone field trials. Scientists have also created plants that produce healthier unsaturated fats and oils rather than saturated ones. Genetic engineering has yielded coffee plants whose beans are caffeine-free without processing and tomatoes with altered pulp content for improved canned products. Genetically modified microbes are used for the production of food additives such as amino acid supplements, sweeteners, flavors, vitamins, and thickening agents. In some cases, these substances had to be obtained from slaughtered animals. Altered organisms are also used for improving fermentation processes in the food industry. Ecological Implications Food safety and quality are at the center of the genetically modified food controversy. Concerns include the possible introduction of new toxins or allergens into the diet and changes in the nutrient composition of foods. Proponents argue that food sources could be designed to have enhanced nutritional value. A large percentage of crops worldwide are lost each year to drought, temperature extremes, and pests. Plants have already been engineered to exhibit frost, insect, disease, and drought resistance. Such alterations would increase yields and allow food to be grown in areas that are currently too dry or infertile, positively impacting the world food supply. Environmental problems such as deforestation, erosion, pollution, and loss of biodiversity have all resulted, in part, from conventional agricultural practices. Use of genetically modified crops could allow better use of existing farmland and lead to a decreased reliance on pesticides and fertilizers. However, critics fear the creation of unpredictable ecological consequences as well. For example, “superweeds”—either the engineered plants or new plant varieties formed by the transfer of recombinant genes conferring various types of resistance to wild species—might compete with valuable plants and have the potential to destroy ecosystems and farmland unless stronger poisons were used for eradication. The transfer of genetic material to wild relatives (outcrossing, or “genetic pollution”) might also lead to the development of new plant diseases. Diane White Husic See also: Biopesticides; Erosion and erosion control; Grazing and overgrazing; Integrated pest management; Multiple-use approach; Pesticides; Rangeland; Slash-and-burn agriculture; Soil; Soil contamination; Species loss. 286
Genetically modified foods Sources for Further Study American Chemical Society. Genetically Modified Foods: Safety Issues. Washington, D.C.: Author, 1995. Anderson, Luke. Genetic Engineering, Food, and Our Environment. White River Junction, Vt.: Chelsea Green, 1999. Paredes-Lopez, Octavio, ed. Molecular Biotechnology for Plant Food Production. Lancaster, Pa.: Technomic, 1999. Rissler, Jane. The Ecological Risks of Engineered Crops. Cambridge, Mass.: MIT Press, 1996. Shannon, Thomas A., ed. Genetic Engineering: A Documentary History. Westport, Conn.: Greenwood Press, 1999. Yount, Lisa. Biotechnology and Genetic Engineering. New York: Facts on File, 2000.
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GEOCHEMICAL CYCLES Types of ecology: Ecoenergetics; Ecosystem ecology; Global ecology Geochemical cycles refer to the movement, or cycling, of elements through ecosystems and the biosphere. Both biotic (living) and abiotic (nonliving) components participate in these cycles, and their interdependency means that a change in one component of such a cycle will have an impact on all other components.
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eochemical cycles are generally considered to be those involving nutrient elements utilized by organisms in various ecosystems. Cycling involves both biological and chemical processes. While nearly all natural elements could be considered as being cycled through both abiotic and living systems, certain elements are most commonly described in such systems. These include carbon, nitrogen, phosphorus, and a variety of lesser elements (including iron, sulfur, and trace elements such as copper and mercury). Although the cycling of elements is often thought of as occurring in a relatively rapid fashion, many of these elements spend long periods locked in abiotic systems. For example, carbon may be found in materials that require millions of years to cycle through ocean sediment back into the atmosphere. The fate of such elements depends on many factors, including their chemical properties and their ability to erode or return to the atmosphere. Some chemical elements, such as carbon, oxygen, and nitrogen, are incorporated into organisms from the atmosphere. Other elements, such as phosphorus, potassium, sulfur, and iron, are found mainly in rocks and sediments.
Carbon and Oxygen Cycles The carbon and oxygen cycles are greatly dependent on each other. Molecular oxygen, which represents approximately 20 percent of the atmosphere, is used by organisms through a metabolic process called respiration. In these reactions, the oxygen reacts with reduced carbon compounds such as carbohydrates (sugars) and generates carbon dioxide (CO2). Though carbon dioxide constitutes only a small proportion of the volume of the atmosphere (0.04 percent), it is in this form that it is used by primary producers such as plants. In the process of photosynthesis, utilizing sunlight as an energy source, plants and some microorganisms bind, or fix, the CO2, converting the carbon again into carbohydrates, resulting in growth of the plant, or replication of the microorganism. The complex carbohydrates which are generated in photosynthesis serve as the food source for 288
Geochemical cycles
The Carbon Cycle Carbon dioxide in the atmosphere Respiration in decomposers
Fossil fuel combustion
Plant respiration
Fossilization
Decomposition of carbon compounds in dead organic matter
Death
Animal respiration Organic compounds in animals
Photosynthesis
Feeding
Organic compounds in green plants
consumers—organisms such as animals (including humans) that eat the plants. The carbohydrates are then broken down, regenerating carbon dioxide. In a sense, the combinations of respiration and photosynthesis represent the cycle of life. Approximately 70 billion metric tons of carbon dioxide (10 percent of the total atmospheric CO2) are fixed each year. The concentration of carbon dioxide in the atmosphere is a factor in regulating the temperature of Earth. Consequently, the release of large quantities of the gas into the atmosphere through the burning of fossil fuels could potentially alter the earth’s climate. Nitrogen Cycle Nitrogen gas (N2) represents 78 percent of the total volume of the atmosphere. However, because of the extreme stability of the bond between the two nitrogens in the gas, plants and animals are unable to use atmospheric nitrogen directly as a nutrient. Nitrogen-fixing bacteria in the soil and in the roots of leguminous plants (peas, clover) are able to convert the gaseous nitrogen into nitrites and nitrates, chemical forms that can be used by plants. Animals then obtain nitrogen by consuming the plants. The decomposition of nitrogen compounds results in the accumulation of ammonium (NH4+) compounds in a process called ammonification. It is in this form that nitrogen is commonly found under conditions in which oxygen is lim289
Geochemical cycles ited. In this form, some of the nitrogen returns to the atmosphere. In the presence of oxygen, ammonium compounds are oxidized to nitrates (nitrification). Once the plant or animal has died, bacteria convert the nitrogen back into nitrogen gas, and it returns to the atmosphere. Phosphorus Cycle Unlike carbon and nitrogen, which are found in the atmosphere, most of the phosphorus required for biotic nutrition is found in mineral form. Phosphorus is relatively water insoluble in this form; it is only gradually dissolved in water. Available phosphorus is therefore often growth-limiting in soils (it is second only to nitrogen as the scarcest of the soil nutrients). Ocean sediments may bring the mineral to the surface through uplifting of land, as along coastal areas, or by means of marine animals. Enzymatic breakdown of organic phosphate by bacteria and the consumption of marine organisms by seabirds cycle the phosphorus into forms available for use by plants. Deposition of guano (bird feces) along the American Pacific coast has long provided a fertilizer rich in phosphorus. Bacteria also play significant roles in the geochemical cycling of many other elements. Iron, despite its abundance in the earth’s crust, is largely
The Phosphorus Cycle Plant tissues
Animal tissues and feces Decomposition by fungi and bacteria
Phosphates in solution
Urine
Loss in drainage
Assimilation by plant cells
Phosphates in soil Incorporation into sedimentary rock; geologic uplift moves this rock into terrestrial environments
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Weathering of rock
Geochemical cycles insoluble in water. Consequently, it is generally found in the form of pre+3 cipitates of ferric (Fe ) compounds, seen as brown deposits in water. Acids are often formed as by-products in the formation of ferric compounds. The bacterial oxidation of pyrite (FeS2) is a major factor in the leaching process of iron ores and in the formation of acid mine drainage. Likewise, much of the sulfur found in the earth’s crust is in the form of pyrite and gypsum (CaSO4 ). Weathering processes return much of the sulfur to water-soluble forms; in the absence of air, the bacterial reduction of sulfate (SO4-2) to forms such as hydrogen sulfide (H2S) allows its return to the atmosphere. Since sulfide compounds are highly toxic to many organisms, bacterial reduction of sulfates is of major biogeochemical significance. Richard Adler See also: Balance of nature; Biomass related to energy; Communities: ecosystem interactions; Communities: structure; Food chains and webs; Herbivores; Hydrologic cycle; Nutrient cycles; Omnivores; Phytoplankton; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Berner, Elizabeth K., and Robert A. Berner. Global Environment: Water, Air, and Geochemical Cycles. Upper Saddle River, N.J.: Prentice Hall, 1996. Bolin, Bert. “The Carbon Cycle.” Scientific American 223 (September, 1970). Clark, F. E., and T. Rosswall, eds. Terrestrial Nitrogen Cycles: Processes, Ecosystem Strategies, and Management Impacts. Stockholm: Swedish Natural Science Research Council, 1981. Heimann, Martin. The Global Carbon Cycle. New York: Springer-Verlag, 1993. Kasischke, Eric S., and Brian J. Stocks, eds. Fire, Climate Change, and Carbon Cycling in the Boreal Forest. New York: Springer, 2000. Discusses the direct and indirect mechanisms by which fire and climate interact to influence carbon cycling in North American boreal forests. Krebs, Charles J. Ecology: The Experimental Analysis of Distribution and Abundance. 5th ed. San Francisco: Benjamin Cummings, 2001. Lasserre, P., and J. M. Martin, eds. Biogeochemical Processes at the Land-Sea Boundary. Amsterdam, N.Y.: Elsevier, 1986. Pomeroy, Lawrence, ed. Cycles of Essential Elements. Stroudsburg, Pa.: Dowden, Hutchinson, & Ross, 1974. Tiessen, Holm, ed. Phosphorus in the Global Environment: Transfers, Cycles, and Management. New York: Wiley, 1995.
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GLOBAL WARMING Type of ecology: Global ecology Global warming is the term applied to rising global air temperatures. This rise in temperature has the potential to cause drastic changes in climate and weather patterns worldwide. Greenhouse Effect “Global warming” is the term for the rise in the earth’s average temperature. Scientists know that the earth’s average global temperature has been rising since the beginning of the Industrial Revolution in the second half of the eighteenth century. Increases in air temperature could alter precipitation patterns, change growing seasons, result in coastal flooding, and turn some areas into deserts. Scientists do not know the cause or causes of this phenomenon but believe that it could be part of a normal climate cycle or be caused by natural events or the activities of humankind. When the ground is heated by sunlight, it gives off the heat as infrared radiation. The atmosphere absorbs the infrared radiation and keeps it from escaping into space. This is called the “greenhouse effect” because it was once believed that the glass panes of greenhouses acted similarly to the atmosphere, capturing the infrared radiation given off by Earth inside the greenhouse and not allowing it to pass through. Although it has subsequently been shown that greenhouses work by simply trapping the heated air, the name has stuck. The atmosphere eventually releases its heat into space. The amount of heat stored in the atmosphere remains constant as long as the composition of gases in the atmosphere does not change. Some gases, including carbon dioxide, water vapor, and methane, store heat more efficiently than others and are called “greenhouse gases.” If the composition of the atmosphere changes to include more of these greenhouse gases, the air retains more heat, and the atmosphere becomes warmer. Global levels of greenhouse gases have been steadily increasing and in 1990 were more than 14 percent higher than they were in 1960. At the same time, the average global temperature has also been rising. Meteorological records show that from 1890 to the mid-1990’s, the average global temperature rose by between 0.4 and 0.7 degree Celsius. About 0.2 degree Celsius of this temperature increase has occurred since 1950. In comparison, the difference between the average global temperature in the 1990’s and in the last ice age is approximately 10 degrees Celsius, and it is estimated that a 292
Global warming drop of as little as 4 to 5 degrees Celsius could trigger the formation of continental glaciers. Therefore, the rise in average temperature is significant and already beginning to cause some changes in the global climate. Documented changes include the melting of glaciers and rising sea levels as the ocean gets warmer and its waters expand. Measurements of plant activity indicate that the annual growing season has become approximately two weeks longer in the middle latitude regions. Effects of Global Warming A common misunderstanding is that global warming simply means that winters will be less cold and summers will be hotter, while everything else
U.S. Greenhouse Gas Emissions, 1990-1999 Type
1990
1
Nitrous Oxide
1995
1996
1997
1998
1999
1,350.5 1,422.5 1,434.7 1,484.1 1,505.2 1,507.4 1,526.8
Carbon Dioxide (carbon)1 Methane Gas
1994
2
Chlorofluorocarbons
2
2
31.74
31.17
31.18
30.16
30.11
29.29
28.77
1,168
1,310
1,257
1,246
1,226
1,223
1,224
202
109
102
67
51
49
41
2.8
2.7
2.9
3.0
3.0
3.0
3.0
Hydrofluorocarbons HFC-23 HFC-125 HFC-134a HFC-143a
3.0 (Z) 1.0 (Z)
3.0 0.3 6.3 0.1
2.0 0.5 14.3 0.1
3.0 0.7 19.0 0.2
3.0 0.9 23.5 0.3
3.4 1.1 26.9 0.5
2.6 1.3 30.3 0.7
Perfluorocarbons2 CF-4 C-2F-6 C-4F-10
3 1 (Z)
2 — (Z)
2 1 (Z)
2 1 (Z)
2 1 (Z)
2 1 (Z)
2 1 (Z)
1
1
2
2
2
2
1
Halons
2
Sulfur hexafluoride2
Source: Abridged from U.S. Energy Information Administration, Emissions of Greenhouse Gases in the United States, annual. From Statistical Abstract of the United States: 2001 (Washington, D.C.: U.S. Census Bureau, 2001). Note: Emission estimates were mandated by Congress through Section 1605(a) of the Energy Policy Act of 1992 (Title XVI). Gases that contain carbon can be measured either in terms of the full molecular weight of the gas or just in terms of their carbon content. 1 In millions of metric tons. 2 In thousands of metric tons. Z. Less than 500 metric tons. — Represents or rounds to zero
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Global warming will be basically the same. Actually, the earth’s weather system is very complicated, and higher global temperatures will result in significant changes in weather patterns. Most changes will be observed in the middle and upper latitudes, with equatorial regions witnessing fewer changes. The areas that will experience most of the changes include North America, Europe, and most of Asia. The Southern Hemisphere will experience less severe effects because it contains more water than the Northern Hemisphere does, and it takes more energy to heat water than land. It is difficult to predict precisely what these changes will be, but observation of the changing climate and scientific studies allow researchers to make some rough estimates of the kinds of changes Earth will experience. Summers will be hotter, with more severe heat waves. Because hot air holds more moisture than cool air, rain will fall less frequently in the summer. Droughts can be expected to be more common and more severe. Through the late 1980’s and into the early 1990’s, annual temperatures climbed higher and higher, and summer heat waves became more frequent. This is a particularly troubling problem in areas where homes are typically built without air conditioning. The air in a closed-up house during a heat wave can reach temperatures well over 40 degrees Celsius. Because these temperatures exceed people’s normal body temperature, which is about 36.5 degrees Celsius, it becomes very difficult for the body to cool down. For this reason, heat waves are particularly dangerous for the very young, the elderly, and people who are ill. More frequent heat waves will cause increases in the use of air conditioning, which requires more energy and will release additional greenhouse gases. Global warming will also produce severe autumn rains. The overheated summer air will cool in the autumn and will no longer be able to hold all of the moisture it was storing. It will release the moisture as heavy rains, causing flooding. This phenomenon has already been observed, but not for a period of time that is scientifically significant. It is difficult to tell the difference between long-term changes and short-term fluctuations with only a few years of observations. These changing rain patterns—droughts and severe autumn storms— will certainly have an effect on the earth’s landscape. Some areas may be turned to deserts, and others may be transformed from plains to forests. One of the strange aspects of global warming is that it is predicted to result in not only hotter periods during the summers but also colder periods during the winter. It takes energy to move large cold-air masses from the polar regions in winter, so it is possible that large winter storms will be colder, more violent, and more frequent. This pattern has been evident since about the mid-1970’s. Winter storms have brought record low tem294
Global warming peratures and enough snow to close cities for days. However, this time span is too short to determine whether this is a temporary phenomenon or a trend. It is possible that some smaller, less permanent event than global warming is responsible for the more severe winter storms. A shorter (although more severe) winter may create a surge in pest populations and diseases that are normally controlled by long winters. Global warming will cause ocean levels to rise because water expands when heated and also because of the melting of glaciers on Greenland and Antarctica. The melting of the ice in the northern polar areas will not contribute to rising ocean levels because that ice, unlike the ice on Greenland and Antarctica, is already in the ocean. Just as the melting of the ice in a drink does not cause the level of the drink to rise, the melting of the northern oceanic ice sheets will not affect sea levels. Causes of Global Warming Although many scientists are convinced, based on the abundant evidence, that global warming is occurring, they are less sure of why. One significant factor, the rise in greenhouse gases, can be attributed to the activities of humankind. Burning forests to clear land and operating factories and automobiles produce carbon dioxide and water vapor. Livestock herds and rotting vegetation release methane, and fertilizers used on farms also release greenhouse gases. Power plants that consume fossil fuels such as coal, oil, or natural gas release massive amounts of carbon dioxide into the air. However, no one knows whether humankind’s activities are the real or only reason for the increase in global temperature. The last ice age ended very recently in geologic terms, and a number of changes are still taking place as the globe recovers from the presence of huge ice sheets. It is possible that the world’s climate is still warming up from the last ice age. Volcanoes are another major source of greenhouse gases, and the level of volcanic activity has been increasing since approximately the beginning of the Industrial Revolution. Global warming could also be part of a natural cyclical change in the climate. Evidence indicates that the earth’s climate varies between warmer and colder periods that last a few centuries. History provides many stories of dramatically changing climate, including one period from 1617 to 1650 that was so unusually cold that it is called the “Little Ice Age.” Therefore, Earth may be merely experiencing another cyclical change in its climate. Study of Global Warming The problem with studying global warming is that no one can be sure of its extent, and some scientists debate whether it actually exists. They argue 295
Global warming that the observed changes may only be a warm phase of a climatic cycle that will make the earth warmer for a few years, then cooler for a few years. If this is true, then the coming decades may see average temperatures leveling off or even dropping. A major source of the confusion involves the way global warming is studied. It would seem easy to record temperatures for a number of years and then compare them. However, detailed records on the weather have not been kept for more than a few decades in many areas. Scientists are forced to rely on interpretations of historical accounts and the clues left in fossil records. The analysis of tree rings, sedimentary deposits, and even very old ice from deep within glaciers can provide data about the climate in the past. In addition, the existing records must be reviewed carefully to identify local changes that may not reflect global ones. For example, as towns grow into cities, the temperature climbs simply because larger cities are warmer than smaller ones, a phenomenon known as the urban heat island effect. Measurements taken years ago in a more rural environment should be lower than those taken after the population around the measuring station increased. This problem can be overcome with balloons. By sending instruments high in the atmosphere on weather balloons, air temperatures can be measured without being affected by urbanization. Although data recorded this way show a consistent rise in global temperature, again such measurements go back only a few decades. Measurements of the level of greenhouse gases in the atmosphere are also affected by urbanization. As a small town becomes a city, levels can be expected to rise. However, recording stations located in regions far removed from cities and factories also show an increase in the level of greenhouse gases. One station on the island of Hawaii has shown a rise in the amount of carbon dioxide present in the air since early 1958, with similar reports coming from stations in Point Barrow, Alaska, and Antarctica. Another important variable in looking at global warming is sea surface temperature. Measurements can be skewed by local effects that have no impact on the global climate. One method used to make detailed measurements of seawater temperature is to broadcast a particular frequency of noise through the water and measure it at distant locations. The speed and frequency of the sound are affected by the temperature of the water. However, more accurate and more global data are becoming available through observations made from satellites placed in geosynchronous orbits, which can take a variety of detailed measurements of many conditions that are factors in global warming. These data will help immensely in enabling scientists to understand the global climate and the changes it is undergoing. Christopher Keating 296
Global warming See also: Biodiversity; Biomes: determinants; Biomes: types; Biosphere concept; Ecosystems: definition and history; Ecosystems: studies; Geochemical cycles; Greenhouse effect; Hydrologic cycle; Nutrient cycles; Ozone depletion and ozone holes; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Abrahamson, Dean Edwin, ed. The Challenge of Global Warming. Washington, D.C.: Island Press, 1989. Berger, John J. Beating the Heat: Why and How We Must Combat Global Warming. Berkeley, Calif.: Berkeley Hills Books, 2000. Gates, David M. Climate Change and Its Biological Consequences. Sunderland, Mass.: Sinauer Associates, 1993. Houghton, John T. Global Warming: The Complete Briefing. 2d ed. New York: Cambridge University Press, 1997. Nance, John J. What Goes Up: The Global Assault on Our Atmosphere. New York: William Morrow, 1991. Rosenzweig, Cynthia. Climate Change and the Global Harvest: Potential Impacts of the Greenhouse Effect on Agriculture. New York: Oxford University Press, 1998. Sommerville, Richard C. J. The Forgiving Air: Understanding Environmental Change. Berkeley: University of California Press, 1996. Wyman, Richard L., ed. Global Climate Change and Life on Earth. New York: Chapman and Hall, 1991.
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GRASSLANDS AND PRAIRIES Types of ecology: Biomes; Ecosystem ecology Grasslands, including the prairies of North America, are a biome characterized by the presence of low plants, mostly grasses, and are distinguished from woodlands, deserts, and tundra. They support a great variety of plants and animals. At present, the remaining grasslands provide grazing for livestock and wildlife.
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rasslands occupied vast areas of the world more than ten thousand years ago, before the development of agriculture, industrialization, and the subsequent explosive growth of the human population. They are characterized by the presence of low plants (mostly grasses), experience sparse to moderate rainfall, and are found in both temperate and tropical climatic zones. The main grasslands of the planet include the prairies of North America, the pampas of South America, the steppes of Eurasia, and the savannas of Africa. Grasslands are intermediate between deserts and woodlands in terms of precipitation and biomass. The warmer tropical savannas average 60 to 150 centimeters (25 to 60 inches) of rain. The temperate grasslands range between twenty-five to seventy-five centimeters (ten to thirty inches) of precipitation, some of which may be in the form of snow. The biomass of grasslands, predominantly grasses, is quantitatively intermediate between that of deserts and woodlands, which produce 10 to 15 percent and 200 to 300 percent, respectively, of the amount of plant material. It should be recognized that the grassland biomes can be subdivided in terms of climate, plant species, and animal species. It should also be noted that grasslands do not always shift abruptly to deserts or woodlands, leading to gradations between them. In addition, grasslands do have scattered trees, often along streams or lakes, and low-lying brush. Grasses have extensive root systems and the ability to become dormant. These permit them to survive low rainfall, including periodic droughts, or the winter cold typical of temperate regions. Furthermore, grasslands have always been subjected to periodic fires, but the deep root systems of grassland plants also permit them to regrow after fire. Grasses coevolved over millions of years with the grazing animals that depend on them for food. Ten thousand years ago, wild ancestors of cattle and horses, as well as antelope and deer, were on the Eurasian steppes; bison and pronghorn prospered on the North American prairies; wildebeest, gazelle, zebra, and buffalo dominated African savannas; and the kangaroo was the predominant 298
Grasslands and prairies grazer in Australia. Grazing is a symbiotic relationship, whereby animals gain their nourishment from plants, which in turn benefit from the activity. It removes vegetative matter, which is necessary in order for grasses to grow, facilitates seed dispersal, and disrupts mature plants, permitting young plants to take hold. Urine and feces from grazing animals recycle nutrients to the plants. The grassland ecosystem also includes other animals, including worms, insects, birds, reptiles, rodents, and predators. The grasses, grazing animals, and grassland carnivores, such as wolves or large cat species, constitute a food chain. Humans have been an increasing presence in grassland areas, where more than 90 percent of contemporary crop production now occurs and much urbanization and industrialization have taken place. Remaining grassland areas are not used for crops, habitation, or industry because of inadequate water supplies or unsuitable terrain but instead are used for grazing domesticated or wild herbivores. In addition, many woodland areas around the world have been cleared and converted to grasslands for crops, livestock, living, or working. The Prairies of North America Originally stretching east from the Rocky Mountains to Indiana and Ohio, and from Alberta, Canada to Texas, the prairies were the major grassland of North America. The short-grass prairie extended about 200 miles (300 kilometers) east of the mountains, and the long-grass prairie bordered the deciduous forest along the eastern edge, while the mixed-grass prairie was between the two. Going from west to east, the amount of precipitation increases, causing changes in plant populations. The short-grass prairie receives only about 25 centimeters (10 inches) of precipitation each year, mostly as summer rain, and, as its name suggests, has short grass, less than 60 centimeters (2 feet) tall. Today, it is used primarily for grazing because the soil is shallow and unsuited for farming without irrigation. The mixedgrass prairie receives moderate precipitation, ranging from 35 to 60 centimeters (14 to 24 inches) and has medium-height grasses, ranging from 60 to 120 centimeters (2 to 4 feet) tall. Much of it is now used for growing wheat. The tall-grass prairie receives more than 60 centimeters (24 inches) of precipitation, mostly in the summer, and had grasses that grow to over 150 centimeters (5 feet) tall. It has rich soil and has been mostly converted to very productive cropland, primarily for corn and soybeans. The prairies experience very cold winters (down to -45 degrees Celsius, -50 degrees Fahrenheit) and very hot summers (up to 45 degrees Celsius, 110 degrees Fahrenheit). They are often windy and experience severe storms, blizzards in winter, thunderstorms and tornadoes in summer. 299
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Grasses have extensive root systems and the ability to become dormant, permitting them to survive the low to moderate rainfall that characterizes regions on the dry sides of mountain ranges. The grassland ecosystem includes native grazers such as bison or, more often today, domesticated grazers such as cattle, as well as worms, insects, birds, reptiles, rodents, and predators such as wolves or large cats. (PhotoDisc)
Like other biomes, the prairies have a characteristic assortment of animals, herbivores that eat the plants and carnivores that prey on the herbivores. Before 1500 c.e., two ruminants, the bison (commonly but inaccurately called buffalo) and the pronghorn (not a true antelope), were the major grazers on the prairies. The prairie dog, a herbivorous rodent that burrows, lived in large communities on the prairies. The major predators were the wolf and coyote for bison and pronghorn, and the black-footed ferret and fox for prairie dogs. A variety of birds (herbivorous and carnivorous), reptiles, and insects also made their home on the prairie. Overgrazing Grasslands While grazing is of mutual benefit to plant and animal, overgrazing is ultimately detrimental to both the plant and animal populations, as well as the environment. Continued heavy grazing leads to deleterious consequences. Removal of leaf tips, even repeated, will not affect regeneration of grasses provided that the basal zone of the plant remains intact. While the upper half of the grass shoot can generally be eaten without deleterious consequences, ingesting the lower half, which sustains the roots and fuels regrowth, will eventually kill the plants. Overgrazing leads to denuding 300
Grasslands and prairies the land, to invasion by less nutritious plant species, to erosion due to decreased absorption of rainwater, and to starvation of the animal species. Because the loss of plant cover changes the reflectance of the land, climate changes can follow and make it virtually impossible for plants to return, with desertification an ultimate consequence. It is not just the number of animals, but the timing of the grazing that can be detrimental. Grasses require time to regenerate, and continuous grazing will inevitably kill them. Consumption too early in the spring can stunt their development. Semiarid regions are particularly prone to overgrazing because of low and often unpredictable rainfall; regrettably, these are the areas of the world where much grazing has been relegated, because the moister grassland areas have been converted to cropland. Overgrazing has contributed to environmental devastation worldwide. Excessive grazing by cattle, sheep, goats, and camels is partly responsible for the desert of the Middle East, ironically the site of domestication for many animals and plants. Uncontrolled livestock grazing in the late 1800’s and early 1900’s negatively affected many areas of the American West, where sagebrush and juniper trees have invaded the grasslands. Livestock overgrazing has similarly devastated areas of Africa and Asia. In the early twenty-first century, feral horses in the American West and the Australian outback are damaging those environments. Overgrazing by wildlife can also be deleterious. The 1924 Kaibab Plateau deer disaster in the Grand Canyon National Park and Game Preserve is one such example, where removal of natural predators led to overpopulation, overgrazing, starvation, and large die-offs. Riparian zones, the strips of land on either side of a river or stream, are particularly susceptible to overgrazing. Because animals naturally congregate in these areas with water, lush vegetation, and shade, they can seriously damage them by preventing grasses from regrowing and young trees from taking root, as well as trampling and compacting the soil and fouling the water course. The ecosystem can be devastated, threatening survival of plant and animal species and leading to serious erosion. While herding and fencing can be used to control animals in these areas, a less expensive method is to disperse the location of water supplies and salt blocks to encourage movement away from rivers or streams. Grassland animals crave salt, and if deprived of it, will seek it out. Grassland Management Grassland areas need not deteriorate if properly managed, whether for livestock, wildlife, or both. Managing grasslands involves controlling the number of animals and enhancing their habitat. Carrying capacity, which is the number of healthy animals that can be grazed indefinitely on a given 301
Grasslands and prairies unit of land, must not be exceeded. Because of year-to-year changes in weather conditions and hence food availability, determining carrying capacity is not simple; worst-case estimates are preferred in order to minimize the chances of exceeding it. The goal should be a healthy grassland achieved by optimizing, not maximizing, the number of animals. For private land, optimizing livestock numbers is in the long-term interest of the landowner, although not always seen as such. For land that is publicly held, managed in common, or with unclear or disputed ownership, restricting animals to the optimum level is particularly difficult to achieve. Personal short-term benefit often leads to long-term disaster, described as the “tragedy of the commons” by biologist Garrett Hardin. Appropriate management of grasslands involves controlling animal numbers and enhancing grassland plants. Restricting cattle and sheep is physically easy through herding and fencing, although it can be politically difficult and expensive. Much more problematic is controlling charismatic feral animals, such as horses, or wildlife, when natural predators have been eliminated and hunting is severely restricted. As for habitat improvement, the use of chemical, fire, mechanical, and biological approaches can increase carrying capacity for either domesticated or wild herbivores. Removing woody vegetation by burning or mechanical means will increase grass cover, fertilizing can stimulate grass growth, and reseeding with desirable species can enhance the habitat. Plants native to a particular region can be best for preserving that environment. Effective grassland management requires matching animals with the grasses on which they graze. James L. Robinson See also: Biomes: determinants; Biomes: types; Chaparral; Deserts; Forests; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes; Wetlands. Sources for Further Study Brown, Lauren. The Audubon Society Nature Guides: Grasslands. New York: Knopf, 1985. Collinson, Alan. Grasslands. New York: Dillon Press, 1992. Demarais, Stephen, and Paul R. Krausman, eds. Ecology and Management of Large Mammals in North America. Upper Saddle River, N.J.: Prentice Hall, 2000. Humphreys, L. R. The Evolving Science of Grassland Improvement. New York: Cambridge University Press, 1997. 302
Grasslands and prairies Joern, Anthony, and Kathleen H. Keeler, eds. The Changing Prairie. New York: Oxford University Press, 1995. Pearson, C. J., and R. L. Ison. Agronomy of Grassland Systems. 2d ed. New York: Cambridge University Press, 1997. Sampson, Fred B., and Fritz L. Knopf, eds. Prairie Conservation. Washington, D.C.: Island Press, 1996. Steele, Philip. Grasslands. Minneapolis: Carolrhoda Books, 1997.
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GRAZING AND OVERGRAZING Types of ecology: Agricultural ecology; Restoration and conservation ecology Animals that eat grass, or graze, can actually help the earth produce richer land cover and soil. When the land suffers ill effects because of too much grazing, overgrazing has occurred.
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he effects of overgrazing occur where there are more grazing animals than the land and vegetation can support. Overgrazing has negatively affected regions of the United States, primarily in the Southwest. Areas that have been severely damaged by overgrazing typically show declining or endangered plant and animal species. Herbivores are animals that feed on plant material, and grazers are herbivores that feed specifically on grass. Examples are horses, cows, antelope, rabbits, and grasshoppers. Overgrazing occurs when grazer populations exceed the carrying capacity of a specified area (the number of individual organisms the resources of a given area can support). In overgrazing conditions, there is insufficient food to support the animal population in question. Depending on the grazer’s strategy, emigration or starvation will follow. Grasslands can handle, and even benefit from, normal grazing; only overgrazing adversely affects them. Grasses’ Defenses Against Grazing Grasslands and grazers coevolved, so grasses can withstand grazing within the ecosystem’s carrying capacity. All plants have a site of new cell growth called the meristem, where growth in height and girth occurs. Most plants have the meristem at the very top of the plant (the apical meristem). If a plant’s apical meristem is removed, the plant dies. If grasses had an apical meristem, grazers—and lawn mowers—would kill grasses. Grasses survive mowing and grazing because the meristem is located at the junction of the shoot and root, close to the ground. With the exception of sheep, grazers in North America do not disturb the meristem, and sheep do so only during overgrazing conditions. At proper levels of grazing, grazing actually stimulates grass to grow in height in an attempt to produce a flowering head for reproduction. Grazing also stimulates grass growth by removing older plant tissue at the top that is functioning at a lower photosynthetic rate. 304
Grazing and overgrazing Grazers Mammalian grazers have high, crowned teeth with a great area for grinding to facilitate opening of plants’ cell walls as a means to release nutrients. The cell wall is composed of cellulose, which is very difficult for grazers to digest. Two major digestive systems of grazing strategies have evolved to accommodate grazing. Ruminants, such as cows and sheep, evolved stomachs with four chambers to allow regurgitation in order to chew food twice to maximize cellulose breakdown. Intestinal bacteria digest the cellulose, releasing fatty acids that nourish the ruminants. Other grazers, such as rabbits and horses, house bacteria in the cecum, a pouch at the junction of the small and large intestines. These bacteria ferment the plant material ingested. The fermented products of the bacteria nourish these grazers. Impacts in the Southwest As previously mentioned, in the United States the negative effects of overgrazing are most intense in the Southwest. Some ecologists believe that one significant factor was the pattern of early European colonization of the area. Missions were abundant in the Southwest, and the missions owned
Grazers such as sheep form a symbiotic relationship with the grasses, getting their nourishment from these plants and in turn facilitating growth of new grass by removing excess vegetative matter, dispersing seed through their droppings, and recycling nutrients via urine and feces. Overgrazing occurs when the number of grazers exceeds the carrying capacity of the grassland. (PhotoDisc) 305
Grazing and overgrazing cattle that were rarely slaughtered, except on big feast days. Because Catholic missionaries received some financial support from their religious orders in Europe, mission cattle were not restrained as strictly as were those owned by cattle ranchers, whose sole livelihood came from raising and selling cattle. Mission cattle roamed greater distances and began the pattern of overgrazing in the Southwest. The impact of overgrazing was particularly intense because much of the Southwest has desertlike conditions. Extreme environmental conditions result in particularly fragile ecosystems. Hence the Southwest was, and is, vulnerable to the effects of overgrazing. Another possible—though disputed—contribution to overgrazing may stem from the fact that much of the land in the Southwest is public land under jurisdiction of the Bureau of Land Management. This federal agency leases land to private concerns for the purpose of grazing cattle or sheep. Some observers feel that the bureau has a conflict of interest in that its primary source of income is money obtained from leasing public land under its jurisdiction. They suspect that the bureau has granted, and fear that it may continue to grant, grazing leases in regions threatened with or suffering from overgrazing. Effects of Overgrazing Overgrazing can lead to a number of ecological problems. Depletion of land cover leads to soil erosion and can ultimately cause desertification. Other possible results are the endangering of some species of grass and the creation of monocultures in regions where certain species have been removed. Desertification is the intensification and expansion of deserts at the expense of neighboring grasslands. When overgrazing occurs along desert perimeters, plant removal leads to decreased shading. Decreased shading increases the local air temperature. When the temperature increases, the air may no longer cool enough to release moisture in the form of dew. Dew is the primary source of precipitation in deserts, so without it, desert conditions intensify. Even a slight decrease in desert precipitation is serious. The result is hotter and drier conditions, which lead to further plant loss and potentially to monocultures. Overgrazing of grasslands, combined with the existence of nonnative species in an ecosystem, can result in the endangerment of species of native grasses. At one time, cattle in the Southwest fed exclusively on native grasses. Then nonnative plant species arrived in the New World in the guts of cows shipped from Europe. They began to compete with the native grasses. European grass species have seeds with prickles and burs; southwestern native grasses do not, making them softer and more desirable to 306
Grazing and overgrazing the cattle. Hence European grasses experienced little, if any, grazing, while the much more palatable southwestern native grasses were grazed to the point of overgrazing. The result was drastic decline or loss of native grassland species. In such cases animals dependent on native grassland species must emigrate or risk extinction. For example, many ecologists conjecture that the Coachella Valley kit fox in California is threatened because of the loss of grassland habitat upon which it is dependent. Solutions Desertification is usually considered irreversible, but the elimination of grazing along desert perimeters can help to prevent further desertification. One kind of attempt to reestablish native grass species involves controlledburn programs. Nonnative grassland species do not appear to be as fireresistant as native grass species. Controlled burn programs are therefore being used in some overgrazed grassland areas to try to eliminate nonnatives and reestablish native grass species. If successful, such programs will improve the health of the ecosystem. Jessica O. Ellison See also: Biopesticides; Desertification; Erosion and erosion control; Forest fires; Forest management; Forests; Genetically modified foods; Grazing and overgrazing; Integrated pest management; Multiple-use approach; Pesticides; Rangeland; Slash-and-burn agriculture; Soil; Soil contamination; Wildlife management. Sources for Further Study Hodgson, J., and A. W. Illius, eds. The Ecology and Management of Grazing Systems. Wallingford, Oxon, England: CAB International, 1996. McBrien, Heather, et al. “A Case of Insect Grazing Affecting Plant Succession.” Ecology 64, no. 5 (1983). Sousa, Wayne P. “The Role of Disturbance in Natural Communities.” Annual Review Ecological Systems 15, 1984. _______. “Some Basic Principles of Grassland Fire Management.” Environmental Management 3, no. 1 (1979). WallisDeVries, Michiel F., Jan P. Bakker, Sipke E. Van Wieren, eds. Grazing and Conservation Management. Boston: Kluwer Academic, 1998.
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GREENHOUSE EFFECT Type of ecology: Global ecology The greenhouse effect is a natural process of atmospheric warming in which solar energy that has been absorbed by the earth’s surface is reradiated and then absorbed by particular atmospheric gases, primarily carbon dioxide and water vapor. Without this warming process, the atmosphere would be too cold to support life. Since 1880, however, the surface atmospheric temperature has been rising, paralleling a rise in the concentration of carbon dioxide and other gases produced by human activities.
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ince 1880, carbon dioxide, along with several other gases—chlorofluorocarbons (CFCs), methane, hydrofluorocarbons (HFCs), perfluourocarbons (PFCs), sulfur hexafluoride, and nitrous oxide—have been increasing in concentration and have been identified as likely contributors to a rise in global surface temperature. These gases are called greenhouse gases. The temperature increase may lead to drastic changes in climate and food production as well as widespread coastal flooding. As a result, many scientists, organizations, and governments have called for curbs on the production of greenhouse gases. Since the predictions are not definite, however, debate continues about the costs of reducing the production of these gases without being sure of the benefits. Global Warming The greenhouse effect occurs because the gases in the atmosphere are able to absorb only particular wavelengths of energy. The atmosphere is largely transparent to short-wave solar radiation, so sunlight basically passes through the atmosphere to the earth’s surface. Some is reflected or absorbed by clouds, some is reflected from the earth’s surface, and some is absorbed by dust or the earth’s surface. Only small amounts are actually absorbed by the atmosphere. Therefore, sunlight contributes very little to the direct heating of the atmosphere. On the other hand, the greenhouse gases are able to absorb long-wave, or infrared, radiation from the earth, thereby heating the earth’s atmosphere. Discussion of the greenhouse effect has been confused by terms that are imprecise and even inaccurate. For example, the atmosphere was believed to operate in a manner similar to a greenhouse, whose glass would let visible solar energy in but would also be a barrier preventing the heat energy from escaping. In actuality, the reason that the air remains warmer inside a greenhouse is probably because the glass prevents the warm air from mixing with the cooler outside air. Therefore the greenhouse effect could be 308
Greenhouse effect more accurately called the “atmospheric effect,” but the term greenhouse effect continues to be used. Even though the greenhouse effect is necessary for life on earth, the term gained harmful connotations with the discovery of apparently increasing atmospheric temperatures and growing concentrations of greenhouse gases. The concern, however, is not with the greenhouse effect itself but rather with the intensification or enhancement of the greenhouse effect, presumably caused by increases in the level of gases in the atmosphere resulting from human activity, especially industrialization. Thus the term global warming is a more precise description of this presumed phenomenon.
The Greenhouse Effect
Sun Earth
Atmosphere
Clouds and atmospheric gases such as water vapor, carbon dioxide, methane, and nitrous oxide absorb part of the infrared radiation emitted by the earth’s surface and reradiate part of it back to the earth. This process effectively reduces the amount of energy escaping into space and is popularly called the “greenhouse effect” because of its role in warming the lower atmosphere. The greenhouse effect has drawn worldwide attention because increasing concentrations of carbon dioxide from the burning of fossil fuels may result in a global warming of the atmosphere. Scientists know that the greenhouse analogy is incorrect. A greenhouse traps warm air within a glass building where it cannot mix with cooler air outside. In a real greenhouse, the trapping of air is more important in maintaining the temperature than is the trapping of infrared energy. In the atmosphere, air is free to mix and move about.
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Greenhouse effect Human Contributions A variety of human activities appear to have contributed to global warming. Large areas of natural vegetation and forests have been cleared for agriculture. The crops may not be as efficient in absorbing carbon dioxide as the natural vegetation they replaced. Increased numbers of livestock have led to growing levels of methane. Several gases that appear to be intensifying global warming, including CFCs and nitrous oxides, also appear to be involved with ozone depletion. Stratospheric ozone shields the earth from solar ultraviolet (short-wave) radiation; therefore, if the concentration of these ozone-depleting gases continues to increase and the ozone shield is depleted, the amount of solar radiation reaching the earth’s surface should increase. Thus, more solar energy would be intercepted by the earth’s surface to be reradiated as long-wave radiation, which would presumably increase the temperature of the atmosphere. However, whether there is a direct cause-and-effect relationship between increases in carbon dioxide and the other gases and surface temperature may be impossible to determine because the atmosphere’s temperature has fluctuated widely over millions of years. Over the past 800,000 years, the earth has had several long periods of cold temperatures—during which thick ice sheets covered large portions of the earth—interspersed with shorter warm periods. Since the most recent retreat of the glaciers around 10,000 years ago, the earth has been relatively warm. Problems of Prediction How much the temperature of the earth might rise is not clear. So far, the temperature increase of around 1 degree Fahrenheit is within the range of normal (historic) trends. The possibility of global warming became a serious issue during the late twentieth century because the decades of the 1980’s and the 1990’s included some of the hottest years recorded for more than a century. On the other hand, warming has not been consistent since 1880, and for many years cooling occurred. The cooling might have resulted from the increase of another product of fossil fuel combustion, sulfur dioxide aerosols, which reflect sunlight, thus lessening the amount of solar energy entering the atmosphere. Similarly, in the early 1990’s temperatures declined, perhaps because of ash and sulfur dioxide produced by large volcanic explosions during that period. In the late 1990’s and early 2000’s temperatures appeared to be rising again, thus indicating that products of volcanic explosions may have masked the process of global warming. The United States Environmental Protection Agency (EPA) states that the earth’s average temperature will probably continue to increase because the greenhouse gases stay in the atmosphere longer than the aerosols. 310
Greenhouse effect Proper analysis of global warming is dependent on the collection of accurate temperature records from many locations around the world and over many years. Because human error is always possible, “official” temperature data may not be accurate. This possibility of inaccuracy compromises examination of past trends and predictions for the future. However, the use of satellites to monitor temperatures has probably increased the reliability of the data. Predictions for the future are hampered in various ways, including lack of knowledge about all the components affecting atmospheric temperature. Therefore, computer programs cannot be sufficiently precise to make accurate predictions. A prime example is the relationship between ocean temperature and the atmosphere. As the temperature of the atmosphere increases, the oceans would absorb much of that heat. Therefore, the atmosphere might not warm as quickly as predicted. However, the carbon dioxide absorption capacity of oceans declines with temperature. Therefore, the oceans would be unable to absorb as much carbon dioxide as before, but exactly how much is unknown. Increased ocean temperatures might also lead to more plant growth, including phytoplankton. These plants would probably absorb carbon dioxide through photosynthesis. A warmer atmosphere could hold more water vapor, resulting in the potential for more clouds and more precipitation. Whether that precipitation would fall as snow or rain and where it would fall could also affect air temperatures. Air temperature could lower as more clouds might reflect more sunlight, or more clouds might absorb more infrared radiation. To complicate matters, any change in temperature would probably not be uniform over the globe. Because land heats up more quickly than water, the Northern Hemisphere, with its much larger landmasses, would probably have greater temperature increases than the Southern Hemisphere. Similarly, ocean currents might change in both direction and temperature. These changes would affect air temperatures as well. In reflection of these complications, computer models of temperature change range widely in their estimates. Predicted increases range from 1.5 to 11 degrees Celsius (3 to 20 degrees Fahrenheit) over the early decades of the twenty-first century. Mitigation Attempts International conferences have been held, and international organizations have been established to research and minimize potential detriments of global warming. In 1988 the United Nations Environment Programme and the World Meteorological Organization established the International Panel on Climate Change (IPCC). The IPCC has conducted much research on cli311
Greenhouse effect mate change and is now considered an official advisory body on the climate change issue. In June, 1992, the United Nations Conference on Environment and Development, or Earth Summit, was held in Brazil. Participants devised the Framework Convention on Climate Change and considered the landmark international treaty. It required signatories to reduce and monitor their greenhouse gas emissions. A more advanced agreement, the Kyoto Accords, was developed in December, 1997, by the United Nations Framework Convention on Climate Change. It set binding emission levels for all six greenhouse gases over a five-year period for the developed world. Developing countries do not have any emission targets. It also allows afforestation to be used to offset emissions targets. The Kyoto agreement includes the economic incentive of trading emissions targets. Some countries, because they have met their targets, would have excess permits, which they might be willing to sell to other countries that have not met their targets. Margaret F. Boorstein See also: Biodiversity; Biomes: determinants; Biomes: types; Biosphere concept; Geochemical cycles; Global warming; Hydrologic cycle; Ozone depletion and ozone holes; Rain forests and the atmosphere. Sources for Further Study Berger, John J. Beating the Heat: Why and How We Must Combat Global Warming. Berkeley, Calif.: Berkeley Hills Books, 2000. Flavin, Christopher, Odil Tunali, and Jane A. Peterson, et al., eds. Climate of Hope: New Strategies for Stabilizing the World’s Atmosphere. Washington, D.C.: Worldwatch Institute, 1996. Graedel, Thomas E. Atmosphere, Climate, and Change. New York: Scientific American Library/W. H. Freeman, 1997. Houghton, John T. Global Warming: The Complete Briefing. 2d ed. New York: Cambridge University Press, 1997. Kondratsev, Kirill, and Arthur P. Cracknell. Observing Global Climate Change. London: Taylor and Francis, 1998. McKibben, Bill. The End of Nature. 10th anniversary ed. New York: Anchor Books, 1999. Rosenzweig, Cynthia. Climate Change and the Global Harvest: Potential Impacts of the Greenhouse Effect on Agriculture. New York: Oxford University Press, 1998. Sommerville, Richard C. J. The Forgiving Air: Understanding Environmental Change. Berkeley: University of California Press, 1996.
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HABITATS AND BIOMES Types of ecology: Biomes; Ecosystem ecology The biosphere is the sum total of all habitats on earth that can be occupied by living organisms. Descriptive and experimental studies of habitat components allow scientists to predict how various organisms will respond to changes in their environment, whether caused by humans or nature.
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ife in the form of individual organisms composed of one or more living cells is found in a vast array of different places on earth, each with its own distinctive types of organisms. Life on earth has been classified by scientists into units called species, whose individuals appear similar, have the same role in the environment, and breed only among themselves. The space in which each species lives is called its habitat. Habitats, Communities, Ecosystems, and Biomes The term “habitat” can refer to specific places with varying degrees of accuracy. For example, rainbow trout can be found in North America from Canada to Mexico, but more specifically they are found in freshwater streams and lakes, with an average temperature below 70 degrees Fahrenheit and a large oxygen supply. The former example describes the macrohabitat of the rainbow trout, which is a broad, easily recognized area. The latter example describes its microhabitat—the specific part of its macrohabitat in which it is found. Similarly, the macrohabitat of one species can refer to small or large areas of its habitat. The macrohabitat of rainbow trout may refer to the habitat of a local population, the entire range of the species, or (most often) an area intermediate to those extremes. While “habitat,” therefore, refers to the place an organism lives, it is not a precise term unless a well-defined microhabitat is intended. The total population of each species has one or more local populations, which are all the individuals in a specific geographic area that share a common gene pool; that is, they commonly interbreed. For example, rainbow trout of two adjacent states will not normally interbreed unless they are part of local populations that are very close to each other. The entire geographic distribution of a species, its range, may be composed of many local populations. On a larger organizational scale, there is more than only one local population of one species in any habitat. Indeed, it is natural and necessary for many species to live together in an area, each with its own micro- and 313
Habitats and biomes macrohabitat. The habitat of each local population of each species overlaps the habitat of many others. This collective association of populations in one general area is termed a community, which may consist of thousands of species of animals, plants, fungi, bacteria, and other one-celled organisms. Groups of communities that are relatively self-sufficient in terms of both recycling nutrients and the flow of energy among them are called ecosystems. An example of an ecosystem could be a broad region of forest community interspersed with meadows and stream communities that share a common geographic area. Some ecosystems are widely distributed across the surface of the earth and are easily recognizable as similar ecosystems known as biomes—deserts, for example. Biomes are usually named for the dominant plant types, which have very similar shapes and macrohabitats. Thus, similar types of organisms inhabit them, though not necessarily ones of the same species. These biomes are easily mapped on the continental scale and represent a broad approach to the distribution of organisms on the face of the earth. One of the more consistent biomes is the northern coniferous forest, which stretches across Canada and northern Eurasia in a latitudinal belt. Here are found needle-leafed evergreen conifer trees adapted to dry, cold, windy conditions in which the soil is frozen during the long winter. North American Biomes The biomes of North America, from north to south, are the polar ice cap, the Arctic tundra, the northern coniferous forest; then, at similar middle latitudes, eastern deciduous forest, prairie grassland, or desert; and last, subtropical rain forest near the equator. Complicating factors that determine the actual distribution of the biomes are altitude, annual rainfall, topography, and major weather patterns. These latter factors, which influence the survival of the living, or biotic, parts of the biome, are called abiotic factors. These are the physical components of the environment for a community of organisms. The polar ice cap is a hostile place with little evidence of life on the surface except for polar bears and sea mammals that depend on marine animals for food. A distinctive characteristic of the Arctic tundra, just south of the polar ice cap, is its flat topography and permafrost, or permanently frozen soil. Only the top meter or so thaws during the brief Arctic summer to support low-growing mosses, grasses, and the dominant lichens known as reindeer moss. Well-known animals found there are the caribou, muskox, lemming, snowy owl, and Arctic fox. The northern coniferous forest is dominated by tall conifer trees. Familiar animals include the snowshoe hare, lynx, and porcupine. This biome 314
Habitats and biomes stretches east to west across Canada and south into the Great Lakes region of the United States. It is also found at the higher elevations of the Rocky Mountains and the western coastal mountain ranges. Its upper elevation limit is the “treeline,” above which only low-growing grasses and herbaceous plants grow in an alpine tundra community similar to the Arctic tundra. In mountain ranges, the change in biomes with altitude mimics the biome changes with increasing latitude, with tundra being the highest or northernmost. Approximately the eastern half of the United States was once covered with the eastern deciduous forest biome, named for the dominant broadleaved trees that shed their leaves in the fall. This biome receives more than 75 centimeters (about 30 inches) of rainfall each year and has a rich diversity of bird species, such as the familiar warblers, chickadees, nuthatches, and woodpeckers. Familiar mammals include the white-tailed deer, cottontail rabbit, and wild turkey. The Great Plains, between the Mississippi River and the Rocky Mountains, receives 25 to 75 centimeters (about 10 to 30 inches) of rain annually to support an open grassland biome often called the prairie. The many grass species that dominate this biome once supported vast herds of bison and, in the western parts, pronghorn antelope. Seasonal drought and periodic fires are common features of grasslands. The land between the Rockies and the western coastal mountain ranges is a cold type of desert biome; three types of hotter deserts are found from western Texas west to California and south into Mexico. Deserts receive fewer than 25 centimeters (10 inches) of rainfall annually. The hot deserts are dominated by many cactus species and short, thorny shrubs and trees, whereas sagebrush, grass, and small conifer trees dominate the cold desert. These deserts have many lizard and snake species, including poisonous rattlesnakes and the Gila monster. The animals often have nocturnal habits to avoid the hot, dry daytime. Southern Mexico and the Yucatan Peninsula are covered by evergreen, broad-leaved trees in the tropical rain-forest biome, which receives more than 200 centimeters (almost 80 inches) of rain per year. Many tree-dwelling animals, such as howler monkeys and tree frogs, spend most of their lives in the tree canopy, seldom reaching the ground. Aquatic biomes can be broadly categorized into freshwater, marine, and estuarine biomes. Freshwater lakes, reservoirs, and other still-water environments are called lentic, in contrast to lotic, or running-water, environments. Lentic communities are often dominated by planktonic organisms, small, drifting (often transparent) microscopic algae, and the small animals that feed on them. These, in turn, support larger invertebrates and fish. Lotic environments depend more on algae that are attached to the bot315
Habitats and biomes toms of streams, but they support equally diverse animal communities. The marine biome is separated into coastal and pelagic, or open-water, environments, which have plant and animal communities somewhat similar to lotic and lentic freshwater environments, respectively. The estuarine biome is a mixing zone where rivers empty into the ocean. These areas have a diverse assemblage of freshwater and marine organisms. The Biosphere All the biomes together, both terrestrial and aquatic, constitute the biosphere, which by definition is all the places on earth where life is found. Organisms that live in a biome must interact with one another and must successfully overcome and exploit their abiotic environment. The severity and moderation of the abiotic environments determine whether life can exist in that microhabitat. Such things as minimum and maximum daily and annual temperature, humidity, solar radiation, rainfall, and wind speed directly affect which types of organisms are able to survive. Amazingly, few places on earth are so hostile that no life exists there. An example would be the boiling geyser pools at Yellowstone National Park, but even there, as the water temperature cools at the edges to about 75 degrees Celsius, bacterial colonies begin to appear. There is abundant life in the top meter or two of soil, with plant roots penetrating to twenty-two meters or more in extreme cases. Similarly, the mud and sand bottoms of lakes and oceans contain a rich diversity of life. Birds, bats, and insects exploit the airspace above land and sea up to a height of about 1,200 meters (nearly 4,000 feet), with bacterial and fungal spores being found much higher. Thus, the biosphere generally extends about 10 to 15 meters (33 to 50 feet) below the surface of the earth and about 1,200 meters above it. Beyond that, conditions are too hostile. A common analogy is that if the earth were a basketball, the biosphere would constitute only the thin outer layer. Studying Habitats and Biomes Abiotic habitat requirements for a local population or even for an entire species can be determined in the laboratory by testing its range of tolerance for each factor. For example, temperature can be regulated in a laboratory experiment to determine the minimum and maximum survival temperatures as well as an optimal range. The same can be done with humidity, light, shelter, and substrate type: “Substrate preference” refers to the solid or liquid matter in which an organism grows and/or moves—for example, soil or rock. The combination of all ranges of tolerance for abiotic factors should describe a population’s actual or potential microhabitat within a community. Furthermore, laboratory experiments can theoretically indi316
Habitats and biomes cate how much environmental change each population can tolerate before it begins to migrate or die. Methods to study the interaction of populations with one another or even the interaction of individuals within one local population are much more complicated and are difficult or impossible to bring into a laboratory setting. These studies most often require collecting field data on distribution, abundance, food habits or nutrient requirements, reproduction and death rates, and behavior in order to describe the relationships between individuals and populations within a community. Later stages of these field investigations could involve experimental manipulations in which scientists purposely change one factor, then observe the population or community response. Often, natural events such as a fire, drought, or flood can provide a disturbance in lieu of human manipulation. There are obvious limits to how much scientists should tinker with the biosphere merely to see how it works. Populations and even communities in a local area can be manipulated and observed, but it is not practical or advisable to manipulate whole ecosystems or biomes. To a limited extent, scientists can document apparent changes caused by civilization, pollution, and long-term climatic changes. This information, along with population- and community-level data, can be used to construct a mathematical model of a population or community. The model can then be used to predict the changes that would happen if a certain event were to occur. These predictions merely represent the “best guesses” of scientists, based on the knowledge available. Population ecologists often construct reasonably accurate population models that can predict population fluctuations based on changes in food supply, abiotic factors, or habitat. As models begin to encompass communities, ecosystems, and biomes, however, their knowledge bases and predictive powers decline rapidly. Perhaps the most complicating factor in building and testing these large-scale models is that natural changes seldom occur one at a time. Thus, scientists must attempt to build cumulative-effect models that are capable of incorporating multiple changes into a predicted outcome. James F. Fowler See also: Biomes: determinants; Biomes: types; Biosphere concept; Chaparral; Deserts; Ecosystems: definition and history; Ecosystems: studies; Forests; Grasslands and prairies; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes; Wetlands. 317
Habitats and biomes Sources for Further Study Allaby, Michael. Biomes of the World. 9 vols. Danbury, Conn.: Grolier International, 1999. Bradbury, Ian K. The Biosphere. New York: Belhaven Press, 1991. Cox, George W. Conservation Biology: Concepts and Applications. 2d ed. Dubuque, Iowa: Wm. C. Brown, 1997. Hanks, Sharon La Bonde. Ecology and the Biosphere: Principles and Problems. Delray Beach, Fla.: St. Lucie Press, 1996. Luoma, Jon R. The Hidden Forest: The Biography of an Ecosystem. New York: Henry Holt, 1999. Miller, G. Tyler, Jr. Living in the Environment. 12th ed. Belmont, Calif.: Thomson Learning, 2001. Sutton, Ann, and Myron Sutton. Eastern Forests. New York: Alfred A. Knopf, 1986. Wetzel, Robert G. Limnology. 3d ed. San Diego: Academic Press, 2001.
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HABITUATION AND SENSITIZATION Type of ecology: Behavioral ecology Habituation is learning to ignore irrelevant stimuli that previously produced a reaction. Results of habituation studies have been used to explain, predict, and control behavior of humans and other organisms.
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abituation is a simple form of nonassociative learning that has been demonstrated in organisms as diverse as protozoans, insects, Nereis (clam worms), birds, and humans. The habituated organism learns to ignore irrelevant, repetitive stimuli which, prior to habituation, would have produced a response. With each presentation of the habituating stimulus, the responsiveness of the organism decreases toward the zero, nonresponse level. If habituation training continues after the zero-response level, the habituation period is prolonged. Habituation to a particular stimulus naturally and gradually disappears unless the training continues. If training is resumed after habituation has disappeared, habituation occurs more rapidly in the second training series than in the first. Habituation is important for survival of the individual. Many stimuli are continuously impinging upon it: Some are important, others are not. Important stimuli require an immediate response, but those which result in neither punishment nor reward may be safely ignored. Stimulus and Response When a new stimulus is presented (when a sudden change in the environment occurs), the organism—be it bird, beast, or human—exhibits the “startle” or “orientation” response. In essence, it stops, looks, and listens. If the stimulus is repeated and is followed by neither reward nor punishment, the organism will pay less and less attention to it. When this happens, habituation has occurred, and the organism can now respond to and deal with other stimuli. On the other hand, if, during habituation learning, a painful consequence follows a previously nonconsequential stimulus, the organism has been sensitized to that stimulus and will respond to it even more strongly than it did before the learning sessions, whether they are occurring in the laboratory or in the field. Young birds must learn to tell the difference between and respond differently to a falling leaf and a descending predator. A young predatory bird 319
Habituation and sensitization must learn to ignore reactions of its prey which pose no danger, reactions that the predator initially feared. A theory known as the dual-process habituation-sensitization theory was formulated in 1966 and revised in 1973. It establishes criteria for both habituation and sensitization. Criteria for habituation (similar to those proposed by E. N. Sokolov in 1960) are that habituation will develop rapidly; the frequency of stimulation determines the degree of habituation; if stimulation stops for a period of time, habituation will disappear; the stronger the stimulus, the slower the rate of habituation; the frequency of stimulation is more important than the strength of the stimulus; rest periods between habituation series increase the degree of habituation; and the organism will generalize and therefore exhibit habituation to an entire class of similar stimuli. Stimulus generalization can be measured: If a different stimulus is used in the second habituation series, habituation occurs more rapidly; it indicates generalization. Sensitization Sensitization, a very strong response to a very painful, injurious, or harmful stimulus, is not limited to stimulus-response circuits but involves the entire organism. After sensitization, the individual may respond more strongly to the habituating stimulus than it did prior to the start of habituation training. There are eight assumptions about sensitization in the dual-process theory. Sensitization does not occur in stimulus-response circuits but involves the entire organism. Sensitization increases during the early stages of habituation training but later decreases. The stronger the sensitizing stimulus and the longer the exposure to it the greater the sensitization; weaker stimuli may fail to produce any sensitization. Even without any external intervention, sensitization will decrease and disappear. Increasing the frequency of sensitization stimulation causes a decrease in sensitization. Sensitization will extend to similar stimuli. Dishabituation, the loss of habituation, is an example of sensitization. Sensitization may be time-related, occurring only at certain times of the day or year. According to the dual-process theory, the response of an organism to a stimulus will be determined by the relative strengths of habituation and sensitization. Charles Darwin, the father of evolution, observed and described habituation, although he did not use the term. He noted that the birds of the Galápagos Islands were not disturbed by the presence of the giant tortoises, Amblyrhynchus; they disregarded them just as the magpies in England, which Darwin called “shy” birds, disregarded cows and horses grazing nearby. Both the giant tortoises of the Galápagos Islands and the 320
Habituation and sensitization grazing horses and cows of England were stimuli which, though present, would not produce profit or loss for the birds; therefore, they could be ignored. The Neurology of Stimulus Response Within the bodies of vertebrates is a part of the nervous system called the reticular network or reticular activating system; it has been suggested that the reticular network is largely responsible for habituation. It extends from the medulla through the midbrain to the thalamus of the forebrain. (The thalamus functions as the relay and integration center for impulses to and from the cerebrum of the forebrain.) Because it is composed of a huge number of interconnecting neurons and links all parts of the body, the reticular network functions as an evaluating, coordinating, and alarm center. It monitors incoming message impulses. Important ones are permitted to continue to the cerebral cortex, the higher brain. Messages from the cerebral cortex are coordinated and dispatched to the appropriate areas. During sleep, many neurons of the reticular network stop functioning. Those that remain operational may inhibit response to unimportant stimuli (habituation) or cause hyperresponsiveness (sensitization). The cat who is accustomed to the sound of kitchen cabinets opening will sleep through a human’s dinner being prepared (habituation) but will charge into the kitchen when the she hears the sound of the cat food container opening (sensitization). Researcher E. N. Sokolov concluded that the “orientation response” (which can be equated with sensitization) and habituation are the result of the functioning of the reticular network. According to Sokolov, habituation results in the formation of models within the reticular activating system. Incoming messages that match the model are disregarded by the organism, but those that differ trigger alerting reactions throughout the body, thus justifying the term “alerting system” as a synonym for the reticular network. Habituation to a very strong stimulus would take a long time. Repetition of this strong stimulus would cause an even stronger defensive reflex and would require an even longer habituation period. The Role of Neurotransmitters Neurotransmitters are chemical messengers that enable nerve impulses to be carried across the synapse, the narrow gap between neurons. They transmit impulses from the presynaptic axon to the postsynaptic dendrite(s). E. R. Kandell, in experiments with Aplysia (the sea hare, a large mollusk), demonstrated that as a habituation training series continues, 321
Habituation and sensitization smaller amounts of the neurotransmitter acetylcholine are released from the axon of the presynaptic sensory neuron. On the other hand, after sensitization, this neuron released larger amounts of acetylcholine because of the presence of serotonin, a neurotransmitter secreted by a facilitory interneuron. When a sensitizing stimulus is very strong, it usually generates an impulse within the control center—a ganglion, a neuron, or the brain. The control center then transmits an impulse to a facilitory interneuron, causing the facilitory interneuron to secrete serotonin. Increased levels of acetylcholine secretion by the sensory neuron result from two different stimuli: direct stimulation of the sensory neurons of the siphon or serotonin from the facilitory interneuron. Facilitory interneurons synapse with sensory neurons in the siphon. Serotonin discharged from facilitory interneurons causes the sensory neurons to produce and secrete more acetylcholine. On the molecular level, the difference between habituation and adaptation—the failure of the sensory neuron to respond—is very evident. The habituated sensory neuron has a neurotransmitter in its axon but is unable to secrete it and thereby enable the impulse to be transmitted across the synapse. The adapted sensory neuron, by contrast, has exhausted its current supply of neurotransmitter. Until new molecules of neurotransmitter are synthesized within the sensory neuron, none is available for release. In 1988, Emilie A. Marcus, Thomas G. Nolen, Catherine H. Rankin, and Thomas J. Carew published the multiprocess theory to explain dishabituation and sensitization in the sea hare, Aplysia. On the basis of their experiments using habituated sea hares that were subjected to different stimuli, they concluded that dishabituation and sensitization do not always occur together; further, they decided, there are three factors to be considered: dishabituation, sensitization, and inhibition. Habituation Studies Habituation studies have utilized a wide variety of approaches, ranging from the observation of intact organisms carrying out their normal activities in their natural surroundings to the laboratory observation of individual nerve cells. With different types of studies, very different aspects of habituation and sensitization can be investigated. Surveying the animal kingdom in 1930, G. Humphrey concluded that habituation-like behavior exists at all levels of life, from the simple one-celled protozoans to the multicelled, complex mammals. E. N. Sokolov, a compatriot of Ivan P. Pavlov, used human subjects in the laboratory. In 1960, he reported on the results of his studies, which involved sensory integration, the makeup of the orientation reflex (which he 322
Habituation and sensitization credited Pavlov with introducing in 1910), a neuronal model and its role in the orientation reflex, and the way that this neuronal model could be used to explain the conditioned reflex. Sokolov measured changes in the diameter of blood vessels in the head and finger, changes in electrical waves within the brain, and changes in electrical conductivity of the skin. By lowering the intensity of a tone to which human subjects had been habituated, Sokolov demonstrated that habituation was not the result of fatigue, because subjects responded to the lower-intensity tone with the startle or orientation reflex just as they would when a new stimulus was introduced. Sokolov concluded that the orientation response (which is related to sensitization) and habituation are the result of the functioning of the reticular network of the brain and central nervous system. Sokolov emphasized that the orientation response was produced after only the first few exposures to a particular stimulus, and it increased the discrimination ability of internal organizers. The orientation response was an alerting command. Heat, cold, electric shock, and sound were the major stimuli that he used in these studies. E. R. Kandell used the sea hare, Aplysia, in his habituation-sensitization studies. Aplysia is a large sluglike mollusk, with a sheetlike, shell-producing body covering, the mantle. Aplysia has a relatively simple nervous system and an easily visible gill-withdrawal reflex. (The gill is withdrawn into the mantle shelf.) Early habituation-sensitization experiments dealt with withdrawal or absence of gill withdrawal. Later experiments measured electrical changes that occurred within the nerve cells that controlled gill movement. These were followed by studies which demonstrated that the gap (synapse) between the receptor nerve cell (sensory neuron) and the muscle-moving nerve cell (motor neuron) was the site where habituation and dishabituation occurred and that neurohormones such as acetylcholine and serotonin played essential roles in these processes. Kandell called the synapse the “seat of learning.” Charles Sherrington used spinal animals in which the connection between the brain and the spinal nerve cord had been severed. Sherrington demonstrated that habituation-sensitization could occur within the spinal nerve cord even without the participation of the brain. Pharmaceuticals have also been used in habituation-sensitization studies. Michael Davis and Sandra File used neurotransmitters such as serotonin and norepinephrine to study modification of the startle (orientation) response. Habituation studies conducted in the laboratory enable researchers to control variables such as genetic makeup, previous experiences, diet, and the positioning of subject and stimulus; however, they lack many of the background stimuli present in the field. In her field studies of the chimpan323
Habituation and sensitization zees of the Gombe, Jane Goodall used the principles of habituation to decrease the distance between herself and the wild champanzees until she was able to come close enough to touch and be accepted by them. The field-experimental approach capitalizes on the best of both laboratory and field techniques. In this approach, a representative group of organisms that are in their natural state and habitat are subjected to specific, known stimuli. Learning to Survive Habituation is necessary for survival. Many stimuli are constantly impinging upon all living things; since it is biologically impossible to respond simultaneously to all of them, those which are important must be dealt with immediately. It may be a matter of life or death. Those which are unimportant or irrelevant must be ignored. Cell physiologists and neurobiologists have studied the chemical and electrical changes that occur between one nerve cell and another and between nerve and muscle cells. The results of those studies have been useful in understanding and controlling these interactions as well as in providing insights for therapies. Psychologists utilize the fruits of habituation studies to understand and predict, modify, and control the behavior of intact organisms. For example, knowing that bulls serving as sperm donors habituate to one cow or model and stop discharging sperm into it, the animal psychologist can advise the semen collector to use a different cow or model or simply to move it to another place—even as close as a few yards away. Conservationists and wildlife protectionists can apply the principles of habituation to wild animals, which must live in increasingly closer contact with one another and with humans, so that both animal and human populations can survive and thrive. For example, black-backed gulls, when establishing their nesting sites, are very territorial. Males which enter the territory of another male gull are rapidly and viciously attacked. After territorial boundaries are established, however, the males in contiguous territories soon exhibit “friendly enemy” behavior: They are tolerant of the proximity of other males that remain within their territorial boundaries. This has been observed in other birds as well as in fighting fish. Walter Lener See also: Altruism; Communication; Defense mechanisms; Displays; Ethology; Herbivores; Hierarchies; Insect societies; Isolating mechanisms; Mammalian social systems; Migration; Mimicry; Omnivores; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. 324
Habituation and sensitization Sources for Further Study Alcock, John. Animal Behavior: An Evolutionary Approach. 6th ed. Sunderland, Mass.: Sinauer Associates, 1998. Alkon, Daniel L. “Learning in a Marine Snail.” Scientific American 249 (July, 1983): 70-84. Barash, David P. Sociobiology and Behavior. New York: Elsevier, 1982. Drickamer, Lee C., Stephen H. Vessey, and Doug Meikle. Animal Behavior: Mechanisms, Ecology, Evolution. 4th ed. Dubuque, Iowa: Wm. C. Brown, 1996. Eckert, Roger, and David Randall. Animal Physiology. 4th ed. San Francisco: W. H. Freeman, 1997. Gould, James L. Ethology: The Mechanisms and Evolution of Behavior. New York: W. W. Norton, 1980. Gould, James L., and Peter Marler. “Learning by Instinct.” Scientific American 256 (January, 1987): 74-85. Halliday, Tim, ed. Animal Behavior. Norman: University of Oklahoma Press, 1994. Klopfer, P. H., and J. P. Hailman. An Introduction to Animal Behavior: Ethology’s First Century. Englewood Cliffs, N.J.: Prentice-Hall, 1967. Slater, P. J. B., and T. R. Halliday, eds. Behavior and Evolution. New York: Cambridge University Press, 1994.
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HERBIVORES Types of ecology: Behavioral ecology; Ecoenergetics Herbivores, animals which eat only plants, include insects and other arthropods, fish, birds, and mammals. They keep plants from overgrowing and are food for carnivores or omnivores.
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erbivores are animals whose diets consist entirely of plants. They occupy one of the major trophic levels and have two ecological functions. First, they eat plants and keep them from overgrowing. Second, they are food for carnivores, which subsist almost entirely upon their flesh, and omnivores, which eat both plants and animals. Herbivores live on land or in oceans, lakes, and rivers. They can be insects, other arthropods, fish, birds, or mammals. Insect Herbivores Insects are the largest animal class, with approximately one million species. Fossils show their emergence 400 million years ago. Insects occur worldwide, from pole to pole, on land and in fresh or salt water. They are the best developed invertebrates, except for some mollusks. They mature by metamorphosis, passing through at least two dissimilar stages before adulthood. Metamorphosis can take up to twenty years or may be complete a week after an egg is laid. Many insects are herbivores. Some feed on many different plants, others depend on one plant variety or a specific plant portion, such as leaves or stems. Relationships between insects and the plants they eat are frequently necessary for plant growth and reproduction. Among the insect herbivores are grasshoppers and social insects such as bees. Artiodactyls Artiodactyls are another type of herbivore—hoofed mammals, including cattle, pigs, goats, giraffes, deer, antelope, and hippopotamuses. Artiodactyls walk on two toes. Their ancestors had five, but evolution removed the first toe and the second and fifth toes are vestigial. Each support toe—the third and fourth—ends in a hoof. The hippopotamus, unique among artiodactyls, stands on four toes of equal size and width. What makes artiodactyls herbivorous is the fact that they lack upper incisor and canine teeth, whereas pads in their upper jaws help the lower teeth grind food. Domesticated artiodactyls include bovids such as cattle, 326
Herbivores sheep, and goats. Many artiodactyls, such as antelope, cattle, deer, goats, and giraffes, are ruminants. They chew and swallow vegetation, which enters the stomach for partial digestion, is regurgitated, chewed again, and reenters the stomach for more digestion. This maximizes nutrient intake from food. Members of the deer family, which include approximately 40 species from the seven-foot-tall moose to the one-foot-tall pudu, are hoofed ruminants that inhabit many continents and biomes: Asia, Europe, the Americas, and North Africa; woods, prairies, swamps, mountains, and tundra. These animals eat the twigs, leaves, bark, and buds of bushes and saplings, and grasses. Most antelope, a group of approximately 150 ruminant species, are African, although some are European or Asian. They live on plains, marshes, deserts, and forests, eating grass, twigs, buds, leaves, and bark. In Asia, Siberian saigas and goat antelope (takin) inhabit mountain ranges. Chamois goat antelope live in Europe’s Alps.There are no true antelope in North America, where their closest relatives are pronghorns and Rocky Mountain goats (goat-antelope with both goat and antelope anatomic features). The smallest antelope, the dik-dik, is rabbit-sized. Elands, the largest antelope, are ox-sized. Giraffes and hippos are artiodactyls that inhabit the dry, tree-scattered land south of the Sahara in Africa. Giraffes rarely graze and can go for
Deer are herbivores, eating grasses and the tender buds, shoots, bark, and twigs of trees. The boundary between forest and field offers them the widest range of food choices. (PhotoDisc) 327
Herbivores months without drinking, getting most of their water from the leaves they eat, because it is difficult for them to reach the ground or the surface of a river with their mouths. By contrast, the short-legged, stocky hippos are semiaquatic, spending most daylight hours nearly submerged eating aquatic plants. At night they eat land plants. Aquatic Herbivores Fish are aquatic vertebrates, having gills, scales, and fins. They include rays, lampreys, sharks, lungfish, and bony fish. The earliest vertebrates, 500 million years ago, were fish. They comprise more than 50 percent of all vertebrates and have several propulsive fins: dorsal fins along the central back; caudal fins at tail ends; and paired pectoral and pelvic fins on sides and belly. Fish inhabit lakes, oceans, and rivers, even in Arctic and Antarctic areas. Most marine fish are tropical. The greatest diversity of freshwater species is found in African and rain forest streams. Ecological Importance It is clear that wild herbivores are ecologically important to food chains. This is because they eat plants, preventing their overgrowth, and they are eaten by carnivores and omnivores. Domesticated herbivores—cattle, sheep and goats, used for human sustenance—account for three to four billion living creatures. Future production of better strains of domesticated herbivores via recombinant deoxyribonucleic acid (DNA) research may cut the numbers of such animals killed to meet human needs. Appropriate species conservation should maintain the present balance of nature and sustain the number of wild herbivore species living on earth. Sanford S. Singer See also: Balance of nature; Food chains and webs; Omnivores; Predation; Trophic levels and ecological niches. Sources for Further Study Gerlach, Duane, Sally Atwater, and Judith Schnell. Deer. Mechanicsburg, Pa.: Stackpole Books, 1994. Gullan, P. J., and P. S. Cranston. Insects: An Outline of Entomology. 2d ed. Malden, Mass.: Blackwell Science, 2000. Olsen, Sandra L., ed. Horses Through Time. Boulder, Colo.: Roberts Rinehart, 1996. Rath, Sara. The Complete Cow. Stillwater, Minn.: Voyageur Press, 1990. Shoshani, Jeheskel, and Frank Knight. Elephants: Majestic Creatures of the Wild. Rev. ed. New York: Checkmark Books, 2000. 328
HIERARCHIES Type of ecology: Behavioral ecology Hierarchies, systems of establishing dominance and subordination, are important in maintaining social order in many species of animals.
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ll animal species strive for their share of fitness. In this struggle for reproductive success, individuals that make up a population often compete for essential resources such as food, mates, or nesting sites. In many species, competition over resources may lead to fighting among individuals. Fighting, however, can be costly to the individuals involved. The loser may suffer real injury or even death, and the winner has to expend energy and still may suffer an injury. In order to prevent constant fighting over resources, many animal species have adopted a system of what sociobiologists call a dominance hierarchy or social hierarchy. The dominance hierarchy is a set of aggression-submission relationships among the animals of a population. With an established system of dominance, the subordinate individuals will acquiesce rather than compete with the dominant individuals for resources. Dominance and Subordinance To be dominant is to have the priority of access to the essential resources of life and reproduction. In almost all cases, the superior dominant animals will displace the subordinates from food, mates, and nest sites. In the matter of obtaining food, for example, wood pigeons are flock feeders. The dominant pigeons are always found near the center of the flock when feeding and feed more quickly than the subordinate birds at the edge of the flock. The birds at the edge of the flock accumulate less food and often obtain just enough to sustain them through the night. Among sheep and reindeer, the lowest-ranking females are also the worst-fed animals and among the poorest of mothers. Baby pigs compete for teat position on the mother and once established will maintain that position until weaning. Those piglets that gain access to the most anterior teats will weigh more at weaning than those who have to settle for posterior teat positions. In gaining access to mates, one study with laboratory mice has shown that while the dominant males constituted only one third of the male population, they sired 92 percent of the offspring. Life is still not all that hopeless for the subordinates. Oftentimes the loser in the battle for dominance is given a second chance, and in some of 329
Hierarchies the more social species, the subordinate only has to await its turn to rise in the hierarchy. In some species, cooperation among subordinate groups, especially kin groups, can lead to the formation of a new colony and a new opportunity to establish dominance. In other species, it may well be advantageous for the subordinate to stay with the group. For example, individual baboons and macaques will not survive very long if they are away from the group’s sleeping area, and they will have no opportunity to reproduce. It has been shown that even a low-ranking male eats well if he is part of a troop, and he may occasionally have the opportunity to mate. In addition, the dominant male will eventually lose prowess, and the subordinate will have a chance to move up in the dominance hierarchy. Types of Hierarchies The simplest possible type of hierarchy is a despotism, in which one individual rules over all other members of the group and no rank distinctions are made among the subordinates. Hierarchies more frequently contain multiple ranks in a more or less linear fashion. An alpha individual dominates all others, a beta individual is subordinate to the alpha but dominates all others, and so on down to the omega individual at the bottom, who is dominated by all of the others. Sometimes, the network is complicated by triangular or other circular relationships in which two or three individuals might be at the same dominance level. Such relationships appear to be less stable than despotisms or linear orders. Nested hierarchies are often observed in some animal species. Societies that are divided into groups can display dominance both within and between the various components. For example, white-fronted geese establish a rank order of several subgroups including parents, mated pairs without young, and free juveniles. These hierarchies are superimposed over the hierarchy within each of the subgroups. In wild turkeys, brothers establish a rank order among their brotherhood, but each brotherhood competes for dominance with other brotherhoods on the display grounds prior to mating. Formation and Maintenance of Hierarchies Hierarchies are formed during the initial encounters between animals through repeated threats and fighting, but once the issue of dominance has been determined, each individual gives way to its superiors with little or no hostile exchange. Life in the group may eventually become so peaceful that the existence of ranking is hidden from the observer until some crisis occurs to force a confrontation. For example, a troop of baboons can go for hours without engaging in sufficient hostile exchanges to reveal their rank330
Hierarchies ing, but in a moment of crisis such as a quarrel over food the hierarchy will suddenly be evident. Some species are organized in absolute dominance hierarchies, in which the rank orders remain constant regardless of the circumstances. Status within an absolute dominance hierarchy changes only when individuals move up or down in rank through additional interaction with their rivals. Other animal societies are arranged in relative dominance hierarchies. In these arrangements, such as with crowded domestic house cats, even the highest-ranking individuals acquiesce to subordinates when the latter approach a point that would normally be too close to their personal sleeping space. The stable, peaceful hierarchy is often supported by status signs. In other words, the mere actions of the dominant individual advertise his dominance to the other individuals. The leading male in a wolf pack can control his subordinates without a display of excessive hostility in the great majority of cases. He advertises his dominance by the way he holds his head, ears, and tail, and the confident face-forward manner in which he approaches other members of his pack. In a similar manner, the dominant rhesus monkey advertises his status by an elaborate posture which includes elevated head and tail, lowered testicles, and slow, deliberate body movements accompanied by an unhesitating but measured scrutiny of other monkeys he encounters. Animals use not only visual signals to advertise dominance but also acoustic and chemical signals. For example, dominant European rabbits use a mandibular secretion to mark their territory. Uses of Hierarchies A stable dominance hierarchy presents a potentially effective united front against strangers. Since a stranger represents a threat to the status of each individual in the group, he is treated as an outsider. When expelling an intruder, cooperation among individuals within the group reaches a maximum. Chicken producers have long been aware of this phenomenon. If a new bird is introduced to the flock, it will be subjected to attacks for many days and be forced down to the lowest status unless it is exceptionally vigorous. Most often, it will simply die with very little show of fighting back. An intruder among a flock of Canada geese will be met with the full range of threat displays and repeated mass approaches and retreats. In some primate societies, the dominant animals use their status to stop fighting among subordinates. This behavior has been observed in rhesus and pig-tailed macaques and in spider monkeys. This behavior has been observed even in animal societies, such as squirrel monkeys, that do not exhibit dominance behavior. Because of the power of the dominant indi331
Hierarchies vidual, relative peace is observed in animal societies organized by despotisms, such as hornets, paper wasps, bumblebees, and crowded territorial fish and lizards. Fighting increases significantly among the equally ranked subordinates as they vie for the dominant position when the dominant animal is removed. Young males are routinely excluded from the group in a wide range of aggressively organized mammalian societies such as baboons, langur monkeys, macaques, elephant seals, and harem-keeping ungulates. At best, these young males are tolerated around the fringes of the group, but many are forced out of the group and either join bachelor herds or wander as solitary nomads. As would be expected, these young males are the most aggressive and troublesome members of the society. They compete with one another for dominance within their group and often unite into separate bands that work together to reduce the power of the dominant males. Males in the two groups show different behaviors. Among the Japanese macaques, the dominant males stay calm and aloof when introduced to a new object so as to not risk loss of their status, but the females and young males will explore new areas and examine new objects. D. R. Gossett See also: Altruism; Communication; Defense mechanisms; Displays; Ethology; Habituation and sensitization; Herbivores; Insect societies; Isolating mechanisms; Mammalian social systems; Migration; Mimicry; Omnivores; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study Barash, David P. Sociobiology and Behavior. 2d ed. New York: Elsevier, 1982. Campbell, Neil A., Lawrence G. Mitchell, and Jane B. Reece. Biology: Concepts and Connections. 3d ed. San Francisco: Benjamin/Cummings, 2000. Feldhamer, G. A., L. C. Drickamer, S. H. Vessey, and J. F. Merritt. Mammalogy. Boston: WCB/McGraw-Hill, 1999. Ridley, Mark. Animal Behavior: An Introduction to Behavioral Mechanisms, Development, and Ecology. 2d ed. Boston: Blackwell Scientific Publications, 1995. Wilson, Edward O. Sociobiology: The Abridged Edition. Cambridge, Mass.: Belknap Press of Harvard University Press, 1980. Wittenberger, James F. Animal Social Behavior. Boston: Duxbury Press, 1981.
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HUMAN POPULATION GROWTH Type of ecology: Population ecology Since the Industrial Revolution of the nineteenth century, human populations have experienced a period of explosive growth. Overpopulation now poses a real threat to plant and animal life, ecosystems, and the long-term sustainability of the earth’s current ecological balance.
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ust eleven thousand years ago, only about five million humans lived on the earth. The initial population growth was slow, largely because of the way humans lived—by hunting and gathering. Such a mobile lifestyle limited the size of families for practical reasons. When simple means of birth control, often abstention from sex, failed, a woman would elect abortion or, more commonly, infanticide to limit her family size. Furthermore, a high mortality rate among the very young, the old, the ill, and the disabled acted as a natural barrier to rapid population growth.
Agricultural Revolution It took more than two million years—from the earliest animal considered to be human, Homo habilis—or about 100,000 years from the time modern human beings, Homo sapiens sapiens, migrated out of Africa into the rest of the world, for the world’s population to reach one billion. The second billion was added in about one hundred years, the third billion in fifty years, the fourth in fifteen years, the fifth billion in twelve years. By the close of the twentieth century, the world’s population was exceeding six billion. This explosion had become possible with the development of agriculture. A hunting-gathering lifestyle requires a nomadic existence over a large range of territory, which makes the establishment of infrastructures, such as permanent housing and long-range food stores, impractical. Agricultural societies, by contrast, can support more people in a limited area and, because settlements are permanent, can build infrastructures over time and therefore minimize efforts directed to basic subsistence, such as the erecting of shelters. Moreover, when humans became sedentary, some limits on family size were lifted. With the development of agriculture, children became an asset to their families by helping with farming and other chores. Starting about eleven thousand years ago (5 million people), humans began to cultivate such plants as barley, lentils, wheat, and peas in the 333
Human population growth Middle East—an area that today extends from Lebanon and Syria in the northwest eastward through Iraq to Iran. In doing so, human beings began to have a profound ecological impact as well. In cultivating and caring for these crops, early farmers changed the characteristics of these plants, making them higher yielding, more nutritious, and easier to harvest. Agriculture spread and first reached Europe approximately six thousand years ago. By the beginning of the common era (1 c.e.), human population had grown to about 130 million, distributed all over the earth. Agriculture might also have originated independently in Africa in one or more centers. Many crops were domesticated there, including yams, okra, coffee, and cotton. In Asia, agriculture based on staples such as rice and soybeans and many other crops such as citrus, mangos, taro, and bananas was developed. Agriculture was developed independently in the New World. It began as early as nine thousand years ago in Mexico and Peru. Christopher Columbus and his followers found many new crops to bring back to the Old World, including corn, kidney beans, lima beans, tomatoes, tobacco, chili peppers, potatoes, sweet potatoes, pumpkins and squashes, avocados, cacao, and the major cultivated species of cotton. Ecological Impact For the last five to six centuries, important staple crops have been cultivated throughout the world. Wheat, rice, and corn, which provide 60 percent of the calories people consume, are cultivated wherever they will grow. Other crops, including spices and herbs, have also been brought under cultivation. One of the results of the agricultural developments— particularly pronounced since the Green Revolution of high-yield crops in the mid-twentieth century—has been a tendency toward “monoculture,” or the reduction of diversity, in crop plants worldwide. The growing population has also changed the landscape, distribution, and diversity of plants dramatically. Clear-cutting and deforestation have driven many species (both plant and animal) to extinction. Relatively little has been done to develop agricultural practices suitable for tropical regions. As a result, the tropics are being devastated ecologically, with an estimated 20 percent of the world’s species likely to be lost by the midtwenty-first century. Industrial Revolution By 1650, the world population had reached 500 million. The process of industrialization had begun, bringing about profound changes in the lives of humans and their interactions with the natural world. With improved living standards, lower death rates, and prolonged life expectancies, human 334
Human population growth
World and Urban Population Growth, 1950-2020 8 7.6
7
Population in billions
6.8 6
6.1 5.3
5 4
4.1
3.7
3 2
5.0
4.5
2.6
3.3
3.0
2.6 1.8
1 0.8 0
1950
1.1 1960
1.4 1970
1980
Total world population
1990
2000
2010
2020
Urban population
Sources: Data are from U.S. Bureau of the Census International Data Base and John Clarke, “Population and the Environment: Complex Interrelationships,” in Population and the Environment (Oxford, England: Oxford University Press, 1995), edited by Bryan Cartledge. Note: The world’s population passed 6 billion in the year 2000.
population grew exponentially. By 1999, there were about 6 billion people, compared with 2.5 billion in 1950. By 2002, the world population was well on its way to 7 billion, with an annual growth rate of nearly 100 million. The processes of industrialization and exponential population growth combined to multiply the ecological effects of human activity on the biosphere. Human use of fossil fuels, fertilizers, pesticides, global trading pracitices, agribusiness practices—all these large-scale activities began to exhibit large-scale effects on both the abiotic and biotic components of ecosystems everywhere. Threats to Sustainability Without effective measures of control, the human population could exceed the earth’s carrying capacity. Humans are, at present, estimated to consume about 40 percent of the total net products generated via photosynthesis by plants. Human activities have reduced the productivity of earth’s forests and grasslands by 12 percent. Each year, millions of acres of once335
Human population growth productive land are turned into desert through overgrazing and deforestation, especially in developing countries. As a result of overfertilization and aggressive practices in agriculture, topsoil is lost at an annual rate of 24 billion metric tons. Collectively, these practices caused the destruction of 40 million acres of rain forest each year during the 1960’s and 1970’s and the extinction of enormous numbers of species. Through technological innovation and aggressive practices in agriculture, a 2.6-fold increase in world grain production has been achieved since 1950. However, this increase in food output is not nearly enough to feed the population. Based upon an estimate by the World Bank and the Food and Agriculture Organization of the United Nations, one out of every five people is living in absolute poverty, unable to obtain food, shelter, or clothing dependably. About one out of every ten people receives less than 80 percent of the daily caloric intake recommended by the United Nations. In countries such as Bangladesh and Haiti and in regions as East Africa, humans are dying in increasing numbers because of the lack of food. This food shortage may stem from drought, soil depletion, or soil loss; more often, famine results from inequitable distribution of resources among populations. Situations exacerbated by a growing population also pose threats
By the end of the twentieth century, the world’s human population had passed the 6 billion mark, and most of that population lived in or near large urban centers typified by this street in Barcelona, Spain: with high-rises and other structures designed for high-density living and working accommodations. (PhotoDisc) 336
Human population growth to the environment, aggravating the problems of acid rains, toxic and hazardous wastes, water shortages, topsoil erosion, ozone layer punctuation, greenhouse effects, and groundwater contamination. Ming Y. Zheng See also: Acid deposition; Biological invasions; Biomagnification; Biopesticides; Deforestation; Erosion and erosion control; Eutrophication; Genetically modified foods; Grazing and overgrazing; Integrated pest management; Invasive plants; Landscape ecology; Multiple-use approach; Ocean pollution and oil spills; Ozone depletion and ozone holes; Pesticides; Pollution effects; Population growth; Rangeland; Slash-and-burn agriculture; Soil; Soil contamination; Urban and suburban wildlife; Waste management; Wildlife management. Sources for Further Study Brown, L. State of the World 2000. New York: W. W. Norton, 2000. Heiser, C. B., Jr. Seed to Civilization: The Story of Food. 2d ed. San Francisco: W. H. Freeman, 1981. National Research Council. Lost Crops of the Incas: Little-Known Plants of the Andes with Promise for Worldwide Cultivation. Washington, D.C.: National Academy Press, 1990. Weiner, J. The Next One Hundred Years: Shaping the Future of Our Living Earth. New York: Bantam Books, 1990.
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HYDROLOGIC CYCLE Types of ecology: Ecoenergetics; Ecosystem ecology; Global ecology The hydrologic cycle, one of the most important geochemical cycles with both short- and long-range impacts on the biosphere, is a continuous system through which water circulates through vegetation, in the atmosphere, in the ground, on land, and in surface water such as rivers and oceans. The sun and earth’s gravity provide the energy that drives the hydrologic cycle.
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he total amount of water on earth is an estimated 1.36 billion cubic kilometers. Of this water, 97.2 percent is found in the earth’s oceans. The ice caps and glaciers contain 2.15 percent of the earth’s water. The remainder, 0.65 percent, is divided among rivers (0.0001 percent), freshwater and saline lakes (0.017 percent), groundwater (0.61 percent), soil moisture (0.005 percent), the atmosphere (0.001 percent), and the biosphere and groundwater below 4,000 meters (0.0169 percent). While the percentages of water appear to be small for these water reservoirs, the total volume of water contained in each is immense. Evaporation Evaporation is the process whereby a liquid or solid is changed to a gas. Heat causes water molecules to become increasingly energized and to move more rapidly, weakening the chemical force that binds them together. Eventually, as the temperature increases, water molecules move from the ocean’s surface into the overlying air. The rate of evaporation is influenced by radiation, temperature, humidity, and wind velocity. Each year, about 320,000 cubic kilometers of water evaporate from oceans. It is estimated that an additional 60,000 cubic kilometers of water evaporate from rivers, streams, and lakes or are transpired by plants each year. A total of about 380,000 cubic kilometers of water is evapotranspired from the earth’s surface every year. Condensation and Precipitation Wind may transport the moisture-laden air long distances. The amount of water vapor the air can hold depends upon the temperature: The higher the temperature, the more vapor the air can hold. As air is lifted and cooled at higher altitudes, the vapor in it condenses to form droplets of water. Condensation is aided by small dust and other particles in the atmosphere. As droplets collide and coalesce, raindrops begin to form, and precipita338
Hydrologic cycle tion begins. Most precipitation events are the result of three causal factors: frontal precipitation, or the lifting of an air mass over a moving weather front; convectional precipitation related to the uneven heating of the earth’s surface, causing warm air masses to rise and cool; and orographic precipitation, resulting from a moving air mass being forced to move upward over a mountain range, cooling the air as it rises. Each year, about 284,000 cubic kilometers of precipitation fall on the world’s oceans. This water has completed its cycle and is ready to begin a new cycle. Approximately 96,000 cubic kilometers of precipitation fall upon the land surface each year. This precipitation follows a number of different pathways in the hydrologic cycle. It is estimated that 60,000 cubic kilometers evaporate from the surface of lakes or streams or transpire directly back into the atmosphere. The remainder, about 36,000 cubic kilometers, is intercepted by human structures or vegetation, infiltrates the soil or bedrock, or becomes surface runoff. Interception In cities, the amount of water intercepted by human structures may approach 100 percent. However, much urban water is collected in storm sewers or drains that lead to a surface drainage system or is spread over the land surface to infiltrate the subsoil. Interception loss from vegetation depends upon interception capacity (the ability of the vegetation to collect and retain falling precipitation), wind speed (the higher the wind speed, the greater the rate of evaporation), and rainfall duration (the interception loss will decrease with the duration of rainfall, as the vegetative canopy will become saturated with water after a period of time). Broad-leaf forests may intercept 15 to 25 percent of annual precipitation, and a bluegrass lawn may intercept 15 to 20 percent of precipitation during a growing season. Transpiration Plants are continuously extracting soil moisture and passing it into the atmosphere through a process called transpiration. Moisture is drawn into the plant rootlet through osmotic pressure. The water moves through the plant to the leaves, where it is passed into the atmosphere through the leaf openings, or stomata. The plant uses less than 1 percent of the soil moisture in its metabolism; thus, transpiration is responsible for most water vapor loss from the land in the hydrologic cycle. For example, an oak tree may transpire 151,200 liters per year. Overland Flow and Infiltration When the amount of rainfall is greater than the earth’s ability to absorb it, 339
Hydrologic cycle
The Hydrologic Cycle
Rain clouds
Cloud formation
ing
S Infiltration
Wat er ta bl e Zone of saturation
fa
ce
run
o ff
an fr o m o c e
ra t
ur
Evaporation
f ro m soi l tran spi r a t io n
fal l
ns pi r f r ve o ma t i o fr o n ge t m st r a t i o n ea ms
e wh il
Precipitation
Soil Rock
Deep percolation
Percolation Groundwater
Ocean
Source: U.S. Department of Agriculture, Yearbook of Agriculture (Washington, D.C.: Government Printing Office, 1955).
excess water begins to run off, a process termed overland flow. Overland flow begins only if the precipitation rate exceeds the infiltration capacity of the soil. Infiltration occurs when water sinks into the soil surface or into fractures of rocks; the amount varies according to the characteristics of the soil or rock and the nature of the vegetative cover. Sandy soils have higher infiltration rates than clay rock soils. Nonporous rock has an infiltration rate of zero, and all precipitation that reaches it becomes runoff. The presence of vegetation impedes surface runoff and increases the potential for infiltration to occur. Water infiltrating the soil or bedrock encounters two forces: capillary force and gravitational force. A capillary force is the tendency of the water in the subsurface to adhere to the surface of soil or sediment particles. Capillary forces are responsible for the soil moisture a few inches below the land surface. The water that continues to move downward under the force of gravity through the pores, cracks, and fissures of rocks or sediments will eventually enter a zone of water saturation. This source of underground water is 340
Hydrologic cycle called an aquifer—a rock or soil layer that is porous and permeable enough to hold and transport water. The top of this aquifer, or saturated zone, is the water table. This water is moving slowly toward a point where it is discharged to a lake, spring, or stream. Groundwater that augments the flow of a stream is called base flow. Base flow enables streams to continue to flow during droughts and winter months. Groundwater may flow directly into the oceans along coastlines. When the infiltration capacity of the earth’s surface is exceeded, overland flow begins. Broad, thin sheets of water a few millimeters thick are called sheet flow. After flowing a few meters, the sheets break up into threads of current that flow in tiny channels called rills. The rills coalesce into gullies and, finally, into streams and rivers. Some evaporation losses occur from the stream surface, but much of the water is returned to the oceans, thus completing the hydrologic cycle. Residence Time Residence time refers to how long a molecule of water will remain in various components of the hydrologic cycle. The average length of time that a water molecule stays in the atmosphere is about one week. Two weeks is the average residence time for a water molecule in a river, and ten years in a lake. It would take four thousand years for all the water molecules in the oceans to be recycled. Groundwater may require anywhere from a few weeks to thousands of years to move through the cycle. This time period suggests that every water molecule has been recycled millions of times. Methods of Study Several techniques are used to gather data on water in the hydrologic cycle. These data help scientists determine the water budget for different geographic areas. Together, these data enable scientists to estimate the total water budget of the earth’s hydrologic cycle. Scientists have developed a vast array of mathematical equations and instruments to collect data on the hydrologic cycle. Variations in temperature, precipitation, evapotranspiration, solar radiation, vegetative cover, soil and bedrock type, and other factors must be evaluated to understand the local or global hydrologic cycle. Precipitation is an extremely variable phenomenon. The United States has some thirteen thousand precipitation stations equipped with rain gauges, placed strategically to compensate for wind and splash losses. Precipitation falling on a given area is determined using a rain-gauge network of uniform density to determine the arithmetic mean for rainfall in the area. The amount of water in a snowpack is estimated by snow surveys. 341
Hydrologic cycle The depth and water content of the snowpack are measured and the extent of the snow cover mapped using satellite photography. The amount of precipitation lost by interception can be measured and evaluated. Most often, interception is determined by measuring the amount above the vegetative canopy and at the earth’s surface. The difference is what is lost to interception. The volume of water flowing by a given point at a given time in an open stream channel is called discharge. Discharge is determined by measuring the velocity of water in the stream channel, using a current meter. The cross-sectional area of the stream channel is determined at a specific point and multiplied by the stream velocity. Automated stream-gauging stations are located on most streams to supply data for various hydrologic investigations. The U.S. National Weather Service maintains about five hundred stations using metal pans, mimicking reservoirs, to measure free-water evaporation. Water depths of 17 to 20 centimeters are maintained in the pans. Errors may result from splashing by raindrops or birds. Because the pans will heat and cool more rapidly than will a natural reservoir, a pan coefficient is employed to compensate for this phenomenon. The wind velocity is also determined. A lake evaporation nomograph determines daily lake evaporation. The mean daily temperature, wind velocity, solar radiation, and mean daily dew point are all used in the calculation. The amount of evapotranspiration can be measured using a lysimeter, a large container holding soil and living plants. The lysimeter is set outside, and the initial soil moisture is determined. All precipitation or irrigation is measured accurately. Changes in the soil moisture storage determine the amount of evapotranspiration. Samuel F. Huffman See also: Balance of nature; Biomass related to energy; Food chains and webs; Geochemical cycles; Herbivores; Nutrient cycles; Omnivores; Phytoplankton; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Berner, Elizabeth K., and Robert A. Berner. Global Environment: Water, Air, and Geochemical Cycles. Upper Saddle River, N.J.: Prentice Hall, 1996. Moore, J. W. Balancing the Needs of Water Use. New York: Springer-Verlag, 1989. Viessman, Warren, Jr., and Gary L. Lewis. Introduction to Hydrology. 4th ed. Glenview, Ill.: HarperCollins, 1995. 342
INSECT SOCIETIES Types of ecology: Behavioral ecology; Population ecology Ants, termites, and many kinds of bees and wasps live in complex groups known as insect societies. Studies of such societies have enriched scientific knowledge about some of the most successful species on earth and have provided insights into the biological basis of social behavior in other animals.
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any of the most robust, thriving species today owe their success in great part to benefits that they reap from living in organized groups or societies. Nowhere are the benefits of group living more clearly illustrated than among the social insects. Edward O. Wilson, one of the foremost authorities on insect societies, estimates that more than twelve thousand species of social insects exist in the world today. This number is equivalent to all the species of known birds and mammals combined. Although insect societies have reached their pinnacle in bees, wasps, ants, and termites, many insects show intermediate degrees of social organization—providing insights regarding the probable paths of the evolution of sociality. Scientists estimate that eusociality has evolved at least twelve times: once in the Isoptera, or termites, and eleven separate times in the Hymenoptera, comprising ants, wasps, and bees. In addition, one group of aphids has been found to have a sterile soldier caste. Although the eusocial species represent diverse groups, they all show a high degree of social organization and possess numerous similarities, particularly with regard to division of labor, cooperative brood care, and communication among individuals. Ants The organization of a typical ant colony is representative, with minor modifications, of all insect societies. A newly mated queen, or reproductive female, will start a new ant colony. Alone, she digs the first nest chambers and lays the first batch of eggs. These give rise to grublike larvae, which are unable to care for themselves and must be nourished from the queen’s own body reserves. When the larvae have reached full size, they undergo metamorphosis and emerge as the first generation of worker ants. These workers—all sterile females—take over all the colony maintenance duties, including foraging outside the nest for food, defending the nest, and cleaning and feeding both the new brood and the queen, which subsequently 343
Insect societies becomes essentially an egg-laying machine. For a number of generations, all eggs develop into workers and the colony grows. Often, several types of workers can be recognized. Besides the initial small workers, or minor workers, many ant species produce larger forms known as major workers, or soldiers. These are often highly modified, with large heads and jaws, well suited for defending the nest and foraging for large prey. Food may include small insects, sugary secretions of plants or sap-feeding insects, or other scavenged foods. After several years, when the colony is large enough, some of the eggs develop into larger larvae that will mature into new reproductive forms: queens and males. Males arise from unfertilized eggs, while new queens are produced in response to changes in larval nutrition and environmental factors. These sexual forms swarm out of the nest in a synchronized fashion to mate and found new colonies of their own. Bees and Wasps With minor modifications, the same pattern occurs in bees and wasps. Workers of both bees and wasps are also always sterile females, but they differ from ants in that they normally possess functional wings and lack a fully differentiated soldier caste. Wasps, like ants, are primarily predators and scavengers; bees, however, have specialized on pollen and plant nectar as foods, transforming the latter into honey that is fed to both nestmates and brood. The bias toward females reflects a feature of the biology of the Hymenoptera that is believed to underlie their tendency to form complex societies. All ants, wasps, and bees have an unusual form of sex determination in which fertilized eggs give rise to females and unfertilized eggs develop into males. This type of sex determination, known as haplodiploidy, generates an asymmetry in the degree of relatedness among nestmates. As a consequence, sisters are more closely related to their sisters than they are to their own offspring or their brothers. Scientists believe that this provided an evolutionary predisposition for workers to give up their own personal reproduction in order to raise sisters—a form of natural selection known as kin selection. Termites The termites, or Isoptera, differ from the social Hymenoptera in a number of ways. They derive from a much more primitive group of insects and have been described as little more than “social cockroaches.” Instead of the strong female bias characteristic of the ants, bees, and wasps, termites have regular sex determination; thus, workers have a fifty-fifty sex ratio. Additionally, termite development lacks complete metamorphosis. Rather, the 344
Insect societies young termites resemble adults in form from their earliest stages. As a consequence of these differences, immature forms can function as workers from an early age, and—at least among the lower termites—they regularly do so. Termites also differ from Hymenoptera in their major mode of feeding. Instead of feeding on insects or flowers, all termites feed on plant material rich in cellulose. Cellulose is a structural carbohydrate held together by chemical bonds that most animals lack enzymes to digest. Termites have formed intimate evolutionary relationships with specialized microorganisms—predominantly flagellate protozoans and some spirochete bacteria—that have the enzymes necessary to degrade cellulose and release its food energy. The microorganisms live in the gut of the termite. Because these symbionts are lost with each molt, immature termites are dependent upon gaining new ones from their nestmates. They do this by feeding on fluids excreted or regurgitated by other individuals, a process known as trophallaxis. This essential exchange of materials also includes, along with food, certain nonfood substances known as pheromones. Pheromones, by definition, are chemicals produced by one individual of a species that affect the behavior or development of other individuals of the same species that come in contact with them. Pheromones are well documented throughout the insect world, and they play a key role in communication between members of nonsocial or subsocial species. Moth mating attractants provide a well-studied example. Pheromones are nowhere better developed than among the social insects. They not only appear to influence caste development in the Hymenoptera and termites but also permit immediate communication among individuals. Among workers of the fire ant (Solenopsis saevissima), chemical signals have been implicated in controlling recognition of nestmates, grooming, clustering, digging, feeding, attraction or formation of aggregations, trail following, and alarm behavior. Nearly a dozen different glands have been identified which produce some chemical in the Hymenoptera, although the exact function of many of these chemicals remains unknown. In addition to chemical communication, social insects may share information in at least three other ways: by tactile contact, such as stroking or grasping; by producing sounds, including buzzing of wings; and by employing visual cues. Through combinations of these senses, individuals can communicate complex information to nestmates. Indeed, social insects epitomize the development of nonhuman language. One such language, the “dance” language of bees, which was unraveled by Karl von Frisch and his students, provides one of the best-studied examples of animal behavior. In the waggle dance, a returning forager communicates the location of 345
Insect societies a food resource by dancing on the comb in the midst of its nestmates. It can accurately indicate the direction of the flower patch by incorporating the relative angles between the sun, the hive, and the food. Information about distance, or more precisely the energy expended to reach the food source, is communicated in the length of the run. Workers following the dance are able to leave the nest and fly directly to the food source, for distances in excess of one thousand meters. Benefits of Cooperation Living in cooperative groups has provided social insects with opportunities not available to their solitary counterparts. Not only can more individuals cooperate in performing a given task, but also several quite different tasks may be carried out simultaneously. The benefits from such cooperation are considerable. For example, group foraging allows social insects to increase the range of foods they can exploit. By acting as a unit, species such as army ants can capture large insects and even fledgling birds. A second benefit of group living is in nest building. Shelter is a primary need for all animals. Most solitary species use naturally occurring shelters or, at best, build simple nests. By cooperating and sharing the effort, social insects are able to build nests that are quite elaborate, containing several kinds of chambers. Wasps and bees build combs, or rows of special cells, for rearing brood and storing food. Subterranean termites can construct mounds more than six meters high, while others build intricate covered nests in trees. Mound-building ants may cover their nests with a thatch that resembles, in both form and function, the thatched roofs of old European dwellings. Colonial nesting provides two additional benefits. First, it enhances defense. By literally putting all of their eggs in one basket, social insects can centralize and share the guard duties. The effectiveness of this approach is attested by one’s hesitation to stir up a hornet’s nest. Nest construction also provides the potential to maintain homeostasis, the ability to regulate the environment within a desirable range. Virtually all living creatures maintain homeostasis within their bodies, but very few animals have evolved the ability to maintain a constant external living environment. In this respect, insect societies are similar to human societies. Workers adjust their activities to maintain the living environment within optimal limits. Bees, for example, can closely regulate the internal temperature of a hive. When temperatures fall below 18 degrees Celsius, they begin to cluster together, forming a warm cover of living bees to protect the vulnerable brood stages. To cool the hive in hot weather, workers initially circulate air by beating their wings. If further cooling is needed, they resort to evaporative cooling by regurgitating water throughout the nest. This 346
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Social insects such as bees, wasps, termites, and ants are known for combining their efforts to build protective structures that allow them to live and reproduce in relative safety. This mound, for example, houses thousands of ants. (Corbis)
water evaporates with wing fanning and serves to cool the entire hive. Other social insects rely on different but equally effective methods. Some ants, and especially termites, build their nests as mounds in the ground, with different temperatures existing at different depths. The mound nests of the African termite, Macrotermes natalensis, are an impressive engineering feat. They are designed to regulate both temperature and air flow through complex passages and chambers, with the mound itself serving as a sophisticated cooling tower. Finally, group living allows the coordination of the efforts of individuals to accomplish complex tasks normally restricted to the higher vertebrates. The similarities between insect societies and human society are striking. An insect society is often referred to as a superorganism, reflecting the remarkable degree of coordination between individual insects. Individual workers have been likened to cells in a body, and castes to tissues or organs that perform specialized functions. Insect societies are not immortal; however, they often persist in a single location for periods similar to the life spans of much larger animals. The social insects have one of the 347
Insect societies most highly developed symbolic languages outside human cultures. Further, social insects have evolved complex and often mutually beneficial interactions with other species to a degree unknown except among human beings. Bees are inseparably linked with the flowers they feed upon and pollinate. Ants have actually developed agriculture of a sort with their fungus gardens and herds of tended aphids. On a more sobering note, ants are the only nonhuman animals that are known to wage war. These striking similarities with human societies have led researchers to study social insects to learn about the biological basis of social behavior and have led to the development of a new branch of science known as sociobiology. Studying Insect Societies Because of the diversity of questions that investigators have addressed regarding insect societies, many methods of scientific inquiry have been employed. In Karl von Frisch’s experiments, for example, basic behavioral observations were coupled with simple but elegant experimental design to unravel the dance language of bees. The bees were raised in an observation colony. This was essentially a large hive housed between plates of glass so that an observer could watch the behavior of individual bees. Researchers followed specific workers by marking them with small numbers placed on the abdomen or thorax. Sometimes the entire observation hive was placed within a small, darkened shed to simulate more closely the conditions within a natural hive. Bees learned to find an artificial “flower”—a glass dish filled with a sugar solution. Brightly colored backgrounds and odors such as peppermint oil were added to the sugars to provide specific cues for the bees to associate with the reward. Feeding stations were set up at fixed distances; observers could follow the exact movements of known individuals both at the feeder and at the hive. In this way, von Frisch was able to describe several types of dances (the round dance for near food sources, the waggle dance for feeding stations that were farther from the hive) and show that a returning bee could share information regarding the location and quality of a source with her nestmates. Scientists subsequently have developed robot bees that can be operated by remote control to perform different combinations of dance behaviors. This allows them to determine which parts of the dance actually convey the coded information. The investigation of forms of chemical communication requires application of a variety of techniques. Chromatography is useful for identifying the minute amounts of chemical pheromones with which insects communicate. Chromatography (which literally means “writing with color”) is particularly suitable for separating mixtures of similar materials. A solu348
Insect societies tion of the mixture is allowed to flow over the surface of a porous solid material. Since each component of the mixture will flow at a slightly different rate, eventually they will become separated or spaced out on the solid material. Once the components of the pheromone have been separated and identified, their activity is assessed separately and in combination using living insects. Such bioassays allow researchers to determine exactly which fractions of the chemical generate the highest response. Other biochemical techniques, such as electrophoresis, have been used to determine subtle behavioral differences, such as kin discrimination among hive mates. Each individual carries a complement of enzymes or proteins that catalyze biological reactions in the body. The structure of such enzymes is determined by the genetic makeup of the individual, and it varies among individuals. Because enzyme structure is inheritable, however, much as eye color is, the degree of similarities between the enzymes can be used as a measure of how closely related two individuals are. The amino acids composing the enzyme differ in their electrical charges, so different forms can be separated using the technique of electrophoresis. When a liquid containing their enzymes is subjected to an electrical field, the proteins with the highest negative charge will move farthest toward the positive pole. This provides a tool to distinguish close genetic relatives for use in conjunction with behavioral observations to test, for example, whether workers can discriminate full sisters from half sisters, or relatives from nonrelatives, as kin selection theory would predict. The Success of Social Insects Social insects are among the most successful groups of animals throughout the world, especially in the tropics. Although the number of species is low when compared to all insects (twelve thousand out of more than a million species), their relative contribution to the community may be unduly large. In Peru, for example, ants may make up more than 50 percent of the individual insects collected at any site. The study of social insects has provided scientists with new ways of looking at social behavior in all animals. Charles Darwin described the evolution of sterile workers in the social insects as the greatest obstacle to his theory of evolution by natural selection. In attempts to explain this seeming paradox, William D. Hamilton closely examined the social Hymenoptera, where sociality had evolved eleven separate times. Realizing that the haplodiploid form of sex determination led to sisters being more closely related to one another than they would be to their own young, Hamilton developed a far-reaching new theory of social evolution: kin selection, or selection acting on groups of closely related individuals. This 349
Insect societies theory, which provides insights into the evolution of many kinds of seemingly altruistic behaviors, arose primarily from his perceptions regarding the asymmetrical relatedness of nestmates in the social Hymenoptera. These insects, then, should be credited with providing the model system that has led to a subdiscipline of behavioral ecology known as sociobiology, the study of the biological basis of social behavior. Moreover, given their central roles in critical ecological processes such as nutrient cycling and pollination, it would be hard to imagine life without them. Catherine M. Bristow See also: Altruism; Animal-plant interactions; Biopesticides; Coevolution; Communication; Communities: ecosystem interactions; Ethology; Mammalian social systems; Mimicry; Pollination; Symbiosis. Sources for Further Study Crozier, Ross H., and Pekka Pamilo. Evolution of Social Insect Colonies: Sex Allocation and Kin Selection. New York: Oxford University Press, 1996. Frisch, Karl von. The Dance Language and Orientation of Bees. Translated by L. E. Chadwick. Cambridge, Mass.: Belknap Press, 1967. Gordon, Deborah M. Ants at Work: How an Insect Society Is Organized. New York: W. W. Norton, 1999. Hoelldobler, Bert, and Edward O. Wilson. Journey to the Ants: A Story of Scientific Exploration. Cambridge, Mass.: Belknap Press, 1994. Ito, Yoshiaki. Behavior and Social Evolution of Wasps: The Communal Aggregation Hypothesis. New York: Oxford University Press, 1993. Moffett, Mark W. “Samurai Aphids: Survival Under Siege.” National Geographic 176 (September, 1989): 406-422. Prestwich, Glenn D. “The Chemical Defenses of Termites.” Scientific American 249 (August, 1983): 78-87. Wilson, Edward O. The Insect Societies. Cambridge, Mass.: The Belknap Press of Harvard University Press, 1971. _______. Sociobiology: The New Synthesis. Cambridge, Mass.: The Belknap Press of Harvard University Press, 1975. _______. Success and Dominance in Ecosystems: The Case of the Social Insects. Oldendorf/Luhe, Federal Republic of Germany: Ecology Institute, 1990.
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INTEGRATED PEST MANAGEMENT Types of ecology: Agricultural ecology; Ecotoxicology; Restoration and conservation ecology Integrated pest management (IPM) is the practice of integrating insect, animal, or plant management tactics, such as chemical control, cultural control, biological control, and plant resistance, to maintain pest populations below damaging levels in the most economical and environmentally responsible manner.
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n the past, pest management strategies in agriculture focused primarily on eliminating all of a particular pest organism from a given field or area. These strategies depended on the use of chemical pesticides to kill all the pest organisms. Prior to the twentieth century, farmers used naturally occurring compounds such as kerosine or pyrethrum for this purpose. During the second half of the twentieth century, synthetic pesticides began playing a prominent role in controlling crop pests. Chemical Effects After 1939 the use of pesticides such as dichloro-diphenyl-trichloroethane (DDT) was so successful in controlling pest populations that farmers began to substitute a heavy dependence on pesticides for sound pest management strategies. Soon pests in high-value crops became resistant to one pesticide after another. In addition, outbreaks of secondary pests occurred because either they developed resistance to the pesticides or the pesticides killed their natural enemies. Among birds ingesting DDT in the food chain, eggshells were so thin as to render many eggs unviable, reducing the bird population. Such impacts of DDT supplied the impetus for chemical companies to develop new pesticides, to which the pests also eventually developed resistance. Rationale for IPM Certain pests have developed resistance to all federally registered materials designed to control them. In addition, many pesticides are toxic to humans, wildlife, and other nontarget organisms and therefore contribute to environmental pollution. For these reasons, and because it is very expensive for chemical companies to put a new pesticide on the market, many producers began looking at alternative strategies such as IPM for managing pests. The driving forces behind the development of IPM programs are concern about the contamination of groundwater and other nontarget 351
Integrated pest management sites, adverse effects on nontarget organisms, and development of pesticide resistance. Pesticides will probably continue to play a vital role in pest management, even in IPM, but it is believed that the role will be greatly diminished over time. An agricultural ecosystem consists of the crop environment and its surrounding habitat. The interactions among soil, water, weather, plants, and animals in this ecosystem are rarely constant enough to provide the ecological stability of nonagricultural ecosystems. Nevertheless, it is possible to use IPM to manage most pests in an economically efficient and environmentally friendly manner. IPM programs have been successfully implemented in the cropping of cotton and potatoes, and they are being developed for other crops. Developing IPM Programs There are generally three stages of development associated with IPM programs, and the speed at which a program progresses through these stages is dependent on the existing knowledge of the agricultural ecosystem and the level of sophistication desired. The first phase is referred to as the pesticide management phase. The implementation of this phase requires that the farmer know the relationship between pest densities and the resulting damage to crops so that the pesticide is not applied excessively. In other words, farmers do not have to kill all the pests all the time. They must use pesticides only when the economic damage caused by a number of pest organisms present on a given crop exceeds the cost of using a pesticide. This practice alone can reduce the number of chemical applications by as much as half. The second phase is called the cultural management phase. Implementation of this phase requires knowledge of the pest’s biology and its relationship to the cropping system. Cultural management includes such practices as delaying planting times, rotating crops, altering harvest dates, and planting resistant cultivars. It is necessary to understand pest responses to other species as well as abiotic factors, such as temperature and humidity, in the environment. If farmers know the factors that control population growth of a particular pest, they may be able to reduce the impact of that pest on a crop. For example, if a particular pest requires short days to complete development, farmers might be able to harvest the crop before the pest has a chance to develop. The third phase is the biological control phase, which involves the use of biological organisms rather than chemicals to control pests. This is the most difficult phase to implement because farmers must understand not only the pest’s biology but also the biology of the pest’s natural enemies and the degree of effectiveness with which these agents control the pest. 352
Integrated pest management In general, it is not possible to rely completely on biological control methods. A major requirement in using biological agents is to have sufficient numbers of the control agent present at the same time that the pest population is at its peak. It is sometimes possible to change the planting dates so that the populations of the pests and the biological control agents are synchronized. Also, there is often more than one pest species present at the same time within the same crop, and it is extremely difficult to control simultaneously two pests with biological agents. D. R. Gossett See also: Biomagnification; Biopesticides; Genetically modified foods; Pesticides; Pollution effects; Soil contamination. Sources for Further Study Pedigo, Larry P. Entomology and Pest Management. 4th ed. Upper Saddle River, N.J.: Prentice Hall, 2002. Romoser, William S., and John G. Stoffolano. The Science of Entomology. 4th ed. Boston: McGraw-Hill, 1998.
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INVASIVE PLANTS Types of ecology: Ecosystem ecology; Ecotoxicology Nonnative (also termed “exotic”) fungi and plants that can outcompete native species are called invasive plants. Invasive plants cause irreversible changes to ecosystems, threaten plant and animal species, and cost billions of dollars to control.
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etween the damage they cause and the cost of control efforts, invasive plants cost the United States more than $140 billion every year. For example, nearly half of the threatened and endangered plant species listed for the United States in 1999, 400 of 958, were in peril because of competition from invasive species. Thus, invasive plants are capable of causing irreparable changes in ecosystems. Most invasive species in the United States originated in Asia or Europe. The seeds or spores of these plants are accidentally transported into new habitats by humans, leaving the plants’ natural enemies and competitors behind. Without natural biological controls, the alien species can thrive and outcompete the native flora, driving the native plants toward extinction and creating a near monoculture of the invader. Invasive plants are weedy species that grow rapidly, produce large numbers of long-lived seeds, and frequently have perennial roots, or rhizomes, that enhance asexual propagation. Invasive plants have a variety of effects on invaded ecosystems. Many invasive species deplete soil moisture and nutrient levels, either by growing more vigorously than native plants early in the growing season or by being more tolerant of reduced levels of water and nutrients than are natives. Some invasive species produce toxic chemicals (allelopathy) that are released into the soil and inhibit the growth of competitors. By outcompeting native plants, the invader decreases species diversity as it replaces many native species. As a result, animal species dependent on native flora are also affected. Fungi and seed plants are among the most disruptive invasive plants in the United States today. Control Methods Invasive species are carried to new habitats, either in or on machinery or organisms, and are usually transported by humans, so prevention is the most cost-effective method of control. Once an invasive species has entered an area, plant quarantine is an effective first line of defense. For example, living plants and animals brought into the United States must pass 354
Invasive plants inspection by the U.S. Department of Agriculture Animal and Plant Health Inspection Service (APHIS) to ensure that they are not carrying potentially invasive species. Particular care is taken to ensure that imports from known areas of infestation are clean of seeds, spores, or propagules. The next most effective strategy is detection and control of small infestations. When there is a known threat of invasion, the affected area should be surveyed periodically and individual plants removed by hand or, in extreme cases, by “spot-spraying” herbicide. Eradication is possible when the infestation is small. Once an invasive species becomes established, the only means of management are expensive chemical or biological controls which, at best, will only minimize damage. A variety of chemicals may be used to kill invasive plants. Most chemicals, however, affect a broad spectrum of plants, including native species. Biological controls, including natural enemies from the invasive plant’s native ecosystem, can be more specific but may also be capable of displacing native species and becoming “invaders.” Fungi Many of the most serious plant pathogens are invasive species introduced into the Americas since the beginning of European settlement. Two classic examples are Dutch elm disease, caused by the fungi Ophiostoma ulmi and Ophiostoma novo-ulmi and chestnut blight, caused by the fungus Cryphonectria parasitica. At the beginning of the twentieth century, the most common street tree growing in the cities of the eastern United States was the
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Invasive plants American elm. About 1910, the European bark beetle was introduced into the United States. It was not until the 1930’s that Dutch elm disease was observed in Ohio and a few eastern states. The fungal spores are carried by the beetles, which burrow under the elm bark. The native elm has little resistance to this fungus, whose spores rapidly germinate and form extensive mycelia within the phloem of the host tree, killing it within a few years. After its initial contact, the fungus spread throughout the cities and forests of the East and gradually westward, so that by 1990 nearly all the native American elm trees in the United States had been killed. American chestnut was also one of the early dominant trees of the eastern U.S. forest. In addition to providing edible fruit, the chestnut became a commercially important timber tree. Chestnut blight fungus was first reported in 1904 on chestnut trees in the New York Zoological Garden and quickly began to spread. This infestation led directly to passage of the Plant Quarantine Act of 1912, the forerunner of APHIS. By 1950 most native chestnut trees were reduced to minor understory shrubs. Biological control using virus strains first isolated in Italy show promise for controlling the blight. Terrestrial Green Plants Virtually all the plants commonly called weeds are foreign invaders that are difficult, if not impossible, to control. Some of the most severe include Canada thistle (Circium arvense), leafy spurge (Euphorbia esula), and purple loosestrife (Lythrum salicaria). Canada thistle is the most widespread and difficult species of thistle to control. It was introduced to Canada from Europe in the 1600’s and in 1795 was listed as a noxious weed in Vermont. It is now found in most of the United States as well as in Canada. Single herbicide applications do not provide long-term control, and there are no effective biological controls that do not also attack native species. Leafy spurge was first reported in Newbury, Massachusetts, in 1827, where it arrived in ship ballast. By 1900 it had reached the West Coast, and it now thrives in more than half the states and in Canada. Thirteen species of insects are approved for biological control, and several herbicides can be used to control infestations effectively. Sheep and goats will browse on spurge. Purple loosestrife was introduced into the United States as an ornamental plant in the early 1800’s and became established in New England by 1830. Its early spread into the Great Lakes region was by barge and other canal traffic. Rapid expansion of the pest, particularly in the West, occurred after 1940, primarily due to the plant’s “escape” from ornamental cultiva356
Invasive plants tion into irrigation projects. It is now found in all the lower forty-eight states except Florida. At present, there are no effective controls. Aquatic Green Plants Invasive plants are not limited to the terrestrial habitat or to vascular plants. One dramatic example is the alga Caulerpa taxifolia, the so-called killer alga. This attractive tropical alga was found to be easy to grow in saltwater aquaria and useful as a secondary food source for herbivorous tropical fish. It began to be used this way at the Oceanographic Museum of Monaco in 1982. Two years later, a meter-square patch was found growing in the Mediterranean Sea, visible from a window of the museum. By 1990 the alga had reached France, and by 1995 it could be found from Spain to Croatia. Caulerpa produces a number of toxins that inhibit foraging by native fish, and it is a prolific vegetative reproducer. Fragments of the alga, stuck on an anchor for example, can start a new infestation wherever the anchor is next dropped. This species has been discovered in Southern California, and a related species has become dominant in Sydney Harbor, Australia. Other aquatic invasive plants in the United States include the mosquito fern (Azolla), the Eurasian water milfoil (Myriophyllum), and the water hyacinth (Eichhornia crassipes). Marshall D. Sundberg See also: Biological invasions; Biomagnification; Eutrophication; Genetically modified foods; Pesticides; Phytoplankton; Pollution effects; Waste management. Sources for Further Study Meinesz, Alexandre. Killer Algae. Chicago: University of Chicago Press, 1999. Randall, John M., and Janet Marinelli, eds. Invasive Plants: Weeds of the Global Garden. Brooklyn, N.Y.: Brooklyn Botanic Garden, 1996. Sheley, Roger L., and Janet K. Petroff. Biology and Management of Noxious Rangeland Weeds. Corvalis, Oreg.: Oregon State University Press, 1999.
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ISOLATING MECHANISMS Types of ecology: Behavioral ecology; Ecosystem ecology; Evolutionary ecology; Speciation Isolating mechanisms act to prevent interbreeding and the exchange of genes between species. The establishment of isolating mechanisms between populations is a critical step in the formation of new species and ensuring biodiversity.
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solating mechanisms (reproductive isolating mechanisms) prevent interbreeding between species. The term, which was first used by Theodosius Dobzhansky in 1937 in his landmark book Genetics and the Origin of Species, refers to mechanisms that are genetically influenced and intrinsic. Geographic isolation can prevent interbreeding between populations, but it is an extrinsic factor and therefore does not qualify as an isolating mechanism. Isolating mechanisms function only between sexually reproducing species. They have no applicability to forms that reproduce only by asexual means, as by mitotic fission, stoloniferous or vegetative reproduction, or egg development without fertilization (parthenogenesis in animals). Obligatory self-fertilization in hermaphrodites (mainly a phenomenon in plants, rare in animals) is a distortion of the sexual process that produces essentially the same results as asexual reproduction. Many lower animals and protists regularly employ both asexual and sexual means of reproduction, and the significance of isolating mechanisms in such forms is essentially the same as in normal sexual species. Premating Mechanisms Reproductive isolating mechanisms are usually classified into two main groups. Premating (prezygotic) mechanisms operate prior to mating, or the release of gametes, and, therefore, do not result in a wastage of the reproductive potential of the individual. Postmating (postzygotic) mechanisms come into play after mating, or the release of gametes, and could result in a loss of the genetic contribution of the individual to the next generation. This distinction is also important in the theoretical sense in that natural selection should favor genes that promote premating isolation; those that do not presumably would be lost more often through mismatings (assuming that hybrids are not produced, or are sterile or inferior), and this could lead to a reinforcement of premating isolation. Ethological (behavioral) isolation is the most important category of premating isolation in animals. The selection of a mate and the mating pro358
Isolating mechanisms cess depends upon the response of both partners to various sensory cues, any one of which may be species-specific. Although one kind of sensory stimulus may be emphasized, different cues may come into play at different stages of the pairing process. Visual signals provided by color, pattern, or method of display are often of particular importance in diurnal animals such as birds, many lizards, certain spiders, and fish. Sounds, as in male mating calls, are often important in nocturnal breeders such as crickets or frogs but are also important in birds. Mate discrimination based on chemical signals or odors (pheromones) is of fundamental importance in many different kinds of animals, especially those where visual cues or sound are not emphasized; chemical cues also are often important in aquatic animals with external fertilization. Tactile stimuli (touch) often play an important role in courtship once contact is established between the sexes. Even electrical signals appear to be utilized in some electrogenic fish. Ecological (habitat) isolation often plays an important role. Different forms may be adapted to different habitats in the same general area and may meet only infrequently at the time of reproduction. One species of deer mouse, for example, may frequent woods, while another is found in old fields; one fish species spawns in riffles, while another spawns in still pools. This type of isolation, although frequent and widespread, is often incomplete as the different forms may come together in transitional habitats. The importance of ecological isolation, however, is attested by the fact that instances in which hybrid swarms are produced between forms that normally remain distinct have often been found to be the result of disruption of the environment, usually by humans. Mechanical isolation is a lessimportant type of premating isolation, but it can function in some combinations. Two related animal species, for example, may be mismatched because of differences in size, proportions, or structure of genitalia. Finally, temporal differences often contribute to premating isolation. The commonest type of temporal isolation is seasonal isolation: Species may reproduce at different times of the year. A species of toad in the eastern United States, for example, breeds in the early spring, while a related species breeds in the late spring, with only a short period of overlap. Differences can also involve the time of day, whereby one species may mate at night and another during the day. Such differences, as in the case of ecological isolation, are often incomplete but may be an important component of premating isolation. Postmating Mechanisms If premating mechanisms fail, postmating mechanisms can come into play. If gametes are released, there still may be a failure of fertilization (inter359
Isolating mechanisms sterility). Spermatozoa may fail to penetrate the egg, or even with penetration there may be no fusion of the egg and sperm nucleus. Fertilization failure is almost universal between remotely related species (as from different families or above) and occasionally occurs even between closely related forms. If fertilization does take place, other postmating mechanisms may operate. The hybrid may be inviable (F1 or zygotic inviability). Embryonic development may be abnormal, and the embryo may die at some stage, or the offspring may be defective. In other cases, development may be essentially normal, but the hybrid may be ill-adapted to survive in any available habitat or cannot compete for a mate (hybrid adaptive inferiority). Even if hybrids are produced, they may be partially to totally sterile (hybrid sterility). Hybrids between closely related forms are more likely to be fertile than those between more distantly related species, but the correlation is an inexact one. The causes for hybrid sterility are complex and can involve genetic factors, differences in gene arrangements on the chromosomes that disrupt normal chromosomal pairing and segregation at meiosis, and incompatibilities between cytoplasmic factors and the chromosomes. If the hybrids are fertile and interbreed or backcross to one of the parental forms, a more subtle phenomenon known as hybrid breakdown sometimes occurs. It takes the form of reduced fertility or reduced viability in the offspring. The basis for hybrid breakdown is poorly understood but may result from an imbalance of gene complexes contributed by the two species. It should be emphasized that in most cases of reproductive isolation that have been carefully studied, more than one kind of isolating mechanism has been found to be present. Even though one type is clearly of paramount importance, it is usually supplemented by others, and should it fail, others may come into play. In this sense, reproductive isolation can be viewed as a fail-safe system. A striking difference in the overall pattern of reproductive isolation between animals and plants, however, is the much greater importance of premating isolation in animals and the emphasis on postmating mechanisms in plants. Ethological isolation, taken together with other premating mechanisms, is highly effective in animals, and postmating factors usually function only as a last resort. Field Studies and Experimental Studies Field studies have often been employed in the investigation of some types of premating isolating mechanisms. Differences in such things as breeding times, factors associated with onset of breeding activity, and differences in habitat distribution or selection of a breeding site are all subject to direct 360
Isolating mechanisms field observation. Comparative studies of courtship behavior in the field or laboratory often provide clues as to the types of sensory signals that may be important in the separation of related species. Mating discrimination experiments carried on in the laboratory have often been employed to provide more precise information on the role played by different odors, colors, or patterns, courtship rituals, or sounds in mate selection. Certain pheromones, for example, which act as sexual attractants, have been shown to be highly species-specific in some insects. The presence or absence of certain colors or their presentation has been shown experimentally to be important in mate discrimination in vertebrates as diverse as fish, lizards, and birds. Call discrimination experiments, in which a receptive female is given a choice between recorded calls of males of her own and another species, have demonstrated the critical importance of mating call differences in reproductive isolation in frogs and toads. Synthetically generated calls have sometimes been used to pinpoint the precise call component responsible for the difference in response. Studies on postmating isolating mechanisms have most often involved laboratory crosses in which the degree of intersterility, hybrid sterility, or hybrid inviability can be analyzed under controlled conditions. In instances in which artificial crosses are not feasible, natural hybrids sometimes occur and can be tested. The identification of natural backcross products can attest incomplete postmating, as well as premating isolation. Instances of extensive natural hybridization are of special interest and have often been subjected to particularly close scrutiny. Such cases often throw light on factors that can lead to a breakdown of reproductive isolation. Also, as natural hybridization more often occurs between marginally differentiated forms in earlier stages of speciation, new insights into the process of species formation can sometimes be obtained. Finally, such studies may yield information on the evolutionary role of hybridization, including introgressive hybridization, the leakage of genes from one species into another. Morphological analysis has long been used in such cases, and chromosomal studies are sometimes appropriate. In recent years, allozyme analysis by gel electrophoresis has become a routine tool in estimates of gene exchange, and molecular analysis of nuclear deoxyribonucleic acid (DNA), mitochondrial DNA, have been useful. As mitochondria are normally passed on only maternally, their DNA can also be used to identify cases in which females of only one of the two species has been involved in the breakdown of reproductive isolation. Investigations of the role of natural selection in the development and reinforcement of reproductive isolation have employed two different ap361
Isolating mechanisms proaches. One has involved the measurement of geographic variation in the degree of difference in some signal character (call, color, or pattern, for example) thought to function in premating isolation between two species that have overlapping ranges. If the difference is consistently greater within the zone of overlap (reproductive character displacement), an argument can be made for the operation of reinforcement. Another approach has involved laboratory simulations, usually with the fruit fly Drosophila, in which some type of selective pressure is exerted against offspring produced by crosses between different stocks, and measurement is made of the frequency of mismatings through successive generations. The results of such studies to this time are contradictory, and the role of selection with regard to development of reproductive isolation requires further study. Enhancing Reproductive Efficiency The efficiency of reproduction in most animals is enhanced immeasurably by premating isolating mechanisms. Clearly, in animals a random testing of potential mates without regard to type is totally unacceptable for most species in terms of reproductive capacity and time and energy resources. Premating isolation in this sense is a major factor in promoting species diversity in animal communities. Both premating and postmating isolating mechanisms are also critical to the maintenance of species diversity in that they act to protect the genetic integrity of each form: A species cannot maintain its identity without barriers that prevent the free exchange of genes with other species. Furthermore, a species functions as the primary unit of adaptation. Every species in a community has its own unique combination of adaptive features that enable it to exploit the resources of its environment and to coexist with other species with a minimum of competition. The diversity of different species that can coexist in the same area depends upon the unique “niche” that each occupies; adaptive features that determine that niche are based on the unique genetic constitution of each species, and this genetic constitution is protected through reproductive isolation. The development of reproductive isolating mechanisms is also critical to the formation of new species (speciation), and ultimately to the development of new organic diversity. The most widely accepted, objective, and theoretically operational concept for a sexual species is the biological species concept. Such a species can be defined as population or group of populations, members of which are potentially capable of interbreeding but which are reproductively isolated from other species. The origin of new species, therefore, depends upon the development of reproductive isolating mechanisms between populations. A major focus of research in 362
Isolating mechanisms evolutionary biology and systematics has been, and continues to be, on the various factors that influence the development of reproductive isolating mechanisms. John S. Mecham See also: Adaptive radiation; Biodiversity; Clines, hybrid zones, and introgression; Communication; Convergence and divergence; Evolution: definition and theories; Gene flow; Mammalian social systems; Natural selection; Nonrandom mating, genetic drift, and mutation; Punctuated equilibrium vs. gradualism; Reproductive strategies; Speciation. Sources for Further Study Dobzhansky, Theodosius. Genetics of the Evolutionary Process. New York: Columbia University Press, 1970. Dobzhansky, Theodosius, Francisco J. Ayala, G. Ledyard Stebbins, and James W. Valentine. Evolution. San Francisco: W. H. Freeman, 1977. Mayr, Ernst. Populations, Species, and Evolution. Cambridge, Mass.: Harvard University Press, 1970.
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LAKES AND LIMNOLOGY Types of ecology: Aquatic and marine ecology; Biomes; Ecosystem ecology Lakes are inland bodies of water that fill depressions in the earth’s surface. They are generally too deep to allow vegetation to cover the entire surface and may be fresh or saline. The study of the physical, chemical, climatological, biological, and ecological aspects of lakes is known as limnology. Geological Origin of Lakes Several geologic mechanisms can create the closed basins that are needed to impound water and produce lakes. The most important of these mechanisms include glaciers, landslides, volcanoes, rivers, subsidence, and tectonic processes. Continental glaciers formed thousands of lakes by the damming of stream valleys with moraine materials. Glaciers also scoured depressions in softer bedrock, and these later filled with water to form lakes. Depressions called kettles formed when buried ice blocks melted. Mountain glaciers also produce numerous small, high alpine lakes by plucking away bedrock. The bowl-shaped depressions that occur as a result of this plucking are called cirques; lakes that occupy cirques are called tarns. Sometimes a mountain glacier moves down a valley and carves a series of depressions along the valley that, from above, look like a row of beads along a string. When these depressions later fill with water, the lakes are called paternoster lakes, the name coming from their similarity to beads on a rosary. Landslides sometimes form natural dams across stream valleys. Large lakes then pond up behind the dam. Volcanoes may produce lava flows that dam stream valleys and produce lakes. A volcanic explosion crater may fill with water and make a lake. After an eruption, the area around the eruption vent may collapse to form a depression called a caldera. Some calderas, such as Crater Lake in Oregon, fill with water. Rivers produce lakes along their valleys when a tight loop of a meandering channel finally is eroded through and leaves behind an oxbow lake, isolated from the main channel. Sediment may accumulate at the mouth of a stream, and the resulting delta may build, bridging across irregularities in the shoreline to create a brackish coastal lake. Natural subsidence creates closed basins in areas underlain by soluble limestones or evaporite deposits. As the underlying limestone is dissolved away, the earth above collapses to form a cavity (sinkhole), which later fills 364
Lakes and limnology with water. Finally, large-scale (tectonic) downwarping of the earth’s crust produces some very large lakes. Large basins form when the crust warps or sinks downward in response to deep forces. The subsidence produces very large closed basins that can hold water. A few immense lakes owe their origins to tectonic downwarping. Sedimentation With few exceptions, most lakes exist in relatively small depressions and serve as the catch basins for sediment from the entire watershed around them. The natural process of sedimentation ensures that most lakes fill with sediment before very long periods of geologic time have passed. Lakes with areas of only a few square kilometers or less will fill within a few tens of thousands of years. Very large lakes, the inland seas, may endure for more than ten million years. Human-made lakes and reservoirs have unusually high sediment-fill rates in comparison with most natural lakes. Humanmade lakes fill with sediment within a few decades to a few centuries. Lake sediments come from four sources: allogenic clastic materials that are washed in from the surrounding watershed; endogenic chemical precipitates that are produced from dissolved substances in the lake waters;
Lakes offer rich habitats for complex ecosystems comprising organisms that live on land, in water, or in both environments. Depending on their elevation, lakes can support wildlife typical of taiga, such as freshwater fish and bears, or lower elevations, such as migratory seabirds. (Digital Stock) 365
Lakes and limnology endogenic biogenic organic materials produced by plants and animals living in the lake; and airborne substances, such as dust and pollen, transported to the lake in the atmosphere. Allogenic clastic materials are mostly minerals; they are produced when rocks and soils in the drainage basin are weathered by mechanical and chemical processes to yield small particles. These particles are moved downslope by gravity and running water to enter streams, which then transport them to the lake. Clastic materials also enter the lake via waves, which erode the materials from the shoreline, and via landslides that directly enter the lake. In winter, ice formed on the lake can expand and push its way a few centimeters to 1 meter or so onto the shore. There, the ice may pick up large particles, such as gravel and cobbles. When spring thaw comes, waves can remove that ice, together with its enclosed particles, and float it out onto the lake. The process by which the large particles are transported out on the lake is called ice-rafting. As the ice melts, the large clastic particles drop to the bottom; they are termed dropstones when found in lake sediments. A landslide into a lake or a flood on a stream that feeds into the lake can produce water heavily laden with sediment. The sedimentladen water is more dense than clean water and therefore can rush down and across the lake bottom at speeds sufficient to carry even coarse sand far out into the lake. These types of deposits are called turbidite deposits. Endogenic chemical precipitates in freshwater lakes commonly consist of carbonate minerals (calcite, aragonite, or dolomite) and mineraloids that consist of oxides and hydroxides of iron, manganese, and aluminum. In some saline and brine lakes, the main sediments may be carbonates, together with sulfates such as gypsum (hydrated calcium sulfate), thenardite (sodium sulfate), or epsomite (hydrated magnesium sulfate), or with chlorides such as halite (sodium chloride) or more complex salts. Of the endogenic precipitates, calcite is the most abundant. Its precipitation represents a balance between the composition of the atmosphere and that of the lake water. Diatoms are distinctive microscopic algae that produce a frustule (a kind of shell) made of silica glass that is highly resistant to weathering. When seen under a high-powered microscope, diatom frustules appear to be artwork—beautiful and highly ornate saucer- and pen-shaped works of glass. A tiny spot of lake sediment may contain millions. A lake’s sediment may contain from less than 1 percent to more than 90 percent organic materials, depending upon the type of lake. Most organic matter in lake sediments is produced within the lake by plankton and consists of compounds such as carbohydrates, proteins, oils, and waxes that are made up of organic carbon, hydrogen, nitrogen, and oxygen, with a lit366
Lakes and limnology tle phosphorus. Plankton, with an approximate bulk composition of 36 percent carbon, 7 percent hydrogen, 50 percent oxygen, 6 percent nitrogen, and 1 percent phosphorus (by weight), includes microscopic plants (phytoplankton) and microscopic animals (zooplankton) that live in the water column. Lakes that are very high in nutrients (eutrophic lakes) commonly have heavy blooms of algae, which contribute much organic matter to the bottom sediment. Terrestrial (land-derived) organic material such as leaves, bark, and twigs form a minor part of the organic matter found in most lakes. Terrestrial organic material is higher in carbon and lower in hydrogen, nitrogen, and phosphorus than is planktonic organic matter. Airborne substances usually constitute only a tiny fraction of lake sediment. The most important material is pollen and spores. Pollen usually constitutes less than 1 percent of the total sediments, but that tiny amount is a very useful component for learning about the recent climates of the earth. Pollen is among the most durable of all natural materials. It survives attack by air, water, and even strong acids and bases. Therefore, it remains in the sediment through geologic time. As pollen accumulates in the bottom sediment, the lake serves as a kind of recorder for the vegetation that exists around it at a given time. By taking a long core of the bottom sediment from certain types of lakes, a geologist may look at the pollen changes that have occurred through time and reconstruct the history of the climate and vegetation in an area. Volcanic ash thrown into the atmosphere during eruptions enters lakes and forms a discrete layer of ash on the lake bottom. When Mount St. Helens erupted in 1980, it deposited several centimeters of ash in lakes more than 160 kilometers east of the volcano. Geologists have used layers of ash in lakes to reconstruct the history of volcanic eruptions in some areas. Although dust storms contribute sediment to lakes, such storms are usually too infrequent in most areas to contribute significant amounts. Water Circulation Lake waters are driven into circulation by temperature-induced density changes and wind. Most freshwater lakes in temperate climates circulate completely twice each year; they are termed dimictic lakes. Circulation exerts a profound influence on water chemistry of the lake and the amount and type of sediment present within the water column. During summer stratification, the lake is thermally stratified into three zones. The upper layer of warm water (epilimnion) floats above the denser cold water and prevents wind-driven circulation from penetrating much below the epilimnion. The epilimnion is usually in circulation, is rich in oxygen (from algal photosynthesis and diffusion from the atmosphere), and is well 367
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Riparian ecosystems vary widely, depending on the course of the river. Upper courses, at higher and colder elevations, typically run faster and are highly oxygenated, supporting trout, bass, salmon, and other freshwater fish and their predators, but not as many grasses, for example, as middle or lower courses and estuaries. (PhotoDisc)
lighted. This layer is where summer blooms of green and blue-green algae occur and calcite precipitation begins. The middle layer (thermocline) is a transition zone in which the water cools downward at a rate of greater than 1 degree Celsius per meter. The bottom layer (hypolimnion) is cold, dark, stagnant, and usually poor in oxygen. There, bacteria decompose the bottom sediment and release phosphorus, manganese, iron, silica, and other constituents into the hypolimnion. Sediment deposited in summer includes a large amount of organic matter, clastic materials washed in during summer rainstorms, and endogenic carbonate minerals produced within the lake. The most common carbonate mineral is calcite (calcium carbonate). The regular deposition of calcite in the summer is an example of cyclic sedimentation, a sedimentary event that occurs at regular time intervals. This event occurs yearly in the summer season and takes place in the upper 2 or 3 meters of water. On satellite photos, it is even possible to see the summer events as whitings on large lakes, such as Lake Michigan. As the sediment falls through the water column in summer, it passes through the thermocline into the hypolimnion and onto the lake bottom. 368
Lakes and limnology As it sits on the bottom during the summer months, bacteria, particularly anaerobic bacteria (those that thrive in oxygen-poor environments), begin to decompose the organic matter. As this occurs, the dissolved carbon dioxide increases in the hypolimnion. If enough carbon dioxide is produced, the hypolimnion becomes slightly acidic, and calcite and other carbonates that fell to the bottom begin to dissolve. The acidic conditions also release dissolved phosphorus, calcium, iron, and manganese into the hypolimnion, as well as some trace metals. Clastic minerals such as quartz, feldspar, and clay minerals are not affected in such brief seasonal processes, but some silica from biogenic material such as diatom frustules can dissolve and enrich the hypolimnion in silica. As summer progresses, the hypolimnion becomes more and more enriched in dissolved metals and nutrients. Autumn circulation begins when the water temperature cools and the density of the epilimnion increases until it reaches the same temperature and density as the deep water. Thereafter, there is no stratification to prevent the wind from circulating the entire lake. When this happens, the cold, stagnant hypolimnion, now rich in dissolved substances, is swept into circulation with the rest of the lake water. The dissolved materials from the hypolimnion are mixed into a well-oxygenated water column. Iron and manganese that formerly were present in dissolved form now oxidize to form tiny solid particles of manganese oxides, iron oxides, and hydroxides. The sediment therefore becomes enriched in iron, manganese, or both during the autumn overturn, the amount of enrichment depending upon the amount of dissolved iron and manganese that accumulated during summer in the hypolimnion. Dissolved silica is also swept from the hypolimnion into the entire water column. In the upper water column, where sunlight and dissolved silica become present in great abundance, diatom blooms occur. The diatoms convert the dissolved silica into solid opaline frustules. As circulation proceeds, the currents may sweep over the lake bottom and actually resuspend 1 centimeter or more of sediment from the bottom and margins of the lake. The amount of resuspension that occurs each year in freshwater lakes is primarily the result of the shape of the lake basin. A lake that has a large surface area and is very shallow permits wind to keep the lake in constant circulation over long periods of the year. As winter stratification comes, an ice cover forms over the lake and prevents any wind-induced circulation. Because the circulation is what keeps the lake sediment in suspension, most sediment quickly falls to the bottom; sedimentation then is minimal through the rest of winter. If light can penetrate the ice and snow, some algae and diatoms can utilize this weak light, 369
Lakes and limnology present in the layer of water just below the ice, to reproduce. Their settling remains contribute small amounts of organic matter and diatom frustules. At the lake bottom, the most dense water (that at 4 degrees Celsius) accumulates. As in summer, some dissolved nutrients and metals can build up in this deep layer, but because the bacteria that are active in releasing these substances from the sediment are refrigerated, they work slowly, and not as much dissolved material builds up in the bottom waters. When spring circulation begins, the ice at the surface melts, and the lake again goes into wind-driven circulation. Oxidation of iron and manganese occurs (as in autumn), although the amounts of dissolved materials available are likely to be less in spring. Once again, nutrients such as phosphorus and silica are circulated out of the dark bottom waters and become available to produce blooms of phytoplankton. Spring rains often hasten the melting, and runoff from rain and snowmelt in the drainage basin washes clastic materials into the lake. The period of spring thaw is likely to be the time of year when the maximum amount of new allogenic (externally derived) sediment enters the lake. Spring diatom blooms continue until summer stratification prevents further replenishment of silica to the epilimnion. Thereafter, the diatoms are succeeded by summer blooms of green algae, closely followed by blooms of blue-green algae. Silica is usually the limiting nutrient for diatoms; phosphorus is the limiting nutrient for green and blue-green algae. Diagenesis After sediments are buried, changes occur; this process of change after burial is termed diagenesis. Physical changes include compaction and dewatering. Bacteria decompose much organic matter and produce gases such as methane, hydrogen sulfide, and carbon dioxide. The “rotten-egg” odor of black lake sediments, often noticed on boat anchors, is the odor of hydrogen sulfide. After long periods of time, minerals such as quartz or calcite slowly fill the pores remaining after compaction. One of the first diagenetic minerals to form is pyrite (iron sulfide). Much pyrite occurs in microscopic spherical bodies that look like raspberries; these particles, called framboids, are probably formed by bacteria in areas with low oxygen within a few weeks. In fact, the black color of some lake muds and oozes results as much from iron sulfides as from organic matter. Other diagenetic changes include the conversion of mineraloid particles containing phosphorus into phosphate minerals such as vivianite and apatite. Manganese oxides may be converted into manganese carbonates (rhodochrosite). Freshwater manganese oxide nodules may form in highenergy environments such as Grand Traverse Bay in Lake Michigan. 370
Lakes and limnology Lake Ecosystems Freshwater and saline lakes account for 0.009 and 0.008 percent of the total amount of water in the world, respectively. Although this is a minute fraction of the world’s water—almost all of it is in the oceans and in glaciers— lakes are an extremely valuable resource. In terms of ecosystems, lakes are divided into a pelagial (open-water) zone and a littoral (shore) zone where macrovegetation grows. Sediments free of vegetation that occur below the pelagial zone are in the profundal zone. The renewal times for freshwater and saline lakes range from 1 to 100 years and 10 to 1,000 years, respectively. The length of time varies directly with lake volume and average depth, and indirectly with a lake’s rate of discharge. The rate of renewal, or turnover time, for lakes is much less than that of oceans and glacial ice, which is measured in thousands of years. Eutrophication The aging of a lake by biological enrichment is known as eutrophication. The water in young lakes is cold and clear, with minimal amounts of plant and animal life. The lake is then in the oligotrophic state. As time goes on, streams that flow into the lake bring in nutrients such as nitrates and phosphates, which encourage aquatic plant growth. As the fertility in the lake increases, the plant and animal life increases, and organic remains start accumulating on the bottom. The lake is now becoming eutrophic. Silt and organic debris continue to accumulate over time, slowly making the lake shallower. Marsh plants that thrive in shallow water start expanding and gradually fill in the original lake basin. Eventually the lake becomes a bog and then dry land. This natural aging of a lake can take thousands of years, depending upon the size of the lake, the local climate, and other factors. However, human activities can substantially accelerate the eutrophication process. Among the problems caused by humans are the pollution of lakes by nutrients from agricultural runoff and poorly treated wastewater from municipalities and industries. The nutrients encourage algal growth, which clogs the lake and removes dissolved oxygen from the water. The oxygen is needed for other forms of aquatic life. The lake has now entered a hypereutrophic state as declining levels of dissolved oxygen result in incomplete oxidation of plant remains, a situation that eventually causes the death of the lake as a functioning aquatic ecosystem. In a real sense, the lake chokes itself to death. Research Methods Scientists who study lakes (limnologists) must study all the natural 371
Lakes and limnology sciences—physics, chemistry, biology, meteorology, and geology—because lakes are complex systems that include biological communities, changing water chemistry, geological processes, and interaction among water, sunlight, and the atmosphere. Many who study ecology become limnologists, and vice versa. Limnologists study modern lake sediments by collecting samples from the water column in sediment traps (cylinders and funnels into which the suspended sediment settles over periods of days or weeks) or by filtering large quantities of lake water. Living material is often sampled with a plankton net. Older sediments that have accumulated on the bottom are collected with dredges and by piston coring, which involves pushing a sharpened hollow tube (usually about 2.5 centimeters in diameter) downward into the sediment. Cores are valuable because they preserve the sediment in the order in which it was deposited, from oldest at the bottom to youngest at the top. Once the sample is collected, it is often frozen and taken to the laboratory. There, pollen and organisms may be examined by microscopy, minerals may be determined by X-ray diffraction, and chemical analyses may be made. Varves are thin laminae that are deposited by cyclic processes. In freshwater lakes, each varve represents one year’s deposit; it consists of a couplet with a dark layer of organic matter deposited in winter and a lightcolored layer of calcite deposited in summer. Varves are deposited in lakes where annual circulations cannot resuspend bottom sediment and therefore cannot mix it to destroy the annual lamination. Some lakes that are small and very deep may produce varved sediments; Elk Lake in Minnesota is an example. In other lakes, the accumulation of dissolved salts on the bottom eventually produces a dense layer (monimolimnion), which prevents disturbance of the bottom by circulation in the overlying fresher waters. Soap Lake in Washington State is an example. Because each varve couplet represents one year, a geologist may core the sediments from a varved lake and count the couplets to determine the age of the sediment in any part of the core. The pollen, the chemistry, the diatoms, and other constituents may then be carefully examined to deduce what the lake was like during a given time period. The study is much like solving a mystery from a variety of clues. Eventually, the history of climate changes of the area may be learned from the study of lake varves. Edward B. Nuhfer and Robert Hordon See also: Acid deposition; Ecosystems: definition and history; Eutrophication; Habitats and biomes; Marine biomes; Ocean pollution and oil spills; Reefs; Wetlands. 372
Lakes and limnology Sources for Further Study Bramwell, Martyn. Rivers and Lakes. London: Franklin Watts, 1986. Burgis, Mary J., and Pat Morris. The Natural History of Lakes. New York: Cambridge University Press, 1987. Cole, Gerald A. Textbook of Limnology. 4th ed. Prospect Heights, Ill.: Waveland Press, 1994. Fraser, Andrew S., Michael Meybeck, and Edwin D. Ongley. Water Quality of World River Basins. 14th ed. New York: United Nations Publications, 1998. Håkanson, Lars, and M. Jansson. Principles of Lake Sedimentology. New York: Springer-Verlag, 1983. Horne, Alexander J., and Charles R. Goldman. Limnology. 2d ed. New York: McGraw-Hill, 1994. Imberger, Jeorg, ed. Physical Processes in Lakes and Oceans. Washington, D.C.: American Geophysical Union, 1998. Lerman, Abraham, Dieter M. Imboden, and Joel R. Gat, eds. Physics and Chemistry of Lakes. New York: Springer-Verlag, 1995. Thornton, Kent W., Bruce L. Kimmel, and Forrest E. Payne, eds. Reservoir Limnology: Ecological Perspectives. New York: John Wiley, 1990. U.S. Environmental Protection Agency. The Great Lakes: An Environmental Atlas and Resource Book. Chicago: Great Lakes Program Office, 1995. Wetzel, Robert G. Limnology. 3d ed. San Diego: Academic Press, 2001.
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LANDSCAPE ECOLOGY Type of ecology: Landscape ecology Humans live in natural landscapes that they have modified and managed to suit their own needs of shelter, security, aesthetics, and usefulness. The science of managing the habitat components of modified landscapes is called landscape ecology, a burgeoning field concerned with preserving the naturalness of modified landscapes while minimizing the negative impact of human intrusion in natural habitats within these landscapes.
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nowledge of landscape ecology is fundamentally important for a number of reasons: natural resource planning, residential and commercial development, wildlife conservation, forestry, agriculture, soil science, ecological function, sociobiology, and the structure of urban and suburban habitats are all elements of landscape ecology of continuing environmental and economic interest to humans. Structurally, landscapes share four components: patches of habitat, corridors that connect patches of habitat, the background matrix that includes patches and corridors, and the wildlife that inhabits the landscape. Humans and natural processes constantly modify each of these landscape components. From an ecological standpoint, humans most impact landscapes by fragmenting large blocks of natural habitat into landscapes consisting of patches of natural habitat, patches of modified habitat, and developed areas. For example, a forested landscape may be transformed into a mosaic of woodland patches, farms, residences, parks, preserves, and greenbelts— the whole typically crossed and gridworked by artificial corridors of roadways, power lines, and gas lines along with natural corridors such as rivers, streams, and fence rows. Some important management issues in landscape ecology include preserving existing wildlife and wildlife habitats, maintaining and improving wildlife habitat and biodiversity, minimizing detrimental impacts of habitat fragmentation, creating natural corridors for wildlife movement between habitats, and creating and managing wildlife parks and preserves in human modified landscapes. Landscape Fragmentation The splitting of a contiguous area of natural landscape into two or more smaller blocks of habitat is called landscape fragmentation. The smaller 374
Landscape ecology habitat parcels that result are called fragments or patches. As human populations grow they appropriate more and more of the natural landscape to accommodate their immediate needs for housing and agriculture, thus the rate of landscape fragmentation continues to increase. Because human populations are projected to grow for several more decades, at least, landscape fragmentation is considered to be a global wildlife and wildlife habitat issue of immediate and serious concern. Natural processes such as floods, ice storms, winds, and landslides contribute to landscape fragmentation, but the vast majority of fragmentation occurs through human activities. Logging, agriculture, roadways, rail lines, power lines, gas lines, trails, the construction of houses, housing clusters, commercial and industrial developments are all some of the ways in which humans fragment natural habitats. The Patchwork Mosaic Habitat fragmentation ultimately results in a landscape mosaic comprising a patchwork of artificial and natural habitats strewn across the landscape often in haphazard and unplanned fashion. Natural habitats, slightly modified habitats, and totally altered habitats and the corridors that connect them juxtaposition one another. The interrelationships of these natural and modified patches with respect to size, shape, and connectivity can have profound impacts that collectively tend to limit natural habitats within the landscape and the wildlife that occur in those natural habitats. Some of the more important of these constraints include the decline or elimination of habitat specialists or area-sensitive species, the invasion of natural habitat patches by domestic, exotic, or alien species, the increased mortality of natural species caused by vehicles or predation by pets and feral animals, and the disturbance of reproductive efforts and other natural behaviors by the range of activities that invariably accompany human intrusion into and modification of, natural landscapes. Initially, landscape fragmentation increases the number and variety of habitat patches within a landscape, thereby increasing habitat diversity. The many small patches provide “stepping stones” that promote species dispersal and interchange from one patch to another which in turn promotes gene flow between patches. Small patches may also provide habitat for certain familiar species, such as the American robin (Turdus migratorius) and gray catbird (Dumetella carolinensis), that use the edges of small patches for foraging, nesting, or refuges. Also, a large number of small patches may reduce erosion and ultimately loss of natural habitats that so often accompanies human activity and intrusion. However, continued landscape fragmentation results in ever smaller 375
Landscape ecology
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habitat patches that necessarily support fewer species and smaller wildlife populations, thereby increasing the risk of extinction of remaining species. As habitat patches shrink in size or disappear, the remaining habitat patches become increasingly isolated, inhibiting wildlife interchange between patches and making recolonization of the more remote habitat patches increasingly difficult. As habitat patches diminish in size, species populations begin to disappear. The first to go are the species that need large areas for their activities such as predators that require large territories for their food base. Thus, as patches shrink to a critical point the area cannot support sufficient prey populations to sustain viable populations of larger predators, such as northern goshawks (Accipiter gentilis) or red-shouldered hawk (Buto lineatus). Area-sensitive species and interior species are also increasingly placed at risk. Area-sensitive species such as the Carolina chickadee (Poecile atricapilla) and eastern wood-peewee (Contopus virens) require large areas of undisturbed habitat for nesting, foraging, and other activities. As habitat patches decline in size, the numbers of these species dramatically decrease. Interior species such as the ovenbird (Seiurus aurocapillus) select habitats deep within the interior of natural habitats. As the size of habitat patches decreases, there is insufficient amount of core area needed to sustain their activities. The decline in populations of many neotropical migrants that nest in woodlands of Eastern North America is attributed to habitat fragmentation. 376
Landscape ecology The transformation of natural landscapes into human and natural patches almost always creates a modified habitat suitable for intrusive species that are tolerant of humans and human-modified landscapes, such as the house sparrow (Passer domesticus), Eurasian starling (Sturnis vulgaris), raccoon (Procyon lotor), and opossum (Didelphis virginiana), all of which are behaviorally adapted to exploit the modified landscapes. Landscape modification also provides an environment for pets that inevitably accompany human intrusions, such as house cats (Felis catus) and dogs (Canis familiaris), both of which may predate natural wildlife species. Both intrusive and domesticated species reduce biodiversity either through outright predation or by competition. A critical concern to landscape ecologists involves the ratio of edge habitat to interior habitat in habitat patches resulting from fragmentation. As habitat patches get smaller, the ratio of edge habitat to interior habitat of each patch increases. Greater edge habitat provides favorable habitat for game and other edge species, but interior species and area-sensitive species are placed at increased risk because predators, scavengers, and parasitic species can now penetrate farther into the interior of the habitat patch. Some of the more familiar and important avian edge species in terms of their impacts on interior species include the brown-head cowbird (Molothrus ater) and the blue jay (Cyanocitta cristata). Two of the many species of mammals that frequent edge habitat and may become nuisance species in human-modified landscapes include the raccoon and the opossum. The potential impact of edge species on interior species is exemplified by a small blackbird with a distinctive brown head called the brownheaded cowbird. The cowbird is a brood parasite that frequents open woodland, grasslands, and forest edge. Unlike other birds, the cowbird does not build a nest but rather deposits its eggs in the nests of other birds, especially flycatchers, vireos, warblers, orioles, and finches. Female brownheaded cowbirds visit nests of potential host species during construction. Once the host bird lays its clutch, the female cowbird visits the nest and removes one or more of the eggs, either by eating them or by dropping them over the edge of the nest cup. She always leaves one egg—otherwise the host might not return. She then deposits a single egg in the host nest. The host female returns and incubates the clutch, which now includes the cowbird egg. The cowbird egg hatches a day or two before the other eggs in the nest and the young grows quickly, demanding and receiving a large portion of the food that the host adult birds bring to the nestlings. The impact of cowbird brood parasitism increases with increasing landscape fragmentation. As patches get smaller the ratio of edge habitat to core habitat in a given habitat patch increases, exposing more of the interior to cowbird ac377
Landscape ecology tivity. Cowbirds penetrate deeper into habitats to parasitize more nests of interior species. In fact, increased cowbird brood parasitism accompanying habitat fragmentation is one reason that interior woodland species such as wood warblers are thought to be declining. Corridors and Connectivity Corridors are links of natural habitats that connect landscape patches to one another. Examples of corridors include areas of vegetation left undeveloped by human disturbance such as belts of vegetation along rivers and streams, vegetated strips along roadways, railways, and drainage ditches, vegetation strips beneath power lines and above gas lines, and linear extensions of vegetated areas such as windbreaks, fence rows, and hedgerows. Corridors are critically important elements of landscape ecology that help maintain stability and diversity of wildlife within each of the natural patches by providing dispersal routes for plants and animals between habitat patches. The ability of wildlife to use these corridors to disperse from one habitat patch to another is called connectivity. Larger patches that support larger species populations serve as the source of individuals that disperse along corridors to repopulate or augment species populations in smaller patches, where species populations are low, are declining in numbers, or have been extirpated. Corridors of natural vegetation promote movement of organisms from one habitat patch by reducing their vulnerability during dispersal. Corridors also facilitate gene flow between wildlife populations in each patch, reducing the change of inbreeding depression. Conversely, lack of corridors or low corridor connectivity puts dispersing wildlife at greater risk. For example, if vegetated corridors are lacking woodland, animals must cross open areas to disperse from one woodland habitat patch to another, increasing their vulnerability to predators. Some animals, such as certain amphibians and reptiles, may be unable to disperse from one habitat patch to another if connecting corridors are not available. Corridor width is also an important consideration in landscape ecology. Narrow corridors increase the potential for intrusion of domestic animals such as cats and dogs along and into the corridor, making wildlife dispersal more difficult and more dangerous. Narrow corridors may also contribute to poaching of larger animals, which are more visible and therefore more vulnerable during their dispersal within the confines of narrow corridors. However, low connectivity also decreases the rate of spread of invasive species and pests, reduces the dispersal of pollutants, thereby enhancing survival of interior species that occupy patches. 378
Landscape ecology Some types of natural corridors also have distinct ecological characteristics that contribute to the overall species and landscape biodiversity in a given landscape. For example, belts of vegetation along rivers and streams form a distinctive ecological habitat called a riparian community that is inhabited by riparian species as well as edge and dispersal species. Parks and Preserves as Landscape Components Parks and preserves are natural units of landscape that have been deliberately set aside as protected parcels in an attempt to maintain ecologically functioning communities of plants and animals. Their size is usually a consequence of how valuable the land is that is being set aside, the value that humans place on wildlife and wildlife communities, the types of land that can be set aside, and the economic sacrifices that humans are willing to make to ensure that natural wildlife communities are protected. Much of the debate over size of parks and preserves has focused on whether to establish a single large preserve or several small preserves. This debate is sometimes called the SLOSS controversy, the acronym standing for “single larger or several smaller” preserves. Large preserves are favored by many ecologists because they provide greater amounts of natural habitat that can provide the resource base needed to support greater wildlife diversity and also larger populations of each plant and animal species. A larger species population reduces the risk of extinction or extirpation due to chance events such as skewed sex ratios or poor reproductive rates in a given year or set of years. A major drawback of a single large preserve, however, is that all of the wildlife of an area is concentrated within a limited landscape that can be destroyed by a single catastrophe such as a severe rainstorm, floods, fires, ice storms, heavy snowfall, landslides, and other natural catastrophes. Furthermore, concentration of wildlife populations in a single large preserve exposes all of the members of a species population to risk from pollutants, chance appearance of competitors, or invasion of exotic species. The alternate choice of creating several small preserves distributes members of a species population among several preserves rather than concentrating them all in a single large preserve. This greatly reduces the chance that a catastrophe will eliminate the wildlife population, as it is extremely unlikely that a chance catastrophe will impact all of the smaller preserves simultaneously. However, the smaller resource base of a smaller preserve automatically limits numbers of individuals in each species population, thereby greatly increasing risk of extirpation of a given species population in a smaller preserve due to chance events. For example, small populations face increased risks of genetic inbreeding, the chance accumu379
Landscape ecology lation of deleterious mutations, and genetic drift. Environmentally, smaller species populations are also more susceptible to disease, the introduction of predators, and the possibility of a skewed sex ratio that results in low reproduction in a given generation. To compensate for the increased risk of wildlife extinction in smaller preserves, landscape ecologists must provide corridors to connect preserves with one another, thereby promoting wildlife movement between preserves. Managing and maintaining parks and preserves and their connecting corridors depends on several factors. Virtually all parks and preserves in urban and suburban landscapes require developing and implementing management strategies to ensure that disturbances from adjacent humanmodified habitats is minimized. Rare habitats or habitats that contain rare or endangered wildlife must be managed differently from open-space parcels that contain common and widespread species. In some locales, parks and preserves may best be managed under the multiple-use concept, functioning simultaneously as wildlife preserves and as areas that provide recreational opportunities for hiking, biking, bird-watching, and wildlife appreciation. Dwight G. Smith Sources for Further Study Forman, Richard T. T., and M. Godron. Landscape Ecology. New York: John Wiley & Sons, 1986. Forman, Richard T. T. Land Mosaics: The Ecology of Landscapes and Regions. New York: Cambridge University Press, 1995. Gardner, R. H., R. V. O’Neill, and M. G. Turner. Landscape Ecology in Theory and Practice. New York: Springer, 2001. Garner, H. F. The Origin of Landscapes: A Synthesis of Geomorphology. New York: Oxford University Press, 1974. Gergel, S. E., and Monica G. Turner, eds. Learning Landscape Ecology: A Practical Guide to Concepts and Techniques. New York: Springer, 2001. Gutzwiller, K. J. Applying Landscape Ecology in Biological Conservation. New York: Springer, 2002. Jongman, R. H. G., C. J. F. Ter Braak, and P. F. R. Van Tongeren. Data Analysis in Communities and Landscape Ecology. New York: Cambridge University Press, 1995.
380
LICHENS Type of ecology: Community ecology Lichens are an example of a very specialized “ecosystem” composed of two distinct species, a fungus and a photosynthetic alga (or bacterium) that have coevolved to live in a symbiotic relationship with each other in a community that grows on rocks, trees, and other substrates.
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ichens are classified as members of the kingdom Fungi, with most being placed under the phyla Ascomycota and Basidiomycota. It is estimated there are seventeen thousand species of lichen, representatives of which have been found nearly everywhere in the world. Symbiosis Symbiosis is an extreme form of an ecological relationship or mutualism between members of different species, in which each partner in the union derives benefits from the other. In symbiotic unions, the partners are so dependent on each other they can no longer independently survive. In lichens, the fungal (mycobiont) symbiont provides protection, while the green-algal or cyanobacterial (photobiont) symbiont provides sugars, created by photosynthesis. It is often suggested that the fungus in lichen species might also pass water and nutrients to the photobiont, but this function is less well documented. This special relationship allows lichens to survive in many environments, such as hot deserts and frozen Arctic tundra, that are inhospitable to most other life-forms. As a result, the lichen whole is greater than the sum of its parts. While in nature lichen partners always exist together, under laboratory conditions it is possible to take the lichen apart and grow the two partners separately. Anatomy Whereas in most plant species the anatomy of the organism is identified with structures associated with a single vegetative body, the “lichen body” is more aptly described as a colony of cells that share a variety of associations with one another that vary from one species of lichen to the next. In some species of lichen, fungal and algal cells merely coexist. Coenogonium leprieurii, for example, is a lichen that lives in low-light tropical and subtropical forests in which the filamentous green-algal partner (Trebouxia) is dominant. 381
Lichens In most lichen species, however, the relationship between the symbiotic partners is more intimate, with the lichen body appearing to be a single entity. In these species the algal symbiont has no cell walls and is penetrated by filaments, or haustoria, from the fungal symbiont. The haustoria pass sugars from the algal cell to the fungal cell and may have a role in the transportation of water and nutrients from the fungal cell back to the algal cell. This integration is so complete that many naturalists prior to the nineteenth century mistakenly classified lichens as mosses. In most lichen species it is nevertheless possible, with a good magnifying device, to identify several distinct regions of the thallus or lichen body. The outermost region is the cortex, a compacted layer composed of short, thick hyphae (widely dilated filaments) of the fungal symbionts that protect the lichen from abiotic factors in its environment. These hyphae extend downward into a second region, the photobiont layer, where they surround the algal symbionts. Below this is a third region, the medulla, composed of a loosely woven network of hyphae. Underneath this is a fourth region, the undercortex, that is similar in appearance and structure to the cortex. The bottom of the lichen body is com-
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382
Lichens posed of rhizines, rootlike structures composed of bundles of hyphae that attach the lichen to its substrate (the rock, bark, or other support on which it resides). This arrangement of regions into layers serves to prevent water loss. Many species can survive complete desiccation, coming back to life when water becomes available again. The cortex also contains pseudocyphellae, which are pores that allow for the exchange of gases necessary for photosynthesis. Life Cycle Lichens typically live for ten years or more, and in some species the lichen body can survive for more than a hundred years. Reproduction in most fungal species proceeds by the development of a cup- or saucer-shaped fruiting body called an apothecium, which releases fungal spores to its surrounding. Procreation in lichens is more problematic, in that the fungal offspring must also receive the right algal symbiont if they are to survive. The most common form of dispersion in lichen is by the accidental breaking off of small pieces of the thallus called isidia, which are then spread by wind to new substrates. In some species, small outgrowths of the thallus known as soralia arise, composed of both fungi and algae and surrounded by hyphae, to form soredia, which after dispersion give rise to a new thallus. Ecological and Economic Importance Lichens not only demonstrate some basic ecological concepts, such as mutualism and symbiosis, but also are excellent bioindicators of air pollution, as many species are particularly sensitive to certain contaminants in their surroundings, such as sulfur dioxide. They also play an important role in tundra biomes, functioning as a major source of food for reindeer and cattle in Lapland. One species of lichen (Umbilicaria esculenta) is considered a delicacy in Japan. Historically, lichens have been used as pigments for the dying of wool. The medical properties of some species of lichens for lung disease and rabies have led to a renewed interest in them. David W. Rudge See also: Animal-plant interactions; Coevolution; Communities: ecosystem interactions; Communities: structure; Convergence and divergence; Food chains and webs; Mycorrhizae; Symbiosis; Trophic levels and ecological niches. Sources for Further Study Brodo, Irwin M., Sylvia Duran Sharnoff, and Stephen Sharnoff. Lichens of North America. New Haven, Conn.: Yale University Press, 2001. 383
Lichens Dobson, Frank. Lichens: An Illustrated Guide. Richmond, Surrey, England: Richmond, 1981. Hale, Mason E., Jr. The Biology of Lichens. 3d ed. London: Edward Arnold, 1983. Hawksworth, D. L., and D. J. Hill. The Lichen-Forming Fungi. New York: Blackie & Son, 1984. Purvis, William. Lichens. Washington, D.C.: Smithsonian Institution Press, 2000.
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Ecology Basics
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MAGILL’S C H O I C E
Ecology Basics Volume 2 Mammalian social systems—Zoos Appendices Indexes
edited by
The Editors of Salem Press
Salem Press, Inc. Pasadena, California Hackensack, New Jersey
Copyright © 2004, by Salem Press, Inc. All rights in this book are reserved. No part of this work may be used or reproduced in any manner whatsoever or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without written permission from the copyright owner except in the case of brief quotations embodied in critical articles and reviews. For information address the publisher, Salem Press, Inc., P.O. Box 50062, Pasadena, California 91115. ∞ The paper used in these volumes conforms to the American National Standard for Permanence of Paper for Printed Library Materials, Z39.48-1992 (R1997). Library of Congress Cataloging-in-Publication Data Ecology basics / edited by the editors of Salem Press. p. cm. — (Magill’s choice) Includes bibliographical references. ISBN 1-58765-174-2 (set : alk. paper) — ISBN 1-58765-175-0 (v. 1 : alk. paper) — ISBN 1-58765-176-9 (v. 2 : alk. paper) 1. Ecology—Encyclopedias. I. Salem Press. II. Series. QH540.4.E39 2003 577′.03—dc21 2003011370
First Printing
printed in the united states of america
Contents Complete List of Contents . . . . . . . . . . . . . . . . . . . . . . . . . xxix Mammalian social systems Marine biomes . . . . . . . Mediterranean scrub . . . Metabolites . . . . . . . . . Migration . . . . . . . . . . Mimicry . . . . . . . . . . Mountain ecosystems . . . Multiple-use approach . . Mycorrhizae . . . . . . . .
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385 391 399 402 407 415 419 422 425
Natural selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 428 Nonrandom mating, genetic drift, and mutation . . . . . . . . . . . . . 435 Nutrient cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 440 Ocean pollution and oil spills . . . Old-growth forests . . . . . . . . Omnivores . . . . . . . . . . . . . Ozone depletion and ozone holes
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Paleoecology . . . . . . . . . . . . . . . . Pesticides . . . . . . . . . . . . . . . . . . Pheromones . . . . . . . . . . . . . . . . Phytoplankton . . . . . . . . . . . . . . . Poisonous animals . . . . . . . . . . . . . Poisonous plants . . . . . . . . . . . . . . Pollination . . . . . . . . . . . . . . . . . Pollution effects . . . . . . . . . . . . . . Population analysis . . . . . . . . . . . . Population fluctuations . . . . . . . . . . Population genetics . . . . . . . . . . . . Population growth . . . . . . . . . . . . Predation . . . . . . . . . . . . . . . . . . Punctuated equilibrium vs. gradualism .
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464 470 476 482 486 490 495 500 507 513 520 528 536 543
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Ecology Basics Rain forests . . . . . . . . . . . . Rain forests and the atmosphere Rangeland . . . . . . . . . . . . Reefs . . . . . . . . . . . . . . . Reforestation . . . . . . . . . . . Reproductive strategies . . . . . Restoration ecology . . . . . . .
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549 554 560 564 572 576 583
Savannas and deciduous tropical forests Slash-and-burn agriculture . . . . . . . . Soil . . . . . . . . . . . . . . . . . . . . . Soil contamination . . . . . . . . . . . . . Speciation . . . . . . . . . . . . . . . . . Species loss . . . . . . . . . . . . . . . . . Succession . . . . . . . . . . . . . . . . . Sustainable development . . . . . . . . . Symbiosis . . . . . . . . . . . . . . . . .
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Taiga . . . . . . . . . . . . . . . . . Territoriality and aggression . . . . Trophic levels and ecological niches Tropisms . . . . . . . . . . . . . . . Tundra and high-altitude biomes .
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Urban and suburban wildlife . . . . . . . . . . . . . . . . . . . . . . . . 659 Waste management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 667 Wetlands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 672 Wildlife management . . . . . . . . . . . . . . . . . . . . . . . . . . . . 677 Zoos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 681 Appendices Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 687 Web Sites . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 729 Indexes Categorized Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 735 Subject Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 741
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Complete List of Contents Volume 1 Acid deposition, 1 Adaptations and their mechanisms, 7 Adaptive radiation, 12 Allelopathy, 15 Altruism, 18 Animal-plant interactions, 24 Balance of nature, 28 Biodiversity, 32 Biogeography, 37 Biological invasions, 40 Bioluminescence, 43 Biomagnification, 47 Biomass related to energy, 50 Biomes: determinants, 55 Biomes: types, 59 Biopesticides, 65 Biosphere concept, 69 Camouflage, 72 Chaparral, 76 Clines, hybrid zones, and introgression, 80 Coevolution, 86 Colonization of the land, 90 Communication, 95 Communities: ecosystem interactions, 100 Communities: structure, 104 Competition, 111 Conservation biology, 119 Convergence and divergence, 120 Deep ecology, 123 Defense mechanisms, 125
Deforestation, 131 Demographics, 137 Dendrochronology, 145 Desertification, 149 Deserts, 154 Development and ecological strategies, 161 Displays, 167 Ecology: definition, 171 Ecology: history, 179 Ecosystems: definition and history, 184 Ecosystems: studies, 191 Endangered animal species, 196 Endangered plant species, 205 Erosion and erosion control, 211 Ethology, 215 Eutrophication, 222 Evolution: definition and theories, 227 Evolution: history, 236 Evolution of plants and climates, 241 Extinctions and evolutionary explosions, 246 Food chains and webs, 255 Forest fires, 258 Forest management, 263 Forests, 269 Gene flow, 274 Genetic diversity, 278 Genetic drift, 281 Genetically modified foods, 284 xxix
Ecology Basics Geochemical cycles, 288 Global warming, 292 Grasslands and prairies, 298 Grazing and overgrazing, 304 Greenhouse effect, 308 Habitats and biomes, 313 Habituation and sensitization, 319 Herbivores, 326 Hierarchies, 329
Human population growth, 333 Hydrologic cycle, 338 Insect societies, 343 Integrated pest management, 351 Invasive plants, 354 Isolating mechanisms, 358 Lakes and limnology, 364 Landscape ecology, 374 Lichens, 381
Volume 2 Mammalian social systems, 385 Marine biomes, 391 Mediterranean scrub, 399 Metabolites, 402 Migration, 407 Mimicry, 415 Mountain ecosystems, 419 Multiple-use approach, 422 Mycorrhizae, 425 Natural selection, 428 Nonrandom mating, genetic drift, and mutation, 435 Nutrient cycles, 440 Ocean pollution and oil spills, 444 Old-growth forests, 452 Omnivores, 455 Ozone depletion and ozone holes, 457 Paleoecology, 464 Pesticides, 470 Pheromones, 476 Phytoplankton, 482 Poisonous animals, 486 Poisonous plants, 490 Pollination, 495 Pollution effects, 500
Population analysis, 507 Population fluctuations, 513 Population genetics, 520 Population growth, 528 Predation, 536 Punctuated equilibrium vs. gradualism, 543 Rain forests, 549 Rain forests and the atmosphere, 554 Rangeland, 560 Reefs, 564 Reforestation, 572 Reproductive strategies, 576 Restoration ecology, 583 Savannas and deciduous tropical forests, 586 Slash-and-burn agriculture, 590 Soil, 594 Soil contamination, 601 Speciation, 604 Species loss, 608 Succession, 612 Sustainable development, 618 Symbiosis, 621 Taiga, 629 Territoriality and aggression, 633 xxx
Complete List of Contents Trophic levels and ecological niches, 641 Tropisms, 650 Tundra and high-altitude biomes, 655 Urban and suburban wildlife, 659 Waste management, 667 Wetlands, 672
Wildlife management, 677 Zoos, 681 Glossary, 687 Web Sites, 729 Categorized Index, 735 Subject Index, 741
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Ecology Basics
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MAMMALIAN SOCIAL SYSTEMS Type of ecology: Behavioral ecology Social organization in mammals ranges from solitary species, which come together only to breed, to large and intricately organized societies. Understanding the social systems of mammals is essential for effective conservation of species.
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ll levels of social organization occur in mammals. There are solitary species, such as the mountain lion (Felis concolor), in which the male and female adults come together only to mate and the female remains with her young only until they are capable of living independently. At the other numerical extreme are some of the hoofed mammals, which form herds of thousands of individuals. The most socially specialized mammal is probably Africa’s naked mole rat (Heterocephalus glaber), which has a eusocial colony structure similar to that of ants, bees, and termites. No current theory accounts for the diversity of mammalian social systems, but two broad generalizations are consistently employed to explain mammalian species’ social organization. These are the environmental context in which the species exists and the mammalian mode of reproduction. Reproductive Determinants More than any other group of animals, mammals are required to form groups for at least part of their lives. Although in all sexually reproducing animals the sexes must come together to mate, mammals have an additional required association between mother and young: All species of mammal feed their young with milk from the mother’s mammary glands. This group, a female and her young, is the basis for the development of mammalian social groups. In some species, the social group includes several females and their young and may involve one or more males as well. Environmental Determinants Mammalian societies are always organized around one or more females and their offspring. Males may also be part of the group, or they may form separate groups. The size and structure of the group are determined by the ecological setting in which it evolves. The particular ecological factors that seem to be of greatest importance in this determination are food supply, the distribution of the food, and predation (including the hiding places and escape routes available in the habitat). Large groups occur when food is scattered in a patchy distribution. 385
Mammalian social systems These groups are largest when the patches contain abundant food. Many organisms are more likely to find the scattered patches than is a single individual. As long as the patches have enough food for all members of the group, it is to each member’s advantage to search with the group. On the other hand, if food is evenly dispersed in small units throughout the environment, the advantage of a group search is lost. Each individual will be better off searching for itself, and some strategy involving a very small social group or even solitary existence would be advantageous. A somewhat similar argument follows for predators. If large prey are taken, a group of predators should be able to subdue the prey and protect its remains from scavengers more efficiently. If small prey are taken, solitary predators have the advantage, since the prey is easily dispatched and the predator will have it to itself. Many other factors are involved in determining the final form of a species’ social organization, but the family unit and environmental context are fundamental in determination of all mammalian social structures. Primate Social Organization The primates are the most social group of mammals. Monkeys demonstrate the importance of food supply and its distribution in determining social structure. The olive baboon (Papio anubis) occupies savannas, where
Lions are among the few feline species that live in groups, called prides. Each pride consists of only one or a few males and several or many females. The females share the responsibility for raising the cubs, teaching them hunting behaviors and other survival skills. These four littermates are nearly independent and, if male, will likely leave the pride. (PhotoDisc) 386
Mammalian social systems it exists in large groups of several adult males, several adult females, and their young. Finding fifty or more animals in a group is not uncommon. Individual males do not guard or try to control specific females except when the females are sexually receptive. The group’s food supply is in scattered patches, but each patch contains an abundance of food. The advantage of having many individuals searching for the scattered food is obvious: If any member finds a food-rich patch, there is plenty for all. Predation probably also plays a role in the olive baboon’s social organization. The savannas they roam have many predators and few refuges for escape. A large group is one defense against predators if hiding or climbing out of reach is not practical. Having many observers increases the chance of early detection, giving the prey time to elude the predator. A large group can also mount a more effective defense against a predator. Large groups of baboons use both of these tactics. The hamadryas baboon (Papio hamadryas), on the other hand, lives in deserts in which the food supply is not only scattered but also often found in small patches. The hamadryas baboon’s social structure contrasts with that of the olive baboon, perhaps because the small patches do not supply enough food to support large groups. A single adult male, one or a few adult females, and their young make up the basic group of fewer than twenty individuals. Several of these family groups travel together under certain conditions, forming a band of up to sixty animals. Within the band, however, the family groups remain intact. The male of each group herds his females, punishing them if they do not follow him. The bands are probably formed in defense against predators. They break up into family units if predators are absent. At night, hamadryas baboons sleep on cliffs, where they are less accessible to predators. Because suitable cliffs are limited, many family groups gather at these sites. Hundreds of animals may be in the sleeping troop, probably affording further protection against predators. Though there are exceptions, forest primates consistently live in smaller groups. In many species, fewer than twenty individuals make up the social group at all times. These consist of one or a few mature males, one or a few mature females, and their offspring. The groups are more evenly distributed throughout their habitat than are groups of savanna or desert primates. In forests, the food supply is more abundant and more evenly distributed. Escape from predators is also more readily accomplished—by climbing trees or hiding in the dense cover. Under these conditions, the advantages of large groups are minimal and their disadvantages become apparent. For example, in small groups the competition for mates and food is less. 387
Mammalian social systems Ungulate Social Organization The ungulates have all levels of social organization. African antelope demonstrate social organizations that, in some ways, parallel those of the primates. Forest antelope such as the dik-dik (Madoqua) and duiker (Cephalophus) are solitary or form small family groups, and they are evenly spaced through their environment. Many hold permanent territories containing the needs of the individual or group. They escape predators by hiding and are browsers, feeding on the leaves and twigs of trees. Many grassland and savanna antelope, such as wildebeest (Connochaetes), on the other hand, occur in large herds. They outrun or present a group defense to predators and are grazers, eating the abundant grasses of their habitat. In many cases, they are also migratory, following the rains about the grasslands to find sufficient food. The social unit is a group of related females and their young. Males leave the group of females and young as they mature. They join a bachelor herd until fully mature, at which time they become solitary, and some establish territories. The large migratory herds are composed of many female-young groups, bachelor herds, and mature males. The social units are maintained in the herd. Though it may seem strange to speak of solitary males in a herd of thousands, that is their social condition. The male territories are permanent in areas that have a reliable food supply year-round, but they cannot be in regions in which the species is migratory. Under these conditions, the males set up temporary breeding territories wherever the herd is located during the breeding season. There are parallels with primate social patterns. Large groups are formed in grasslands, and these roam widely in search of suitable food. The groups are effective as protection against predators in habitats with few hiding places. Smaller groups are found in forests, where food is more evenly dispersed and places to hide from predators are more readily found. Rodent Social Organization Rodents also have all kinds of social organization. The best known, and one of the most complex, is the social system of the black-tailed prairie dog (Cynomys ludovicianus). The coterie is the family unit in this case, and it consists of an adult male, several adult females, and their young. Members maintain a group territory defended against members of other coteries. Coterie members maintain and share a burrow system. Elaborate greeting rituals have developed to allow the prairie dogs of a coterie to recognize one another. Hundreds of these coteries occur together in a town. The members of these towns keep the vegetation clipped—as a result, preda388
Mammalian social systems tors can be seen from a distance. Prairie dogs warn one another with a “bark” when they observe a predator, and the burrow system affords a refuge from most predators. The only vertebrate known to be eusocial is the naked mole rat. It occurs in hot, dry regions of Africa. The colony has a single reproductive female, a group of workers, and a group of males whose only function is to breed with the reproductive female. The workers cooperate in an energetically efficient burrowing chain when enlarging the burrow system. In this way, they are able to extend the burrow system quickly during the brief wet season. Digging is very difficult at other times of the year. The entire social system is thought to be an adaptation to a harsh environment and a sparse food supply. Carnivore Social Organization Most carnivores are not particularly social, but some do have elaborate social organization. Many of these are based on the efficiency of group hunting in the pursuit of large prey or on the ability of a group to defend a large food supply from scavengers. The gray wolf (Canis lupus) and African hunting dog (Lycaon pictus) are examples. In both cases, the social group, or pack, consists of a male and female pair and their offspring of several years. Though there are exceptions, solitary carnivores and carnivores that form temporary family units during the breeding season, such as the red fox (Vulpes vulpes), hunt prey smaller than themselves. The coyote (Canis latrans) can switch social systems to use the food available most efficiently. It forms packs similar to those of the gray wolf when its main prey is large or when it can scavenge large animals and is solitary when the primary available prey is small. These examples and many others show that the social groups of mammals are based on the family group. The particular social organization employed by a species is determined by the ecological situation in which it occurs. The specific aspects of the environment that seem to be most important include food abundance, food distribution, food type, and protection from predators. Carl W. Hoagstrom See also: Altruism; Communication; Defense mechanisms; Displays; Ethology; Habituation and sensitization; Herbivores; Hierarchies; Insect societies; Isolating mechanisms; Migration; Mimicry; Omnivores; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. 389
Mammalian social systems Sources for Further Study Dunbar, Robin I. M. Primate Social Systems. Ithaca, N.Y.: Cornell University Press, 1988. Eisenberg, John F., and Devra G. Kleiman, eds. Advances in the Study of Mammalian Behavior. Special Publication 7. Shippensburg, Pa.: American Society of Mammalogists, 1983. Gittleman, John L., ed. Carnivore Behavior, Ecology, and Evolution. Ithaca, N.Y.: Cornell University Press, 1989. Immelmann, Klaus, ed. Grzimek’s Encyclopedia of Ethology. New York: Van Nostrand Reinhold, 1977. Macdonald, David W. European Mammals: Evolution and Behavior. London: HarperCollins, 1995. Nowak, Ronald M., and John L. Paradiso. Walker’s Mammals of the World. 6th ed. 2 vols. Baltimore: Johns Hopkins University Press, 1999. Rosenblatt, Jay S., and Charles T. Snowdon, eds. Parental Care: Evolution, Mechanisms, and Adaptive Significance. Advances in the Study of Behavior 25. San Diego, Calif.: Academic Press, 1996. Slater, P. J. B. An Introduction to Ethology. Reprint. London: Cambridge University Press, 1990. Vaughan, Terry A. Mammalogy. 4th ed. Philadelphia: Saunders College Publishing, 2000. Wrangham, Richard W., W. C. McGrew, Frans B. M. De Waal, and Paul G. Heltne, eds. Chimpanzee Cultures. Cambridge, Mass.: Harvard University Press, 1994.
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MARINE BIOMES Types of ecology: Aquatic and marine ecology; Biomes; Ecosystem ecology The world’s oceans contain the largest and most varied array of life-forms on earth. The marine environment is divided into coastal, open water, deep-sea, and bottom zones and the lives of animals living in each of these regions are dictated by the physical conditions present in these zones.
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pproximately 71 percent of earth’s surface is covered by salt water, and the marine environments contained therein constitute the largest and most diverse array of life on the planet. Life originated in the oceans, and the salt water that comprises the largest constituent of the tissues of all living organisms is a vestigial reminder of the aquatic origins of life. Marine Zones The marine environment can be divided broadly into different zones, each of which supports numerous habitats. The coastal area between the high and low tide boundaries is known as the intertidal zone; beyond this is the neritic zone, relatively shallow water that extends over the continental shelves. The much deeper water that extends past the boundaries of the continental shelves is known as the oceanic zone. Open water of any depth away from the coastline is also known as the pelagic zone. The benthic zone is composed of the sediments occurring at the sea floor. Areas in which freshwater rivers empty into the saltwater oceans produce a continually mixed brackish water region known as an estuary. Estuarine zones often also include extensive wetland areas such as mudflats or salt marshes. Zones in the marine environment are distributed vertically as well as horizontally. Life in the ocean, as on land, is ultimately supported by sunlight in most cases, used by photosynthetic plants as an energy source. Sunlight can only penetrate water to a limited depth, generally between one hundred and two hundred meters; this region is known as the photic or epipelagic zone. Below two hundred meters, there may be sufficient sunlight penetrating to permit vision, but not enough to support photosynthesis; this transitional region may extend to depths of one thousand meters and is known as the disphotic or mesopelagic zone. Below this depth, in the aphotic zone, sunlight cannot penetrate and the environment is perpetually dark, with the exception of small amounts of light produced 391
Marine biomes by photoluminescent invertebrate and vertebrate animals. This aphotic zone is typically divided into the bathypelagic zone, between seven hundred and one thousand meters as the upper range and two thousand to four thousand meters as the lower range, where the water temperature is between 4 and 10 degrees Celsius. Beneath the bathypelagic zone, overlying the great plains of the ocean basins, is the abyssalpelagic zone, with a lower boundary of approximately six thousand meters. Finally, the deepest waters of the oceanic trenches, which extend to depths of ten thousand meters, constitute the hadalpelagic zone. In each of these zones, the nature and variety of marine life present is dictated by the physical characteristics of the zone. However, these zones are not absolute, but rather merge gradually into each other, and organisms may move back and forth between zones. Plankton Marine life can be divided broadly into three major categories. Those small organisms that are either free-floating or weakly swimming and which thus drift with oceanic currents are referred to as plankton. Plankton can be further divided into phytoplankton, which are plantlike and capable of photosynthesis; zooplankton, which are animal-like; and bacterioplankton, which are bacteria and bluegreen algae suspended in the water column. Larger organisms that can swim more powerfully and which can thus move independently of water movements are known collectively as the nekton. Finally, organisms that are restricted to living on or in the sediments of the seafloor bottom are referred to as the benthos. The phytoplankton, which are necessarily restricted to the photic zone, are by far the largest contributors to photosynthesis in the oceans. The phytoplankton are therefore responsible for trapping most of the solar energy obtained by the ocean (the primary productivity), which can then be transferred to other organisms when the phytoplankton are themselves ingested. The phytoplankton are composed of numerous different types of photosynthetic organisms, including diatoms, which are each encased in a unique “pillbox” shell of transparent silica, and dinoflagellates. The very rapid growth of some species of dinoflagellates in some areas results in massive concentrations or blooms that are sometimes referred to as red tides. Chemicals that are produced by red tide dinoflagellates often prove toxic to other marine organisms and can result in massive die-offs of marine life. Smaller photosynthetic plankton forms comprise the nanoplankton and also play an important role in the photosynthetic harnessing of energy in the oceans. The zooplankton are an extremely diverse group of small animal organ392
Marine biomes isms. Unlike the phytoplankton, which can make their own complex organic compounds via photosynthesis, the phytoplankton must ingest or absorb organic compounds produced by other organisms. This is accomplished by either preying upon other planktonic organisms or by feeding on the decaying remains of dead organisms. A number of zooplankton species also exist as parasites during some portion of their life cycles, living in or upon the bodies of nekton species. The largest group of zooplankton are members of the subphylum Crustacea, especially the copepods. These organisms typically possess a jointed exoskeleton, or shell, made of chitin, large antennae, and a number of jointed appendages. Space precludes a definitive listing of all of the zooplanktonic organisms, however virtually all of the other groups of aquatic invertebrates are represented in the bewildering variety of the zooplankton, either in larval or adult forms. Even fish, normally a part of the nekton, contribute to the zooplankton, both as eggs and as larval forms. The bacterioplankton are found in all of the world’s oceans. Some of these, the blue-green algae (cyanobacteria), play an important role in the photosynthetic productivity of the ocean. Bacterioplankton are usually found in greatest concentrations in surface waters, often in association with organic fragments known as particulate organic carbon, or marine snow. Bacterioplankton play an important role in renewing nutrients in the photic zones of the ocean; such renewal is important in maintaining the photosynthetic activity of the phytoplankton, upon which the rest of marine life is in turn dependent. One of the principal problems facing plankton is maintaining their position in the water column. Since these organisms are slightly denser than the surrounding seawater, they tend to sink. Clearly this is a disadvantage, particularly since plankton typically have very limited mobility. This is especially true for the photosynthetic phytoplankton, which must remain within the photic zone in order to carry on photosynthesis. A number of strategies have evolved among planktonic species to oppose this tendency to sink. Long, spindly extensions of the body provide resistance to the flow of water. Inclusions of oils or fats (which are less dense than water) within the body provide positive buoyancy by decreasing the overall density of the plankton. Finally, some species, such as the Portuguese man-o’-war, generate balloonlike gas bladders, which provide enough buoyancy to keep them at the very surface of the epipelagic zone. Nekton The nekton comprise those larger animals that have developed locomotion to a sufficient degree that they can move independently of the ocean’s 393
Marine biomes water movements. Whereas the plankton are principally invertebrates, most of the nekton are vertebrates. The majority of the nekton are fish, although reptile, bird, and mammalian species are also constituent parts. The oceanic nekton are those species which are found in the epipelagic zone of the open ocean. These include a wide variety of sharks, rays, bony fish, seabirds, marine mammals, and a few species of reptiles. Some members of the oceanic nekton, such as blue sharks, oceanic whitetip sharks, tuna, flying fish, and swordfish, spend their entire lives in the pelagic environment; these are said to be holoepipelagic. Others, the meroepipelagic nekton—such as herring, dolphins, salmon, and sturgeon—spend only a portion of their lives in the epipelagic zone, returning to coastal or freshwater areas to mate. Seabirds are a special case: Although they spend much of their time flying over the epipelagic zone and nest on land, they feed in the epipelagic zone. Some species may dive as deep as one hundred meters in search of prey. Some members of the nekton enter the epipelagic only at certain times in their life cycles. Eels of the family Anguillidae spend most of their lives in fresh water but return to the epipelagic zone to spawn. Additionally, at night many species of deep-water fish migrate up into the epipelagic to feed before returning to deeper waters during the daylight hours. The pelagic environment, unlike the terrestrial one, is profoundly threedimensional. Nektonic animals can move both horizontally and vertically within the water column. Furthermore, since most of the pelagic environment is essentially bottomless, since there is no apparent or visible ground or substrate, the environment is essentially uniform and featureless. These features play an important role in the evolution of the behavior of nektonic animals. Fish suspended in an essentially transparent and featureless medium have no shelter in which to hide from predators, nor are there any apparent landmarks to serve as directional cues for animals moving horizontally from place to place. Life in the open ocean has therefore favored adaptations for great mobility and speed with which to move across large distances and escape from predators, as well as camouflage and cryptic coloration designed to deceive potential predators or prey. As is the case for plankton, most nektonic animals are denser than the surrounding seawater, and maintaining position in the water column is of the first importance. Most fish possess a swim bladder, a gas-filled membranous sac within their body that opposes the tendency to sink and provides the fish with neutral buoyancy. Sharks and rays lack a swim bladder, but accumulate large concentrations of fats and oils in their liver, which also help counter the tendency to sink. Large, fast-swimming species of 394
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Seabirds and fish are examples of nekton, generally vertebrates that have developed locomotion to a sufficient degree that they can move independently of the ocean’s water movements or occupy other portions of the photic, or epipelagic, zone of the ocean ecosystem. (PhotoDisc)
shark, tuna, and many billfish also rely on the generation of hydrodynamic lift to maintain vertical position in the water column. The tail and body of these fish generate forward thrust, moving the animal through the water, and the fins, notably the pectoral fins, generate lift from the water flowing over them in a manner similar to that of an airplane’s wing. Thus these animals fly through the water, but are in turn required to move continuously in order to generate lift. All members of the nekton are carnivores, feeding on other nektonic species or upon plankton, particularly the larger zooplankton. In general, the size of the prey consumed by nekton is directly related to the size of the predator, with larger species consuming larger prey. However, the organisms that feed upon plankton, the planktivores, include a wide variety of fish species such as herring, salmon, and the whale shark, the largest extant fish species. They also include the largest marine animals of all, the baleen whales. The case of large animals feeding upon very small plankton directly addresses the need of all animals to meet their energy requirements. For all animals, the amount of energy obtained from food consumed must necessarily exceed the energy expended in acquiring the prey. Very large animals, such as whales and whale sharks, require a great deal of energy to move their bodies through the aquatic environment, but because of their 395
Marine biomes great size they are necessarily less agile than smaller forms. The amount of energy required to chase and catch these smaller animals would generally exceed the energy derived from ingesting them. Plankton, however, are relatively easy to obtain due to their very limited mobility. However, because of their small size, vast quantities of plankton must be ingested in order to meet the metabolic requirements of large marine animals. Some very large species that are not planktivores solve the energy problem by evolving behaviors for acquiring specialized diets that yield higher energy. White sharks, for example, feed on fish when young, but as they age and increase in size, marine mammals, notably seals and sea lions (pinnipeds), become a major part of their diet. Marine mammals all possess blubber, an energy-rich substance that yields much more energy than fish. Similarly, sperm whales, the largest hunting carnivores on the planet, have a diet that consists in large part of giant squid, which are hunted in the ocean depths largely using the whale’s acoustic echolocation sense. Orcas (killer whales) effectively use pack hunting techniques to hunt larger whales and other marine mammals. The deeper regions of the ocean are dominated by different types of nekton. However, we know even less about their ecology due to their relative inaccessibility. The disphotic or mesopelagic zone contains many animal species that migrate vertically into surface waters at night to feed upon the plankton there. Many of these organisms possess large, welldeveloped eyes and also possess light organs containing symbiotic luminescent bacteria. The majority of the fish species in this group are colored black and the invertebrates are largely red (red light penetrates water less effectively than do longer wavelengths, and these animals appear darkcolored at depth). Beneath this zone, in the bathypelagic and abyssalpelagic zones, there are many fewer organisms and much less diversity than in the shallower levels. Animals in this region are typically colorless and possess small eyes and luminescent organs. Because organisms in these deep regions are few and far between, many species have become specialized in order to maximize their advantages. Thus, deep-sea fish are characterized by large teeth and remarkably hinged jaws that allow them to consume prey much larger than might be expected from their size. Similarly, since encounters with potential mates are presumably scarce, a number of unique reproductive strategies have evolved. In the anglerfish (Ceratius), all of the large individuals are female and the comparatively tiny males are parasitic, permanently attaching themselves to the female. Much, however still remains to be learned of the ecology of these deep-sea organisms.
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Marine biomes Benthos The benthos of the world’s oceans consists of animals that live on the solid substrate of the water column, the ocean floor. Scientists typically divide benthic organisms into two categories, the epifauna, which live on the surface of the bottom at the sediment-water interface and the infauna, those organisms living within the sediments. In shallow water benthic communities, members of virtually every major animal group are represented. Ecologists generally differentiate between soft bottom benthic communities (sand, silt, and mud, which comprise the majority of the benthic zone) and rocky bottom communities, which are less common proportionately. Soft bottom communities have an extensive diversity of burrowing infauna, such as polychaete worms, and mollusks, such as clams. Rocky bottom communities possess a larger proportion of epifauna, such as crustaceans and echinoderms (starfish, sea urchins, and brittle stars), living on the surface of what is essentially a two-dimensional environment. Vertical faces of the hard bottom environment, such as canyon walls or coral reefs, are often home to a wide variety of animals occupying various crannies and caves. In some parts of the world, kelp plants that are anchored to the substrate and which extend to the water surface dominate the rocky bottom substrate. In these kelp forests, large kelp plants (actually a species of brown algae) form a forestlike canopy that plays host to a wide and complex array of animals extending throughout the water column. On the deep ocean floor, the benthos is composed of representatives of virtually major animal group: crustaceans such as amphipods, segmented polychaete worms, sea cucumbers, and brittle stars. Less common are starfish, sea lilies, anemones, and sea fans. The fish of the deep benthos include rat tails and a number of eel species. Estuaries, where freshwater rivers empty into marine environments, are typified by large, cyclic changes in temperature and salinity. Although estuaries have played an important role in human history as the sites of major ports, the variety and number of estuarine species tend to show less diversity of animal species due to the difficulty in adapting to the large swings in environmental conditions. Animal life in the sea, like that on land, shows an astonishing variety of forms and behaviors, the result of natural selection. The inaccessibility and hostility of much of the world’s oceans to human exploration and observation leaves much yet to be learned about the biology of marine life. Much remains to be achieved in order to obtain a useful body of knowledge concerning life in the sea. John G. New
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Marine biomes See also: Acid deposition; Eutrophication; Evolution: definition and theories; Habitats and biomes; Invasive plants; Lakes and limnology; Ocean pollution and oil spills; Reefs; Wetlands. Sources for Further Study Niesen, T. M. The Marine Biology Coloring Book. 2d ed. New York: HarperResource, 2000. Nybakken, J. W. Marine Biology: An Ecological Approach. 5th ed. San Francisco: Benjamin/Cummings, 2001. Robison, B. H., and J. Connor. The Deep Sea. Monterey Bay, Calif.: Monterey Bay Aquarium Press, 1999. Safina, C. Song for the Blue Ocean: Encounters Along the World’s Coasts and Beneath the Seas. New York: Henry Holt, 1998.
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MEDITERRANEAN SCRUB Types of ecology: Biomes; Ecosystem ecology Mediterranean scrub vegetation is dominated by fire-adapted shrubs. The biome fringes the Mediterranean Sea, for which it is named, but is also found along western coasts of continents in areas with warm, dry summers and moist, cool winters.
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egions with mediterranean vegetation are coastal regions between 30 and 45 degrees north latitude or between 30 and 45 degrees south latitude. The air circulating around high-pressure zones over adjacent oceans guides storms away from the coast in the warm season but changes position in concert with the tilt of the earth on its axis and brings storms onto the coast in the cool season. As a result, the warm season is dry, and the cool season is moist. Fire is an important component of mediterranean environments, especially after the warm, dry summer. North America’s representative of mediterranean scrub is the chaparral of the Pacific Coast of Southern California and northern Baja California, Mexico. In chaparral and some other mediterranean regions, winds blowing from continental high-pressure regions toward the coast help push storm tracks offshore during the warm season. In California these winds are called Santa Ana winds and are best known for driving chaparral fires. Lightning started such fires before human settlement, but they are often started by careless people today. With the cooler temperatures of autumn and winter the continental pressure wanes and the Santa Ana winds decrease. At the same time, the oceanic high-pressure region shifts, and winter storms track onto the coast, bringing the cool season rains. Character and Components Mediterranean scrub is found in small, scattered areas around the world. The plant species that occur in this biome on one continent are unrelated to those that occur in the same biome on other continents. As a result, mediterranean scrub presents a classical example of convergent evolution, the environmentally driven development of similar characteristics in unrelated species. Under the influence of mediterranean climate, entire communities of unrelated species become similar to one another. Many mediterranean areas also contain a large number of endemic plant species, species that grow nowhere else. Mediterranean scrub is dominated by shrubs well adapted to fire. Some species have specialized underground structures that are undamaged by 399
Mediterranean scrub the fire and send up new growth shortly after the fire passes. Other species have specialized, long-lived seeds that require intense heat to stimulate germination. Still other species combine the two strategies. In communities that burn regularly, such species have a great advantage over their competitors. Mediterranean shrubs are not just adapted to recover after a fire; they are actually adapted to carry the fire once it is started. These species synthesize and store highly flammable chemicals in their leaves and stems. The flammable vegetation ensures that most fires will burn large areas. The most widespread shrub in North American chaparral is chamise (Adenostoma fasciculatum), which sprouts from underground structures and produces large numbers of seedlings after a fire. Various species of manzanita (Arctostaphylos) and wild lilac (Ceanothus) are also widespread throughout chaparral. Some species in each genus both sprout and produce large numbers of seedlings after fires. Other species in each genus depend entirely on heat-stimulated seeds to reestablish their presence in a burned area. Mediterranean vegetation also occurs on western coasts in southern Australia, where it is called mallee; the Cape region of South Africa (fynbos); the central coast of Chile (matorral); and around the Mediterranean Sea (maquis). In all these areas, the vegetation has the same adaptive characteristics and appearance, but the species are not related to those of other areas. Although there are differences among the regions besides the species that occur in each, the similar physical and vegetational characteristics lend a continuity that is widely recognized as the mediterranean scrub biome. Human Impact As people moved into Mediterranean scrub regions, two major and related concerns surfaced. First, the fires, which are such an important part of scrub ecology, were destructive and dangerous, leading to fire suppression. Second, fire suppression may actually increase fire damage and may threaten the mediterranean scrub biome’s very existence when combined with other human activities. A comparison of the fire history in the chaparral of California and that of Baja California lends credibility to the idea that fire suppression increases fire damage. Fire suppression has long been practiced in Southern California. In contrast, much less fire suppression has gone on in Baja. Fewer, larger, and more destructive fires burn in Southern California chaparral than in Baja chaparral. The simplest explanation is that fire suppression allows fuel to build up, so that when a fire starts it is essentially unstoppable, as often occurs in California chaparral. 400
Mediterranean scrub With less fire suppression and less fuel accumulation, Baja fires burn more frequently but are smaller and less destructive. The small fires remove the fuel periodically, thus decreasing the danger of large, destructive fires. There are other differences between California and Baja chaparral that may account for the differences in the fire regimes, but the foregoing hypothesis is interesting from the perspective of human impact on chaparral as well as that of fire’s impact on humans. Population growth and its attendant activities threaten the very existence of the chaparral. Humans destroy chaparral to build home sites, suppress fires, and plant grass in burned areas to stabilize the soil and to mitigate future fires. The grasses compete with chaparral plants and retard chaparral recovery. The impact of these and other activities on the native chaparral ecosystem is not well understood but is almost certainly negative. Other mediterranean scrub areas suffer similar fates. Although mediterranean scrub is still well represented in comparison to some biomes, its response to human impact should be carefully studied and monitored, both to protect human investment in mediterranean ecosystems and to preserve the intriguing mediterranean scrub and its many unique plant species. Carl W. Hoagstrom See also: Biomes: determinants; Biomes: types; Chaparral; Forest fires; Forest management; Forests. Sources for Further Study Barbour, Michael G., and William Dwight Billings, eds. North American Terrestrial Vegetation. 2d ed. New York: Cambridge University Press, 2000. Dallman, Peter R. Plant Life in the World’s Mediterranean Climates. Berkeley: University of California Press, 1998. Vankat, John L. The Natural Vegetation of North America: An Introduction. Melbourne, Fla.: Krieger, 1992.
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METABOLITES Type of ecology: Chemical ecology Metabolites are compounds synthesized by plants for both essential functions, such as growth and development (primary metabolites), and specific functions, such as pollinator attraction of defense against herbivory (secondary metabolites).
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etabolites are organic compounds synthesized by organisms using enzyme-mediated chemical reactions called metabolic pathways. Primary metabolites have functions that are essential to growth and development and are therefore present in all plants. In contrast, secondary metabolites are variously distributed in the plant kingdom, and their functions are specific to the plants in which they are found. Secondary metabolites are often colored, fragrant, or flavorful compounds, and they typically mediate the interaction of plants with other organisms. Such interactions include those of plant-pollinator, plant-pathogen, and plant-herbivore. Primary Metabolites Primary metabolites comprise many different types of organic compounds, including, but not limited to, carbohydrates, lipids, proteins, and nucleic acids. They are found universally in the plant kingdom because they are the components or products of fundamental metabolic pathways or cycles such as glycolysis, the Krebs cycle, and the Calvin cycle. Because of the importance of these and other primary pathways in enabling a plant to synthesize, assimilate, and degrade organic compounds, primary metabolites are essential. Examples of primary metabolites include energy-rich fuel molecules, such as sucrose and starch, structural components such as cellulose, informational molecules such as DNA (deoxyribonucleic acid) and RNA (ribonucleic acid), and pigments, such as chlorophyll. In addition to having fundamental roles in plant growth and development, some primary metabolites are precursors (starting materials) for the synthesis of secondary metabolites. Secondary Metabolites Secondary metabolites largely fall into three classes of compounds: alkaloids, terpenoids, and phenolics. However, these classes of compounds also include primary metabolites, so whether a compound is a primary or secondary metabolite is a distinction based not only on its chemi402
Metabolites cal structure but also on its function and distribution within the plant kingdom. Many thousands of secondary metabolites have been isolated from plants, and many of them have powerful physiological effects in humans and are used as medicines. It is only since the late twentieth century that secondary metabolites have been clearly recognized as having important functions in plants. Research has focused on the role of secondary metabolites in plant defense. This is discussed below with reference to alkaloids, though it is relevant to many types of secondary metabolites. Alkaloids Alkaloids are a large group of nitrogen-containing compounds, examples of which are known to occur in approximately 20 percent of all flowering plants. Closely related plant species often contain alkaloids of related chemical structure. The primary metabolites from which they are derived include amino acids such as tryptophan, tyrosine, and lysine. Alkaloid biosynthetic pathways can be long, and many alkaloids have correspondingly complex chemical structures. Alkaloids accumulate in plant organs such as leaves or fruits and are ingested by animals that consume those plant parts. Many alkaloids are extremely toxic, especially to mammals, and act as potent nerve poisons, enzyme inhibitors, or membrane transport inhibitors. In addition to being toxic, many alkaloids are also bitter or otherwise bad-tasting. Therefore, the presence of alkaloids and other toxic secondary metabolites can serve as a deterrent to animals to avoid eating such plants. Sometimes domesticated animals that have not previously been exposed to alkaloid-containing plants do not have acquired avoidance mechanisms, and they become poisoned. For example, groundsel contains the alkaloid senecionine, which has resulted in many recorded cases of livestock fatalities due to liver failure. More frequently, over time, natural selection has resulted in animals developing biochemical mechanisms or behavioral traits that lead to avoidance of alkaloid-containing plants. In other, more unusual cases, animals may evolve a mechanism for sequestering (storing) or breaking down a potentially toxic compound, thus “disarming” the plant. For instance, caterpillars of the cinnabar moth can devour groundsel plants and sequester senecionine without suffering any ill effects. Moreover, the caterpillars thereby acquire their own weapon against predators: the plant-derived alkaloid stored within their bodies. Over time, plants acquire new capabilities to synthesize additional defense compounds to combat animals that have developed “resistance” to the original chemicals. This type of an “arms race” is a form of coevolution and 403
Metabolites may help to account for the incredible abundance of secondary metabolites in flowering plants. Medicinal Alkaloids Many potentially toxic plant-derived alkaloids have medicinal properties, as long as they are administered in carefully regulated doses. Alkaloids with important medicinal uses include morphine and codeine from the opium poppy and cocaine from the coca plant. These alkaloids act on the nervous system and are used as painkillers. Atropine, from the deadly nightshade plant, also acts on the nervous system and is used in anesthesia and ophthalmology. Vincristine and vinblastine from the periwinkle plant are inhibitors of cell division and are used to treat cancers of the blood and lymphatic systems. Quinine from the bark of the cinchona tree is toxic to the Plasmodium parasite, which causes malaria, and has long been used in tropical and subtropical regions of the world. Other alkaloids are used as stimulants, including caffeine, present in coffee, tea, and cola plants (and the drinks derived from these plants); and nicotine, which is present in tobacco. Nicotine preparations are, paradoxically, also used as an aid in smoking cessation. Nicotine is also a very potent insecticide. For many years ground-up tobacco leaves were used for insect control, but this practice was superseded by the use of special formulations of nicotine. More recently the use of nicotine as an insecticide has been discouraged because of its toxicity to humans. Terpenoids Terpenoids are derived from acetyl coenzyme A or from intermediates in glycolysis. They are classified by the number of five-carbon isoprenoid units they contain. Monoterpenes (containing two C5-units) are exemplified by the aromatic oils (such as menthol) contained in the leaves of members of the mint family. In addition to giving these plants their characteristic taste and fragrance, these aromatic oils have insect-repellent qualities. The pyrethroids, which are monoterpene esters from the flowers of chrysanthemum and related species, are used commercially as insecticides. They fatally affect the nervous systems of insects while being biodegradable and nontoxic to mammals, including humans. Diterpenes are formed from four C5-units. Paclitaxel (commonly known by the name Taxol), a diterpene found in bark of the Pacific yew tree, is a potent inhibitor of cell division in animals. At the end of the twentieth century, paclitaxel was developed as a powerful new chemotherapeutic treatment for people with solid tumors, such as ovarian cancer patients. 404
Metabolites Triterpenoids (formed from six C5-units) comprise the plant steroids, some of which act as plant hormones. These also can protect plants from insect attack, though their mode of action is quite different from that of the pyrethroids. For example, the phytoecdysones are a group of plant sterols that resemble insect molting hormones. When ingested in excess, phytoecdysones can disrupt the normal molting cycle with often lethal consequences to the insect. Tetraterpenoids (eight C5-units) include important pigments such as beta-carotene, which is a precursor of vitamin A, and lycopene, which gives tomatoes their red color. Rather than functioning in plant defense, the colored pigments that accumulate in ripening fruits can serve as attractants to animals, which actually aid the plant in seed dispersal. The polyterpenes are polymers that may contain several thousand isoprenoid units. Rubber, a polyterpene in the latex of rubber trees that probably aids in wound healing in the plant, is also very important for the manufacture of tires and other products. Phenolic Compounds Phenolic compounds are defined by the presence of one or more aromatic rings bearing a hydroxyl functional group. Many are synthesized from the amino acid phenylalanine. Simple phenolic compounds, such as salicylic acid, can be important in defense against fungal pathogens. Salicylic acid concentration increases in the leaves of certain plants in response to fungal attack and enables the plant to mount a complex defense response. Interestingly, aspirin, a derivative of salicylic acid, is routinely used in humans to reduce inflammation, pain, and fever. Other phenolic compounds, called isoflavones, are synthesized rapidly in plants of the legume family when they are attacked by bacterial or fungal pathogens, and they have strong antimicrobial activity. Lignin, a complex phenolic macromolecule, is laid down in plant secondary cell walls and is the main component of wood. It is a very important structural molecule in all woody plants, allowing them to achieve height, girth, and longevity. Lignin is also valuable for plant defense: Plant parts containing cells with lignified walls are much less palatable to insects and other animals than are nonwoody plants and are much less easily digested by fungal enzymes than plant parts that contain only cells with primary cellulose walls. Other phenolics function as attractants. Anthocyanins and anthocyanidins are phenolic pigments that impart pink and purple colors to flowers and fruits. This pigmentation attracts insects and other animals that move between individual plants and accomplish pollination and fruit 405
Metabolites dispersal. Often the plant pigment and the pollinator’s visual systems are well matched: Plants with red flowers attract birds and mammals because these animals possess the correct photoreceptors to see red pigments. Valerie M. Sponsel See also: Allelopathy; Defense mechanisms; Genetically modified foods; Pheromones; Poisonous animals; Poisonous plants. Sources for Further Study Levetin, Estelle, and Karen McMahon. Plants and Society. Boston: WCB/ McGraw-Hill, 1999. Moore, Randy, et al. Botany. 2d ed. Boston: WCB/McGraw-Hill, 1998.
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MIGRATION Type of ecology: Behavioral ecology Migration is an important ecological process that results in the redistribution of animal populations from one habitat to another. Adaptive habitat changes are fundamentally important aspects of the life histories of many species.
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igration is a general term employed by ecologists and ethologists to describe the nearly simultaneous movement of many individuals or entire populations of animals to or between different habitats. As defined, migrations do not include local excursions made by individuals or small groups of animals in search of food, to mark territorial boundaries, or to explore surrounding environments. Nomads are migrants whose populations follow those of their primary food sources. Such animals (the American bison, for example) do not have fixed home ranges and wander in search of suitable forage. Some scientists view nomadic movements as a form of extended foraging behavior rather than as a special case of migration. In either context, the important point is that populations change habitats in response to changing conditions. In contrast to migrations made by populations and excursions made by individuals, the spreading or movement of animals away from others is known as dispersal. Examples of dispersal include the drift of plankton in currents and the departure of subadult animals from the home range of their parents. In numerous species (sea turtles, rattlesnakes, and salmon, for example), dispersed members of a population may return to the place of origin after a variable interval of time. Navigation Among the animals known to navigate are birds (the best-studied group), lobsters, bees, tortoises, bats, marine and terrestrial mammals, fish, brittle starfish, newts, toads, and insects. Some migratory species can orient themselves—that is, they know where they are in time and space. Many birds and mammals, for example, have an inherent sense of the direction, distance, and location of distant habitats. Orientation and travel along unfamiliar routes from one place or habitat to another is called navigation. Navigators use environmental and sensory information to reach distant geographical locations, and many of them do so with a remarkably accurate sense of timing. Homing pigeons are perhaps the best-studied animal navigators. These birds are able not only to discover where they are when 407
Migration released but also to return to their home loft from distant geographical locations. Much has been learned about how animals successfully navigate over long distances from the pioneering studies of Archie Carr. Carr proposed that green sea turtles successfully find their widely separated nesting and feeding beaches by means of an inherent clock sense, map sense, and compass sense. His investigations and those of many others continue to stimulate great interest in the physiology and ecology of navigating species and in the environmental cues to which they respond. Sensory biologists, biophysicists, and engineers have incorporated knowledge of how animals detect and use environmental information to develop new and more accurate navigational systems for human use. Animals use a variety of cues to locate their positions and appropriate travel paths. Most species have been found to use more than one type of information (sequentially, alternatively, or simultaneously) to navigate. Included among the orientation guideposts that one or more of these groups may use are the positions of the sun and stars, magnetic fields, ultraviolet light, tidal fluctuations caused by the changing positions of the moon and sun, atmospheric pressure variations, infrasounds (very low frequency sounds), polarized light (on overcast days), environmental odors, shoreline configurations, water currents, and visual landmarks. Celestial cues also require a time sense, or an internal clock, to compensate for movements of the animal relative to changing positions of celestial objects in the sky. In addition to an absolute dependence on environmental cues, young or inexperienced members of some species may learn navigational routes from experienced individuals, such as their parents, or other experienced individuals in the population. Visual mapping remembered from exploratory excursions may also play a role in enhancing the navigational abilities of some birds, fish, mammals, and other animals. Benefits of Migration The different categories of animal movements, however, are perhaps not as important as the reasons animals migrate and the important biological consequences of the phenomenon. As a general principle, migrations are adaptive behavioral responses to changes in ecological conditions. Populations benefit in some way by regularly or episodically moving from one habitat to another. An example of the adaptive value of migratory behavior is illustrated by movement of a population from a habitat where food, water, space, nesting materials, or other resources have become scarce (often a seasonal phenomenon) to an area where resources are more abundant. Relocation to 408
Migration a new habitat (or to the same type of habitat in a different geographical area) may reduce intraspecific or interspecific competition, may reduce death rates, and may increase overall fitness in the population. These benefits may result in an increase in reproduction in the population. Reproductive success, then, is the significant benefit and the only biological criterion used to evaluate population fitness. Programmed Movements While many factors are believed to initiate migratory events, most fall into one of two general categories. The first and largest category may be called programmed movements. Such migrations usually occur at predictable intervals and are important characteristics of a species’ lifestyle or life cycle. Programmed migrations are not, in general, density-dependent. Movements are not caused by overcrowding or other stresses resulting from an excessive number of individuals in the population. The lifestyle of a majority of drifting animals whose entire lives are spent in the water column, for example, includes a vertical migration from deep water during the day to surface waters at night. Thus, plankton exhibit a circadian rhythm (activity occurring during twenty-four-hour intervals) in their movements. An abundance of food at or near the surface and escape from deep-water predators are among the possible reasons for these migrations. Daily vertical movements of plankton are probably initiated by changes in light intensity at depth, and the animals follow light levels as they move toward the surface with the sinking sun. It is interesting to note that zooplankters living in polar waters during the winter-long night do not migrate. Monarch butterflies and many large, vertebrate animals, such as herring, albatross, wildebeests, and temperate-latitude bats, migrate from one foraging area to another, or from breeding to foraging habitats, on a seasonal or annual basis. Annual migrations usually coincide with seasonal variation. Changes in day length, temperature, or the abundance of preferred food items associated with seasonal change may stimulate mass movements directly, or indirectly, through hormonal or other physiological changes that are correlated with seasonal environmental change. The onset of migration in many vertebrates is evidenced by an increase in restlessness that seems, in human terms, to be anticipatory. In addition to their daily vertical migrations (lifestyle movements), the life cycles of marine zooplankton involve migrations, and it is convenient to use them as examples. As discussed, most adult animal plankters are found at depth during the day and near the surface at night. In contrast, zooplankton eggs and larvae remain in surface waters both day and night. 409
Migration
Bird migrations are among the most noticeable of animal migrations, with huge flocks passing through the skies on their way to a seasonal home that can be thousands of miles distant from their original location. (Corbis)
As the young stages grow, molt, and change their shapes and food sources, they begin to migrate vertically. The extent of vertical migrations gradually increases throughout the developmental period, and as adults, these animals assume the migratory patterns of their parents. Patterns of movement that change during growth and development are examples of ontogenetic, or life-cycle, migrations. Episodic Movements The second large category of migratory behavior includes episodic, densitydependent population movement. Such migrations are often associated with, or caused by, adverse environmental changes (effect) that may be caused by overlarge populations (cause). Local resources are adequate to support a limited number of individuals (called the carrying capacity of the environment), but once that number has been exceeded, the population must either move or perish. Unfortunately, migration to escape unfavorable conditions may be unsuccessful, as another suitable habitat may not be encountered. Migrations caused by overpopulation or environmental degradation are common. Pollution and habitat destruction by humankind’s activities are increasingly the cause of degraded environments, and 410
Migration in such cases, it is reasonable to conclude that humans have reduced the carrying capacity of many animal habitats. Familiar examples of densitydependent migrations are those of lemmings, locusts, and humans. Ecological Import Environmental or physiological factors that initiate migrations may be of interest to sensory biologists and physiological ecologists; knowledge of variation in population distributions is important to biogeographers and wildlife biologists; and migrations in predator-prey relationships, competition, pollution, and life-history strategies are important aspects of classical ecological studies. In addition to the specific aspect of migration being studied, the particular group of animals under investigation (moths, eels, elephants, snails) requires that different methods be used. Some of the approaches used in migration-related research illustrate how information and answers are obtained by scientists. Arctic terns migrate from their breeding grounds in the Arctic to the Antarctic pack ice each year. The knowledge that these birds make a twenty-thousand-mile annual round-trip comes from the simplest and most practical method: direct observation of the birds (or their absence) at either end of the trip. Direct observation by ornithologists of the birds in flight can establish what route they take and whether they pause to rest or feed en route. Many birds have also been tracked using radar or by observations of their silhouettes passing in front of the moon at night. Birds are often banded (a loose ring containing coded information is placed on one leg) to determine the frequency of migration and how many round-trips an average individual makes during its lifetime. From this information, estimates of longevity, survivorship rates, and nesting or feeding site preferences can be made. Factors that initiate migratory behavior in terns and in other birds can often be determined by ecologists able to relate environmental conditions (changes in temperature, day length, and the like) to the timing of migrations. Physiological ecologists study hormonal or other physiological changes that co-occur with environmental changes. Elevated testosterone levels, for example, may signal the onset of migratory behavior. How Arctic terns orient and navigate along their migratory routes is usually studied by means of laboratory-conducted behavioral experiments. Birds are exposed to various combinations of stimuli (magnetic fields, planetarium-like celestial fields, light levels), and their orientation, activity levels, and physiological states are measured. Experiments involving surgical or chemical manipulation of known sensory systems are 411
Migration sometimes conducted to compare behavioral reactions to experimental stimuli. In such experiments, the birds (or other test animals) are rarely harmed. Tags of several types are used to study migrations in a wide variety of animals, including birds, bees, starfish, reptiles, mammals, fish, snails, and many others. Tags may be transmitting collars (located by direction-finding radio receivers); plastic or metal devices attached to ears, fins, or flippers; or even numbers, painted on the hard exoskeletons of bees and other insects. Additional types of tagging (or identifying) include radioactive implants and microchips that can be read by computerized digitizers; the use of brands and tattoos; and, of great interest, the use of biological tags. Parasites known to occur in only one population of migrants (nematode parasites of herring, for example) provide an interesting illustration of how the distribution of one species can be used to provide information about another. The Importance of Migration The causes, frequency, and extent of animal migration are so diverse that several definitions for the phenomenon have been proposed. None of these has been accepted by all scientists who study animal movements, however, and it is sometimes difficult to interpret what is meant when the term “migration” is used. Most researchers have adopted a broad compromise to include all but trivial population movements that involve some degree of habitat change. It is important to recognize that few populations of animals are static; even sessile animals (such as oysters and barnacles) undergo developmental habitat changes, which are referred to as ontogenetic migrations. Aside from certain tropical and evergreen forest areas where migrations are relatively uncommon, a significant number of both aquatic and terrestrial species move from one habitat to another at some time during their lives. In the face of environmental change, including natural events such as seasonal variation and changes caused by resource limitations and environmental degradation, animals must either move, perish, or escape by means of drastic population reduction or by becoming inactive until conditions become more favorable (hibernation, arrested development and dormancy, and diapause in insects are examples of behavioral-ecological inactivity). Migration is the most common behavioral reaction to unfavorable environmental change exhibited by animals. One cannot understand the biology of migrators until their distribution and habitats throughout life are known. The patterns of animal movements are fascinating, and it is useful to summarize some of the major dif412
Migration ferences between them. First, many species travel repeatedly during their lives between two habitats, on a daily basis (as plankton and chimney swifts do) or on an annual basis (as frogs and elks do). Second, some species migrate from one habitat (usually suitable for young stages) to another (usually the adult habitat) only once during their lives (for example, salmon, eels, damselflies, and most zooplankton, which live on the bottom as adults). Third, some species (many butterflies, for example) are born and mature in one geographical area (England, for example), migrate as adults to a distant geographical area (Spain, for example), and produce offspring that mature in the second area. These migrations take place between generations. In a fourth pattern, one may include the seasonal swarming of social arthropods such as termites, fire ants, and bees. A fifth but ill-defined pattern is discernible, exemplified by locust “plagues,” irruptive emigration in lemmings and certain other rodents, and some mass migrations by humankind, as caused by war, famine, fear, politics, or disease. These are episodic and often, if not primarily, caused by severe population stress or catastrophic environmental change. Sneed B. Collard See also: Altruism; Communication; Defense mechanisms; Displays; Ethology; Habituation and sensitization; Herbivores; Hierarchies; Insect societies; Isolating mechanisms; Mammalian social systems; Mimicry; Omnivores; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study Able, Kenneth P., ed. Gatherings of Angels: Migrating Birds and Their Ecology. Ithaca, N.Y.: Comstock, 1999. Aidley, David, ed. Animal Migration. New York: Cambridge University Press, 1981. Begon, Michael, John Harper, and Colin Townsend. Ecology: Individuals, Populations, and Communities. 3d ed. Sunderland, Mass.: Sinauer Associates, 1996. Dingle, Hugh. Migration: The Biology of Life on the Move. New York: Oxford University Press, 1996. Eisner, Thomas, and Edward Wilson, eds. Animal Behavior: Readings from “Scientific American.” San Francisco: W. H. Freeman, 1975. Newberry, Andrew, ed. Life in the Sea: Readings from “Scientific American.” San Francisco: W. H. Freeman, 1982. Pyle, Robert Michael. Chasing Monarchs: Migrating with Butterflies of Passage. Boston: Houghton Mifflin, 1999. 413
Migration Rankin, Mary, ed. Migration: Mechanisms and Adaptive Significance. Port Aransas, Tex.: Marine Science Institute, University of Texas at Austin, 1985. Reader’s Digest Association. The Wildlife Year. Pleasantville, N.Y.: Author, 1993. Schone, Hermann. Spatial Orientation: The Spatial Control of Behavior in Animals and Man. Translated by Camilla Strausfeld. Princeton, N.J.: Princeton University Press, 1984.
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MIMICRY Types of ecology: Behavioral ecology; Physiological ecology Mimicry is the process whereby one organism resembles another and, because of this resemblance, obtains an evolutionary advantage.
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he broadest description of mimicry is when one organism, called the operator or dupe, cannot distinguish a second organism, referred to as the mimic, from a third organism or a part of the environment, called the model. There are many different types of mimicry. Some mimics look like another organism; some smell like another organism; some may even feel like another organism. There are also many ways that mimicking another organism could be helpful. Mimicry may help to hide an organism in plain sight or protect a harmless organism from predation when it mimics a harmful organism. It can even help predators sneak up on prey species when the predator mimics a harmless organism. Camouflage vs. Mimicry In the case of hiding in plain sight, the line between camouflage and mimicry is not sharply defined. Spots or stripes that help an organism blend with the surroundings is classified as camouflage, because those patterns allow the organism to remain hidden in many areas that have mixtures of sunlight and shadow, and the organism does not look like any particular model. As an organism’s appearance begins to mimic another organism more and more closely, rather than displaying just a general pattern, it moves toward mimicry. As in all other areas of biology, there are arguments about where camouflage ends and mimicry begins. The stripes of a tiger and the spots on a fawn are certainly camouflage. The appearance of a stick insect is more ambiguous. Its body is very thin and elongated and is colored in shades of brown and gray. Is this mimicry of a twig or just very good camouflage? Many biologists disagree. The shapes and colors of many tropical insects, especially mantises, also fall into this gray area of either extremely good camouflage or simple mimicry. Coloration: Batesian and Müllerian Mimicry In contrast to camouflage, which hides its bearers, many species of dangerous or unpalatable animals are brightly colored. This type of color pattern, which stands out against the background, is called warning coloration. Some examples are the black and white stripes of the skunk, the yellow 415
Mimicry and black stripes of bees and wasps, red, black, and yellow stripes of the coral snake, and the bright orange of the monarch butterfly. Several species of harmless insects have the same yellow and black pattern that is seen on wasps. In addition to mimicking the coloration of the more dangerous insects, some harmless flies even mimic the wasps’ flying patterns or their buzzing sound. In each case, animals that have been stung by wasps or bees avoid both the stinging insects and their mimics. This mimicry of warning coloration is called Batesian mimicry. Batesian mimicry is also seen in the mimicry of the bright red color of the unpalatable red eft stage of newts by palatable salamanders. Sometimes two or more dangerous or unpalatable organisms look very much alike. In this case, both are acting as models and as mimics. This mimicry is called Müllerian mimicry. Müllerian mimicry is seen in monarch and viceroy butterflies. Both butterflies have in their bodies many of the chemicals found in the plants they ate as larvae. These include many unpalatable chemicals and even toxic chemicals that cause birds to vomit. If a bird eats either a monarch or a viceroy that has these chemicals, the bird usually remembers and avoids preying on either species again—a classic
Monarch butterflies and viceroy butterflies both have in their bodies unpalatable and even toxic chemicals that cause birds to vomit and avoid preying on them later—a classic example of Müllerian mimicry, in which two or more dangerous or unpalatable organisms look very much alike. It is believed that evolutionary processes select for such mimicry because it simplifies the process of recognition and avoidance on the part of predators, thereby increasing the fitness of the similar-looking prey. (PhotoDisc) 416
Mimicry Müllerian mimicry. Interestingly, not all monarchs or viceroys are unpalatable. It depends on the types and concentrations of chemicals in the particular plants on which they fed as larvae. Birds that have eaten the palatable monarchs or viceroys do not reject either monarchs or viceroys when offered them as food, but birds that have eaten an unpalatable monarch or an unpalatable viceroy avoid both palatable and unpalatable members of both species. This represents both Batesian and Müllerian mimicry at work. Aggressive Mimicry Mimicry by predators is called aggressive mimicry. The reef fish, called the sea swallow, is a cleaner fish, and larger fish enter the sea swallow’s territory to be cleaned of parasites. The saber-toothed blenny mimics the cleaner in both appearance and precleaning behavior, but when fish come to be cleaned, the blenny instead bites off a piece of their flesh to eat. Anglerfish have small extensions on their heads that resemble worms. They mimic worms to lure their prey close enough to be eaten. The alligator snapping turtle’s tongue and the tips of the tails of moccasins, copperheads, and other pit vipers are also wormlike and are used as lures. Certain predatory female fireflies respond to the light flashes of males of a different species with the appropriate response of the female of that species. This lures the male closer, and when the unsuspecting male is close enough to mate, the female devours him. This mimicry is quite complex, because the predatory females are able to mimic the response signals of several different species. Octopuses There are many other instances of mimicry, but the world champion mimics may be octopuses. As predators, these animals show unbelievable aggressive mimicry of other reef organisms. Octopuses can take on the color, shape, and even texture of corals, algae, and other colonial reef dwellers. As a prey species, the octopus can use the same type of mimicry for camouflage, but can also be a Batesian mimic, taking on the color and shape of many of the reef’s venomous denizens. Since in each case, being a mimic helped the organism in some way, it is not hard to understand how mimicry may have evolved. In a population in which some organisms were protected by being mimics, the protected mimics were most likely to mate and leave their genes for the next generation while the unprotected organisms were less likely to breed. Richard W. Cheney, Jr.
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Mimicry See also: Altruism; Camouflage; Communication; Defense mechanisms; Displays; Mammalian social systems; Pheromones; Poisonous animals; Predation; Reproductive strategies; Territoriality and aggression. Sources for Further Study Brower, Lincoln P., ed. Mimicry and the Evolutionary Process. Chicago: University of Chicago Press, 1988. Ferrari, Marco. Colors for Survival: Mimicry and Camouflage in Nature. Charlottesville, Va.: Thomasson-Grant, 1993. Owen, D. Camouflage and Mimicry. Chicago: University of Chicago Press, 1982. Salvato, M. “Most Spectacular Batesian Mimicry.” In University of Florida Book of Insect Records, edited by T. J. Walker. Gainesville: University of Florida Department of Entomology and Nematology, 1999. Wickler, Wolfgang. Mimicry in Plants and Animals. New York: McGrawHill, 1968.
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MOUNTAIN ECOSYSTEMS Types of ecology: Biomes; Ecosystem ecology Mountains cover one fifth of the earth’s terrestrial surface, and they are one of the most extreme environments in the global ecosystem. Mountains are globally significant landforms that function as storehouses for irreplaceable resources such as clean air and water, biological and cultural diversity, as well as timber and mineral resources.
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ountains are the most conspicuous landforms on earth. They are found on every continent and have been defined simply as elevated landforms of high local relief, with much of the surface in steep slopes, displaying distinct variations in climate and vegetation zones from the base to the summit. The earth’s mountain ranges have been created by the collision of tectonic plates. Associated with many of these mountain ranges are volcanoes. If the solidified magma of a volcano builds up, it can become a mountain; likewise, if the collision involves two oceanic plates, a string of volcanic mountains, called an island arc, can form on the ocean floor. Mountain Habitat Mountains are globally significant reservoirs of biodiversity. They contain rich assemblages of species and ecosystems. Because of the rapid changes in altitude and temperature along a mountain slope, multiple ecological zones are stacked upon one another, sometimes ranging from dense tropical jungles to glacial ice within a few kilometers. Many plant and animal species are found only on mountains, having evolved over centuries of isolation to inhabit these specialized environments. Mountains can also function as biological corridors, connecting isolated habitats or protected areas and allowing species to migrate between them. These extraordinary ecological conditions, coupled with many bio-climatic zones, have resulted in a high number of ecological niches available for habitation in mountain ecosystems. Biodiversity Because of the great diversity in habitats within mountainous regions, with each region showing a different combination of environmental factors, total mountain fauna is relatively rich and the variety of small communities very great, in spite of the general severity of the mountain environment as a whole. Likewise, this diversity has resulted in a wide range of 419
Mountain ecosystems
Mountains are perhaps the most significant reservoirs of biodiversity. Because of the rapid changes in altitude and temperature along a mountain slope, multiple ecological zones are stacked upon one another—sometimes ranging from dense tropical jungles to glacial ice—and therefore contain rich assemblages of species and ecosystems. (PhotoDisc)
endemic species that have evolved over centuries of isolation from other genetic material. Rocky Mountain National Park typifies this diversity as a home to some 900 species of plants, 250 species of birds, and 60 species of mammals. Some are easily seen and others are elusive, but all are part of the ecosystem in the park. On a global scale, the diversity of mountain fauna extends to many species of ungulates, including elk, bighorn sheep, moose, and deer. Also present in mountain communities are many species of rodents. Rodent species may include beaver, marmots, squirrels, and chipmunks. Other mammalian animal life include bear, canids, such as coyote and wolf, and many species of felids, such as mountain lions and bobcats. Mountain avian fauna comprise many families of hummingbirds, bluebirds, hawks, falcons, eagles, and many more. Ecological Threats Mountains are threatened in a variety of ways, but without question, human settlement and activities such as camping, hiking, and other recreational activities constitute the biggest threats to the mountain ecosystem. 420
Mountain ecosystems Hikers and motorized offroad vehicles, for example, create tracks in the soil that form erosion gullies and trample vegetation that has taken many years to grow. Commercial harvesting of trees in the lower forest zones of mountains is having an increasingly detrimental effect on biodiversity. Global warming is another threat to mountain ecosystems. Snowlines are receding, and continued melting of glaciers and polar ice caps could eventually lead to drying of major river systems which feed from them. In an attempt to restore or conserve mountain ecosystems, many countries have replanted indigenous trees with fast-growing coniferous trees, in an ill-fated effort to supply a growing human population with wood products. These hybrid forests are not nearly as beautiful as the native forests, but more to the point, they do not offer environments conducive to the ecosystems that the native species supported. This loss of habitat creates a loss of wildlife, which then becomes threatened and eventually endangered because of the decline of native vegetation. Jason A. Hubbart See also: Biomes: types; Forest fires; Forest management; Forests; Grazing and overgrazing; Habitats and biomes; Lakes and limnology; Old-growth forests; Rain forests; Rain forests and the atmosphere; Restoration ecology; Savannas and deciduous tropical forests; Sustainable development; Taiga; Tundra and high-altitude biomes; Wildlife management. Sources for Further Study Denniston, D. High Priorities: Conserving Mountain Ecosystems and Cultures. Worldwatch Paper 123. Washington, D.C.: Worldwatch Institute, 1995. Messerli, B., and J. D. Ives. Mountains of the World: A Global Priority. New York: Parthenon, 1997. Price, L. Mountains and Man. Berkeley: University of California Press, 1981. Sauvain, P. Geography Detective: Mountains. Minneapolis: Carolrhoda Books, 1996. Stronach, N. Mountains. Minneapolis: Lerner, 1995.
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MULTIPLE-USE APPROACH Types of ecology: Agricultural ecology; Restoration and conservation ecology The multiple-use approach is a concept of resource use in which land supports several concurrent managed uses rather than single uses over time and space.
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he multiple-use approach is a management practice that is teamed with the concept of sustained yield. Multiple use began as a working policy, generally associated with forestry, and was enacted as law in 1960. As a concept of land-use management, it has most often been applied to the use of forestlands. Historically, multiple use has been linked with another concept, that of sustained yield. Historical Background The history of the intertwined multiple-use and sustained-yield approaches to land management in the United States dates from the late 1800’s. Prior to that time, forestlands were used for timber production, rangeland for grazing, and parklands for recreation. Little attention was given to the interrelated aspects of land use. By the late 1800’s, however, some resource managers began to see land as a resource to be managed in a more complex, integrated fashion that would lead to multiple use. This awakening grew out of the need for conservation and sustained yield, especially in the forest sector of the resource economy.
Sustained Yield Since the earliest European settlement of North America, forest resources had been seen both as a nearly inexhaustible source of timber and as an impediment to be cleared to make way for agriculture. This policy of removal led to serious concern by the late 1800’s about the future of American forests. By 1891 power had been granted to U.S. president Benjamin Harrison to set aside protected forest areas. Both he and President Grover Cleveland took action to establish forest reserves. To direct the management of these reserves, Gifford Pinchot was appointed chief forester. Pinchot was trained in European methods of forestry and managed resources, as noted by Stewart Udall in The Quiet Crisis (1963), “on a sustained yield basis.” The sustainedyield basis for forest management was thus established. Essentially, the sustained-yield philosophy holds that the amount of timber harvested should not exceed the ultimate timber growth during the same period. 422
Multiple-use approach Multiple Use Properly managed, forestlands can meet needs for timber on an ongoing, renewable basis. However, land in forest cover is more than a source of timber. Watersheds in such areas can be protected from excessive runoff and sedimentation through appropriate management. Forest areas are also wildlife habitat and potential areas of outdoor recreation. The combination of forest management for renewable resource production and complex, interrelated land uses provided the basis for the development of multipleuse sustained-yield as a long-term forest management strategy. Multiple Use Joins Sustained Yield The merging of these two concepts took shape over a period of many years, beginning in the early twentieth century. The establishment of national forests by Presidents Harrison and Cleveland provided a base for their expansion under President Theodore Roosevelt in the early 1900’s. With the active management of Pinchot and the enthusiastic support of Roosevelt, the national forests began to be managed on a long-term, multiple-use sustained-yield basis. The desirability of this approach eventually led to its formalization by law: On June 12, 1960, Congress passed the Multiple Use-Sustained Yield Act. To some, this act was the legal embodiment of practices already in force. However, the act provides a clear statement of congressional policy and relates it to the original act of 1897 that had established the national forests. The 1960 act specifies that “the national forests are established and shall be administered for outdoor recreation, range, timber, watershed, and wildlife and fish purposes.” Section 2 of the act states that the “Secretary of Agriculture is authorized and directed to develop and administer the renewable resources of the national forests for multiple use and sustained yield of the several products and services obtained therefrom.” The act gives no specifics, providing a great deal of freedom in choosing ways to meet its provisions. It also refrains from providing guidelines for management. In practice, the achievement of a high level of land management under the act has called for advocating a conservation ethic, soliciting citizen participation, providing technical and financial assistance to public and private forest owners, developing international exchanges on these management principles, and extending management knowledge. Jerry E. Green See also: Biopesticides; Conservation biology; Erosion and erosion control; Genetically modified foods; Grazing and overgrazing; Integrated pest management; Old-growth forests; Rangeland; Reforestation; Restoration 423
Multiple-use approach ecology; Slash-and-burn agriculture; Soil; Soil contamination; Sustainable development. Sources for Further Study Cutter, Susan, Hilary Renwick, and William Renwick. Exploitation, Conservation, Preservation: A Geographical Perspective on Natural Resource Use. 3d ed. New York: J. Wiley & Sons, 1999. Hewett, Charles E., and Thomas E. Hamilton, eds. Forests in Demand: Conflicts and Solutions. Boston: Auburn House, 1982. Lovett, Francis. National Parks: Rights and the Common Good. Lanham, Md.: Rowman & Littlefield, 1998. Sedjo, Roger A., ed. A Vision for the U.S. Forest Service: Goals for Its Next Century. Washington, D.C.: Resources for the Future, 2000. Udall, Stewart. The Quiet Crisis. 1963. Reprint. Salt Lake City, Utah: Gibbs Smith, 1998.
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MYCORRHIZAE Type of ecology: Community ecology Mycorrhizae are mutualistic, symbiotic relationships between plant roots or other underground organs and fungi. They are among the most abundant symbioses in the world.
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ycorrhizal associations (from the Greek mukes, meaning “fungus,” and rhiza, meaning “root”) have been described in virtually all economically important plant groups. Investigators in Europe detected fungal associations in most European species of flowering plants, all gymnosperms, ferns, and some bryophytes, especially the liverworts. Similar patterns are predicted in other ecosystems. Continuing studies of ecosystems, from boreal forests to temperate grasslands to tropical rain forests and agroecosystems, also suggest that most plant groups are intimately linked to one or more species of fungus. It is theorized that most of the plants in stable habitats where competition for resources is common probably have some form of mycorrhizal association. Species from all the major taxonomic groups of fungi, including the Ascomycotina, Basidiomycotina, Deuteromycotina, and Zygomycotina, have been found as partners with plants in mycorrhizae. Considering the prevalence of mycorrhizae in the world today, botanists theorize that mycorrhizae probably arose early in the development of land plants. Some suggest that mycorrhizae may have been an important factor in the colonization of land. The fungal partner (or mycobiont) in a mycorrhizal relationship benefits by gaining a source of carbon. Often these mycobionts are poor competitors in the soil environment. Some mycobionts have apparently coevolved to the point that they can no longer live independently of a plant host. The plant partner in the mycorrhizal relationship benefits from improved nutrient absorption. This may occur in different ways; for example, the mycobiont may directly transfer nutrients to the root. Infected roots experience more branching, thus increasing the volume of soil that the plant can penetrate and exploit. Evidence also suggests that mycorrhizal roots may live longer than roots without these associations. Comparison of the growth of plants without mycorrhizae to those with fungal partners suggests that mycorrhizae enhance overall plant growth.
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Mycorrhizae Endomycorrhizae Mycorrhizae may be classified into two broad groups: endomycorrhizae and ectomycorrhizae. Endomycorrhizae enter the cells of the root cortex. Ectomycorrhizae colonize plant roots but do not invade root cortex cells. The most common form of endomycorrhizae are the vesicular-arbuscular mycorrhizae. The fungi involved are zygomycetes. These mycorrhizae have internal structures called arbuscules, which are highly branched, thin-walled tubules inside the root cortex cells near the vascular cylinder. It is estimated that 80 percent of all plant species may have vesiculararbuscular mycorrhizae. This type of mycorrhiza is especially important in tropical trees. There are several other subtypes of endomycorrhizae. Ericoid mycorrhizae, found in the family Ericaceae and closely related families, supply the host plants with nitrogen. These are usually restricted to nutrient-poor, highly acidic conditions, such as heath lands. Arbutoid mycorrhizae, found in members of the Arbutoideae and related families, share some similarities with ectomycorrhizae in that they form more developed structures called the sheath and Hartig net (described below). Monotropoid mycorrhizae, found in the plant family Monotropaceae, are associated with plants that lack chlorophyll. The host plant is completely dependent on the mycobiont, which also has connections to the roots of a nearby tree. Thus the host, such as Monotropa, indirectly parasitizes another plant by using the mycobiont as an intermediate. Orchidaceous mycorrhizae are essential for orchid seed germination. Ectomycorrhizae Ectomycorrhizae are common in forest trees and shrubs in the temperate and subarctic zones. Well-developed fungal sheaths characterize these mycorrhizae, along with special structures called Hartig nets. Basidiomycetes are the usual mycobionts and often form mushrooms or truffles. Ectomycorrhizae help protect the host plant from diseases by forming a physical fungal barrier to infection. The Fungal Partner Individual filaments of a fungal body are called hyphae. The entire fungal body is called a mycelium. Root infection may occur from fungal spores that germinate in the soil or from fungal hyphae growing from the body of a nearby mycorrhiza. When infection occurs, hyphae are drawn toward certain chemical secretions from a plant root. In ectomycorrhizae, root hairs do not develop in roots after infection occurs. Infected roots have a fungal sheath, or mantle, that ranges from 20 to 426
Mycorrhizae 40 micrometers thick. Fungal hyphae penetrate the root by entering between epidermal cells. These hyphae push cells of the outer root cortex apart and continue to grow outside the cells. This association of hyphal cells and root cortex cells is called a Hartig net. In ectomycorrhizae, the mycobionts never invade plant cells, nor do they penetrate the endodermis or enter the vascular cylinder. The root tip may be ensheathed by fungi, but the apical meristem is never invaded. Main roots experience fewer anatomical changes than lateral roots after infection. Lateral roots become thickened, may show the development of characteristic pigments, and grow very slowly. Infected roots also show different branching patterns, compared to those of uninfected roots. Endomycorrhizae are highly variable in structure. Many endomycorrhizae do not have sheaths or Hartig nets. In all endomycorrhizae, hyphae penetrate into root cortex cells, while portions of the mycelium remain in contact with the soil. The hyphae that remain in the soil are important in fungal reproduction and produce large numbers of haploid spores. Fungi do not invade root meristems, vascular cylinders, or chloroplast-containing cells in the plant. Some of the host cells contain fungal extensions called vesicles that are filled with lipids. Vesicles are specialized structures that are often thickwalled and may serve as storage sites or possibly in reproduction. Vesicles are also produced on the hyphae that grow in the soil. Near the vascular cylinder, the hyphae branch dichotomously and form large numbers of thin-walled tubules called arbuscules that invade host cells. The arbuscules cause the host membranes to fold inward, creating a plant-fungus interface that has a very large surface area. The arbuscules last for about fourteen days before they break down on their own or are digested by the host cell. Host cells whose fungal arbuscules have broken down may be reinvaded by other hyphae. Darrell L. Ray See also: Coevolution; Communities: ecosystem interactions; Communities: structure; Lichens; Old-growth forests; Symbiosis. Sources for Further Study Deacon, J. W. Modern Mycology. 3d ed. Malden, Mass.: Blackwell Science, 1997. Harley, J. L., and S. E. Smith. Mycorrhizal Symbiosis. New York: Academic Press, 1983. Raven, Peter H., Ray F. Evert, and Susan E. Eichhorn. Biology of Plants. 6th ed. New York: W. H. Freeman/Worth, 1999. 427
NATURAL SELECTION Types of ecology: Evolutionary ecology; Speciation Natural selection is the process of differential survival and reproduction of individuals resulting in long-term changes in the characteristics of species. This process is central to evolution.
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atural selection is a three-part process. First, there must exist differences among individuals in some trait. Second, the trait differences must lead to differences in survival and reproduction. Third, the trait differences must have a genetic basis. Natural selection results in long-term changes in the characteristics of a population. As one of the central processes responsible for evolution, natural selection results in both finetuning adaptations of populations and species to their environments and creating differences among species. The importance of natural selection was first recognized by Charles Darwin as the primary mechanism for evolutionary change. Processes that support natural selection include genetic drift and migration. These processes interact with the processes responsible for producing variation (mutation and development) and those responsible for determining the rate and direction of evolution (mating system, population size, and long-term ecological changes) to establish the evolutionary path of a species. The Basic Process Natural selection occurs through the interaction of three conditions: variation among individuals in a population in some trait, differences in those individuals’ fitness as a result of the variations in that trait, and heritable variation in that trait. If those three conditions are met, then the characteristics of the population with respect to that trait will change from one generation to the next until equilibrium with other processes is reached. An example that demonstrates this process involves the peppered moth. It has two forms in the United Kingdom, a light-colored form and a darkcolored form; there is variation in color among individuals. Genetic analysis has shown that this difference in color is caused by a single gene; the variation has a heritable basis. The moth is eaten by birds that find their food by sight. The light-colored form cannot be seen when sitting on lichencovered trees, while the dark-colored form can be seen easily. Air pollution kills the lichen, however, and turns the trees dark in color. Then, the darkcolored form is hidden and the light-colored form visible. Thus, differ428
Natural selection ences in color lead to fitness differences: Dark moths will become more fit if air pollution increases, renders them less visible to predators, and thereby makes it likelier that their genetic material will pass into another generation. In fact, this proved to be the case: In the early nineteenth century, the dark-colored form was very rare. In the last half of the nineteenth century, however, air pollution increased, and the dark-colored form became much more frequent as a result of natural selection. Directional Selection The characteristics of a population can be changed by natural selection in several ways. If individuals in a population with an extreme value for a trait have the greatest fitness on average, then the mean value of the trait will change in a consistent direction, which is called directional selection. For example, the soil in the vicinity of mines contains heavy metals that are toxic to plants. Individuals with the greatest resistance to heavy metals have the highest survivorship. Evolution leads to an increase in resistance. Stabilizing Selection If individuals in a population with intermediate values for a trait have the greatest fitness on average, then the variation in the trait will be reduced, which is called stabilizing selection. For example, in many species of birds, individuals with intermediate numbers of offspring have the greatest fitness. If an individual has a small number of offspring, that parent has reduced reproduction and a low fitness. If the number of offspring is large, the parent will not be able to provide enough food for all the young, and most, or all, will starve, again resulting in reduced reproduction and a low fitness. Evolution leads to all birds producing the same, intermediate number of offspring. Disruptive Selection If individuals in a population with different values for a trait have the greatest fitnesses on average and intermediates have low fitness, then the variation in the trait will be increased. This is called disruptive selection. For example, for Darwin’s finches, individuals with long, thin bills are able to probe into rotting cacti to find insects. Individuals with short, thick bills are able to crack hard seeds. Individuals with intermediate-shaped bills are not able to do either well and have reduced fitness relative to the more extreme types. Evolution therefore leads to two different species of finch with different bills. Natural selection is a slow process. The rate of evolution—that is, response to selection—is determined by the magnitude of fitness differences 429
Natural selection among individuals and the heritability of traits. Fitness differences tend to be small so that more fit individuals on average may have only a few more offspring than less fit individuals. Heritabilities of most traits are low to intermediate, meaning that most differences among individuals are not a result of genetic differences. Therefore, even if one individual has many offspring and another has few offspring, they may not differ genetically and no change will occur. For example, if all the beetles in a population were between one and two centimeters in length and there was selection for larger beetles, it could take five hundred generations before all beetles were larger than two centimeters. Also, the direction of selection may change from one generation to the next, so that no net change occurs. Correlational Selection Natural selection does not act on traits in isolation. How a trait affects fitness in combination with other traits—called correlational selection—is important. For example, fruit flies lay their eggs in rotting fruit. Considered in isolation, a female should always lay as many eggs as possible. One fruit is not big enough for all the eggs she might lay, however, so she must fly from fruit to fruit. Flying requires energy, and the more energy that is used in flight the less that can be used to make eggs. Hence, natural selection results in the division of energy between eggs and flight that yields the greatest overall number of offspring. This example demonstrates that the result of natural selection is often a trade-off among different traits. Sexual Selection By acting differently on males and females, natural selection results in sexual selection. This form of selection can explain differences in the forms of males and females of a species. In general, because male gametes, sperm, are much smaller and “cheaper” to produce than female gametes, eggs, more sperm than eggs are produced. As a result, it is possible for one male to fertilize many eggs, while other males fertilize few or no eggs. For example, a lion pride usually consists of one or a few males and many females. Other males are excluded, and they live separately; larger males are able to chase away smaller males. The thick mane on male lions helps to protect their throats when they fight other males. Thus, larger males with thicker manes tend to survive, fathering more cubs than other males, leading to additional bias in selection favoring these traits. This is an example of sexual selection because the only selection pressure for the trait in question is on males; all females, regardless of size, will mate. The result is that males are larger than females and have manes. 430
Natural selection Group and Kin Selection Natural selection can occur not only among individuals but also among groups. This process is generally known as group selection; when the groups are composed of related individuals, it is called kin selection. Group selection operates the same way as individual selection. The same three conditions are necessary: variation among groups in some trait, fitness differences among groups because of that trait, and a heritable basis for that trait. For example, in Australia, rabbits introduced from Europe in 1859 spread rapidly during the next sixty years. In order to control the rabbits, a virus was introduced in 1950. At first, the virus was very virulent, killing almost all infected animals within a few days. After ten years, however, the virus had evolved to become more benign, with infected rabbits living longer or not becoming sick at all. Virulent strains of the virus grow and reproduce faster than benign strains. Therefore, within a single rabbit, virulent strains have a higher fitness than benign strains. The longer a rabbit lives, however, the more opportunity there is for the virus to be passed to other rabbits. Thus, a group of benign viruses infecting a rabbit are more likely to be passed on than a group of virulent viruses. In this example, group selection among rabbits resulted in evolution opposite to individual selection within rabbits; however, group selection and individual selection can result in evolution in the same direction. In general, natural selection can act at many levels: the gene, the chromosome, the individual, a group of individuals, the population, or the species. Measuring Natural Selection Natural selection is investigated in two ways: through indirect measurement and through direct measurement. Indirect methods involve observing the outcome of natural selection and inferring its presence. Direct methods involve measuring the three parts of the process and following the course of evolution. Although the direct methods are preferred, as they provide direct proof of natural selection, in most instances, only indirect methods can be used. Indirect methods involve three kinds of observations. First, comparisons are made of trait similarities or differences among populations or species living in the same or different areas. For example, many species of animals living in colder climates have larger bodies than those living in warmer climates. It is inferred, therefore, that colder climates result in natural selection for larger bodies. Second, long-term studies are done of traits, in particular changes in a group in the fossil record. For example, during the evolution of horses, their food, grasses, became tougher and 431
Natural selection horses’ teeth became thicker. It is inferred, therefore, that tough grass resulted in natural selection for thicker teeth. Third, comparisons are made of gene frequencies of natural populations, with predictions from mathematical models. Gene frequencies are measured using various techniques, including scoring differences in appearance, as with light-colored and dark-colored moths; using electrophoresis to observe differences in proteins; and determining the sequence of base pairs of deoxyribonucleic acid (DNA). The models make predictions about expected frequencies in the presence or absence of selection. Indirect methods are best at revealing long-term responses to evolution and general processes of natural selection that affect many species. The indirect methods suffer from the problem that often many processes will result in similar patterns. So, it must be assumed that other processes were not operating, or other predictions must be made to separate the processes. Direct methods involve two kinds of observation. First, there is observation of changes in a population following some change in the environment. There are many types of environmental changes, including humanmade changes, natural disasters, seasonal changes, and introductions of species into new environments. For example, from the changes in the peppered moth following a change in pollution levels, one can measure the effects of natural selection. The second type of observation is the direct measurement of fitness differences among individuals with trait differences. For example, individual animals are tagged at an early age and survival and reproduction are monitored. Then, statistical techniques are used to find a relationship between fitness and variation among individuals in some trait. Alternatively, comparisons of traits are made between groups of individuals, such as breeding and nonbreeding, adults and juveniles, or live and dead individuals, again using statistical techniques. For example, lions that breed are larger than lions that do not breed. Direct methods are best at revealing the relative importance to natural selection of the three factors (variation, fitness differences, and heritability). The direct methods suffer from two limitations. It takes a long time for evolution to occur. So, although one can measure natural selection, it is often not known if it results in evolution. Also, for many species, it is impossible or impractical to mark individuals and follow them through their lives. Many methods can be used to study natural selection and evolution. Each method provides information about different parts of the process. Only through the integration of these methods can the entire process of evolution be revealed. Knowledge of natural selection is still growing; many questions proposed by Darwin and others are yet to be answered. It is still not known to 432
Natural selection what extent organisms are well adapted to their environments or whether the evolution of the parts of the chromosome that are not translated into proteins are a result of processes that do not involve natural selection. Of the many theories of how natural selection works, it is still unknown which ones are the most important in nature and to what extent evolution is caused by natural selection at the level of the individual, the group, and the species. Ecological Implications Scientists and researchers combined their knowledge of natural selection with a revolutionary breakthrough in molecular biology in the 1950’s: the discovery of the helical structure of deoxyribonucleic acid (DNA) and subsequent discoveries and developments surrounding recombinant DNA technology. The resultant manipulation of traits in organisms from crops to mammals led to an age of genetic engineering. Today, strawberries, soybeans, dairy products, and a host of other foods, as well as higher organisms including human tissues, can be genetically manipulated to beneficial, as well as often unintended negative, ends. The addition of a new gene into an organism will result in natural selection on that gene and change selection on other genes. For example, certain crop plants genetically modified to resist herbicides have begun to mix with native species considered weeds, creating a new problem of “superweeds” resistant to herbicides. An understanding of natural selection is also critical for conservation biology. During the twentieth century, the rate at which natural areas are being destroyed and species are becoming extinct has accelerated tremendously. Conservation biology attempts to stop that destruction and preserve species diversity. For extinction of endangered species to be halted, it must be understood how natural selection will affect these species given massive environmental changes. By discovering how evolution is occurring under natural conditions, researchers are learning how to design nature preserves to maintain species. Samuel M. Scheiner, updated by Christina J. Moose See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Development and ecological strategies; Evolution: definition and theories; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Genetically modified foods; Isolating mechanisms; Nonrandom mating, genetic drift, and mutation; Paleoecology; Population genetics; Punctuated equilibrium vs. gradualism; Speciation; Species loss. 433
Natural selection Sources for Further Study Avers, Charlotte J. Process and Pattern in Evolution. New York: Oxford University Press, 1989. Bell, Graham. Selection: The Mechanism of Evolution. New York: Chapman and Hall, 1997. Brandon, Robert N. Adaptation and Environment. Princeton, N.J.: Princeton University Press, 1990. Darwin, Charles. On the Origin of Species by Means of Natural Selection. London: J. Murray, 1859. Endler, John A. Natural Selection in the Wild. Princeton, N.J.: Princeton University Press, 1986. Futuyma, Douglas J. Evolutionary Biology. 3d ed. Sunderland, Mass.: Sinauer Associates, 1998. Gould, Stephen J. The Panda’s Thumb. New York: W. W. Norton, 1980. Pianka, Eric R. Evolutionary Ecology. Boston: Addison-Wesley, 1999. Provine, William B. Sewall Wright and Evolutionary Biology. Chicago: University of Chicago Press, 1986.
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NONRANDOM MATING, GENETIC DRIFT, AND MUTATION Types of ecology: Evolutionary ecology; Population ecology Nonrandom mating, genetic drift, and mutation are three mechanisms, besides natural selection and migration, that can change the genetic structure of a population.
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volution is a process in which the gene frequencies of a population change over time, and nonrandom mating, genetic drift, and mutation are all mechanisms of genetic change in populations. These mechanisms violate the assumptions of the Hardy-Weinberg model of genetic equilibrium by increasing or decreasing the frequency of heterozygote genotypes in the population. Nonrandom Mating Nonrandom mating occurs in a population whenever every individual does not have an equal chance of mating with any other member of the population. While many organisms do tend to mate randomly, there are some common patterns of nonrandom mating. Often, individuals tend to mate with others nearby, or they may choose mates that are most like themselves. When individuals choose mates that are phenotypically similar, positive assortative mating has occurred. If mates look physically different, then it is negative assortative mating. Population geneticists use the term “assortative” because it means “to separate into groups,” usually in a pattern that is not random. The terms “positive” and “negative” refer to the probability that mated pairs have the same phenotype more or less often than expected by chance. Two color varieties of snow geese (Chen hyperborea), blue and white, are commonly found breeding in Canada, and they show positive assortative mating patterns based on color. The geese tend to mate only with birds of the same color; blue mate with blue and white with white. Since a bird’s color (phenotype) is determined by the presence of a dominant blue color allele, matings between similar phenotypes are also matings between similar genotypes. Matings between similar genotypes cause the frequency of individuals that are homozygous for the blue or the white allele to be greater, and the frequency of heterozygotes to be less than if mating were random and in Hardy-Weinberg equilibrium. Negative assortative mating increases the frequency of heterozygote genotypes in the population and decreases homozygote frequency. 435
Nonrandom mating, genetic drift, and mutation Assortative mating does not change the frequency of the blue or white alleles in the goose population; it simply reorganizes the genetic variation and shifts the frequency of heterozygotes away from Hardy-Weinberg equilibrium frequencies. Inbreeding Inbreeding is the mating of relatives and is similar to positive assortative mating because like genotypes mate and result in a high frequency of homozygotes in the population. In assortative mating, only those genes that influence mate choice become homozygous, but inbreeding increases the homozygosity of all the genes. High homozygosity means that many of the recessive alleles that were masked by the dominant allele in heterozygotes will be expressed in the phenotype. Deleterious or harmful alleles can remain hidden from selection in the heterozygote, but after one generation of inbreeding, these deleterious alleles are expressed in a homozygous condition and can substantially reduce viability below normal levels. Low viability resulting from mating of like genotypes is called inbreeding depression. Genetic Drift Genetic drift, like positive assortative mating, reduces the frequency of heterozygotes in a population, but with genetic drift, the frequency of alleles in a population changes. Nonrandom mating does not change allele frequency. Genetic drift is sometimes called random genetic drift because the mechanism of genetic change is random and attributable to chance events in small populations, such that allele frequencies tend to wander or drift. Statisticians use the term “sampling effect” to describe observed fluctuations from expected values when only a few samples are chosen, and it is easy to observe by tossing a coin. A fair coin flipped a hundred times would be expected to produce approximately fifty heads and fifty tails, plus or minus a few heads or tails. Yet, if the coin is flipped only four times, it is not too surprising to get four heads or four tails. The probability of getting either all heads or all tails on four consecutive flips is one out of eight, but the probability of getting all heads or all tails decreases to much less than one in a billion as the sample size increases from four to a hundred tosses. Similarly, it is much easier for nonrandom events to occur in small populations than in large populations. If a population has two alleles with equal frequency for a particular trait, then the result of random mating can be simulated by tossing a coin. The frequency of each allele in the next generation would be determined by flipping the coin twice for each individual, since sexually reproducing organisms have two alleles for each trait, 436
Nonrandom mating, genetic drift, and mutation and counting the number of heads and tails. In a small population, only a few gametes, each containing one allele for the trait, will fuse to form zygotes. Chance events can cause the frequencies of alleles in a small population to drift randomly from generation to generation; often one allele is lost from the population. In small populations with fewer than fifty mating pairs, alleles may be eliminated in fewer than twenty generations by random genetic drift, leaving only one allele for a particular trait in the population. Thus, all individuals would be homozygous for the remaining allele and genetically identical. Theoretically, in any finite population random genetic drift will occur, but it is usually negligible if the population size is greater than a hundred. Sometimes, disasters or disease may drastically reduce the population size, causing a bottleneck effect. The bottleneck in population size reduces genetic variability in a population because there are only a few alleles and results in random genetic drift. Many islands and new populations are established by a small group of founders that constitute a nonrandom genetic sample because they have only a fraction of the alleles from the original large population. Founder effects and bottleneck effects are phenomena that result in a loss of heterozygosity and decreased genetic variability because of the chance drift in allele frequency away from Hardy-Weinberg equilibrium values in small populations. Mutations Mutations are any changes in the genetic material that can be passed on to offspring. Some mutations are changes at a single point in the chromosome, while at other times, pieces of genetic material are removed, extra pieces are added, or pieces are exchanged with other chromosomes. All these changes could result in the formation of new alleles or could change one allele into a different allele. The random mistakes in the chromosomes occur at the molecular level, and only later are the changes in information or alleles translated into phenotypic differences. Thus, mutation is the ultimate source of genetic variability and is random with respect to the needs of the organism. Most mutations are lethal and are never expressed, but nonlethal mutations provide the necessary variation for natural selection. Even though mutations are very important for evolution, they have only a small effect on allele and genotype frequencies in populations because mutation rates are relatively low. If an allele makes up 50 percent of the gene pool and mutates to another allele once for every hundred thousand gametes, it would take two thousand generations to reduce the frequency of the allele by 2 percent. The net effect of mutations is to increase genetic variability, but at a very slow rate. 437
Nonrandom mating, genetic drift, and mutation Studying Genetic Variability Population geneticists use a wide variety of laboratory, field, and natural experiments to investigate genetic variability. Natural experiments are situations that have developed without a scientist intentionally designing an experiment, but conditions are such that scientists can test a theory. Researchers have used known pedigrees or ancestral histories of zoo animals and have found that mortality rates of inbred young are often two to three times higher than for noninbred young. Population geneticists use pedigrees to calculate the probability that two alleles are identical by descent; this research provides an index of the amount of inbreeding in a population. The study of random genetic drift is usually carried out in the laboratory. Scientists often use small organisms that reproduce quickly, such as fruit flies (Drosophila melanogaster), to conserve space and save time. In a 1956 study of eye color conducted by Peter Buri, after only eighteen generations and sixteen fruit flies per population, more than half of the 107 populations started had only one of the two alleles for eye color. Mutations are so rare that even fruit flies reproduce too slowly for scientists to study the effects of mutations on populations, even though much is known about the mechanism of mutation by studying Drosophila. Small bacterial growth chambers can hold many millions of bacterial cells, and, since they reproduce quickly, even mutations that occur in only one in a million cells can be detected. In 1955, it was found that mutation rates were very low in bacteria until caffeine was added to the growth chamber, whereupon mutation rates increased tenfold. Any chemical or type of radiation that can cause mutations is called a mutagen. Electrophoresis has also been a useful tool for the study of nonrandom mating, genetic drift, and mutations, because allele and genotype frequencies can be determined from samples of the population and unique alleles can be identified. The Dangers of Inbreeding Most governments and religions forbid marriages between close relatives because matings between first cousins result in a 20 percent decrease in heterozygosity; for those between brothers and sisters, there is an 80 percent decrease in heterozygosity. The decrease in heterozygosity and genetic variation and increase in homozygote frequency often result in inbreeding depression because deleterious recessive alleles are expressed. All inbreeding is not undesirable; many of the prizewinning bulls and pigs at state fairs have some inbreeding in their pedigrees. Most breeds of dogs were produced by breeding close relatives so that the offspring would have particular traits. 438
Nonrandom mating, genetic drift, and mutation Zookeepers and others that breed and protect rare and endangered species must continually be concerned about the negative effects of both inbreeding and genetic drift. Most zoos are lucky if they have two or three pairs of breeding adults, and total population sizes are usually very small compared to those of natural populations. These conditions mean that inbreeding may reduce the vigor of the population and genetic drift will reduce the diversity of alleles in the population, thus reducing the chances of survival for the captive species. There is hope for rare and endangered species if independent inbred lines are crossed, thus reducing the effects of inbreeding depression, and if breeding adults from other zoos or populations are traded occasionally, thus increasing the effective population size. Mutations are the ultimate source of genetic variation and so are very important in the study of evolution, but the population-level effects of one mutation are difficult to study because of the low frequency of natural mutations. Certain nonlethal mutations may have little evolutionary impact but may be important medically because spontaneous mutations result in hemophilia or dwarfism (achondroplasia) in more than 3 out of 100,000 cases. As exposure to background radiation and chemical levels increases, mutation rates are likely to increase, as well as the incidence of mutationrelated diseases. William R. Bromer See also: Biodiversity; Gene flow; Genetic diversity; Genetic drift; Pollination; Population genetics; Speciation; Zoos. Sources for Further Study Ayala, Francisco J. Population and Evolutionary Genetics: A Primer. Menlo Park, Calif.: Benjamin/Cummings, 1982. Crow, J. F. Basic Concepts in Population, Quantitative, and Evolutionary Genetics. New York: W. H. Freeman, 1986. Fisher, R. A. The Genetical Theory of Natural Selection. New York: Dover, 1958. Hartl, Daniel L. A Primer of Population Genetics. 3d ed. Sunderland, Mass.: Sinauer Associates, 2000. Mettler, L. E., T. G. Gregg, and H. E. Schaffer. Population Genetics and Evolution. 2d ed. Englewood Cliffs, N.J.: Prentice-Hall, 1988. Real, Leslie A., ed. Ecological Genetics. Princeton, N.J.: Princeton University Press, 1994. Wilson, Edward O., and W. H. Bossert. A Primer of Population Biology. Sunderland, Mass.: Sinauer Associates, 1971.
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NUTRIENT CYCLES Types of ecology: Ecoenergetics; Ecosystem ecology Within an ecosystem, nutrients move through biogeochemical cycles. Those cycles involve chemical exchanges of elements among the earth’s atmosphere, water, living organisms, soil, and rocks.
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ll biogeochemical cycles—whether the carbon cycle, the hydrologic cycle, the nitrogen cycle, the phosphorus cycle, or others—have a common structure, sharing three basic components: inputs, internal cycling, and outputs. Input of Nutrients The input of nutrients to an ecosystem depends on the type of biogeochemical cycle. Nutrients with a gaseous cycle, such as carbon and nitrogen, enter an ecosystem from the atmosphere. For example, carbon enters ecosystems almost solely through photosynthesis, which converts carbon dioxide to organic carbon compounds. Nitrogen enters ecosystems through a few pathways including lightning, nitrogen-fixing bacteria, and atmospheric deposition. In agricultural ecosystems, nitrogen fertilization provides a great amount of nitrogen influx, much larger than by any other influx pathways. In contrast to carbon and nitrogen with input from the atmosphere, the input of nutrients such as calcium and phosphorus depends on the weathering of rocks and minerals. Soil characteristics and the process of soil formation have a major influence on processes involved in nutrient release to recycling pools. Supplementary soil nutrients come from airborne particles and aerosols, as wet or dry depositions. Such atmospheric deposition can supply more than half of the input of nutrients to some ecosystems. The major sources of nutrients for aquatic ecosystems are inputs from the surrounding land. These inputs can take the forms of drainage water, detritus and sediment, and precipitation. Flowing aquatic systems are highly dependent on a steady input of detrital material from the watershed through which they flow. Internal Cycling Internal cycling of nutrients occurs when nutrients are transformed in ecosystems. Plants take up mineral (mostly inorganic) nutrients from soil through their roots and incorporate them into living tissues. Nutrients 440
Nutrient cycles in the living tissues occur in various forms of organic compounds and perform different functions in terms of physiology and morphology. When these living tissues reach senescence, the nutrients are usually returned to the soil in the form of dead organic matter. However, nitrogen can be reabsorbed from senescent leaves and transferred to other living tissues. Various microbial decomposers transform the organic nutrients into mineral forms through a process called mineralization. The mineralized nutrients are once again available to the plants for uptake and incorporation into new tissues. This process is repeated, forming the internal cycle of nutrients. Within the internal cycles, the majority of nutrients are stored in organic forms, either in living tissues or dead organic matter, whereas mineral nutrients represent a small proportion of the total nutrient pools. Output of Nutrients The output of nutrients from an ecosystem represents a loss. Output can occur in various ways, depending on the nature of a specific biogeochemical cycle. Carbon is released from ecosystems to the atmosphere in the The Nitrogen Cycle form of carbon dioxide via Nitrogen in the process of respiration atmosphere by plants, animals, and microorganisms. Nitrogen is Nitrogen Denitrification lost to the atmosphere in fixation by bacteria gaseous forms of nitrogen, nitrous oxide, and ammoFeeding nia, mostly as by-products of microbial activities in Protein Protein Uptake Nitrates in soil. Nitrogen is also lost in animals in plants by roots the soil through leaching from the soil and carried out of ecoNitrification systems by groundwater flow to streams. Leaching Nitrites Death and Death and also results in export of cardecomposition decomposition bon, phosphorus, and other Nitrifying nutrients out of ecosystems. bacteria Output of nutrients from ecosystems can also occur through surface flow Ammonia of water and soil erosion. 441
Nutrient cycles However, loss of nutrients from one ecosystem may represent input to other ecosystems. Output of organic matter from terrestrial ecosystems constitutes the majority of nutrient input into stream ecosystems. Organic matter can also be transferred between ecosystems by herbivores. For example, moose feeding on aquatic plants can transport nutrients to adjacent terrestrial ecosystems and deposit them in the form of feces. Considerable quantities of nutrients are lost permanently from ecosystems by harvesting, especially in farming and logging lands, when biomass is directly removed from ecosystems. Fire usually results in the loss of large amounts of nutrients. Fire kills vegetation and converts portions of biomass and organic soil matter to ash. Fire causes loss of nutrients through volatilization and airborne particulate. After fire, many nutrients become readily available, and nutrients in ash are subject to rapid mineralization. If not taken up by plants during vegetation recovery, nutrients are likely to be lost from ecosystems through leaching and erosion. The Hubbard Brook Example Nutrient cycling has been studied in several intact ecosystems. One of the most notable experiments was conducted in the Hubbard Brook experimental forest in New Hampshire. The experimental forest was established initially for forest hydrology research. Begun in the early 1960’s, one of the longest-running studies of water and nutrient dynamics of forest ecosystems has been on the Hubbard Brook site. Both water and nutrient concentrations in precipitation inputs and stream outputs were regularly monitored, allowing estimations of nutrient balances over the watershed ecosystems. One of the major findings from the Hubbard Brook study was that undisturbed forests exhibit regularity and predictability in their input-output balances for water and certain chemical elements. Nitrogen, however, shows a more complex, but still explicable, pattern of stream concentrations. Losses of nitrates from the control watershed are higher in the dormant season, when biological activity is low. Losses are near zero during the growing season, when biological demand for nitrogen by plants and microbes are high. Removal of vegetation in the Hubbard Brook forest had a marked effect on water and nutrient balances. Summer stream flow during the devegetation experiment was nearly four times higher than in the control watershed. The increase in stream flow, combined with increases in the concentration of nutrients within the stream, resulted in increases in loss rates of nitrate much higher than those of undisturbed areas. Similarly, loss of potassium used in large quantities by plants showed the greatest increase. 442
Nutrient cycles Nutrient Uptake and Competition Ecosystem nutrient cycling is critical for plant growth and ecosystem productivity. Plant uptake of essential nutrient elements is related to nutrient availability, root absorption surface, rooting depth, and uptake kinetics of roots. A nutrient-rich site usually supports more plants of different species than a site with fewer available nutrients. Nutrient competition among plants is usually manifested through physiological, morphological, and ecological traits. Usually grasses and forbs can coexist in one grassland ecosystem, for example, through different rooting depth. To compete for less soluble nutrients such as phosphorus, plants usually extend their root surfaces using symbiotic relationships with mycorrhizae. Differential seasonality in nutrient uptake and rooting depth become more critical to compete for limited nutrients. Yiqi Luo See also: Balance of nature; Biomass related to energy; Competition; Food chains and webs; Geochemical cycles; Herbivores; Hydrologic cycle; Omnivores; Phytoplankton; Rain forests and the atmosphere; Trophic levels and ecological niches. Sources for Further Study Aber, J. D., and J. M. Melillo. Terrestrial Ecosystems. 2d ed. San Diego: Academic Press, 2001. Likens, G. E., et al. Biogeochemistry of a Forested Ecosystem. New York: Springer-Verlag, 1977. Schlesinger, W. H. Biogeochemistry: An Analysis of Global Change. 2d ed. San Diego: Academic Press, 1997.
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OCEAN POLLUTION AND OIL SPILLS Types of ecology: Aquatic and marine ecology; Ecotoxicology Oil spills resulting from human error often affect marine and coastal areas. Past oil spills in different areas of the world demonstrate that environmental damage depends on the toxicity and the persistence of the oil; both vary widely depending on a variety of factors. Why Oil Spills Occur Almost all imported and Alaskan oil is transported to U.S. refineries and consumers by oceangoing tankers. Most oil spills result from marine transportation accidents, with human error usually playing a major role. Navigation errors, equipment malfunctions, bad judgment, and even the inability of all crew members to speak a common language have all been major contributing factors in the largest and most environmentally damaging oil spills. Not all oil spills are environmental disasters, but spilled oil can decimate plant and animal populations by a combination of mechanical toxicity and chemical toxic effects resulting from an organism’s physiological reaction to the chemicals present in oil. Environmental Damage The most common sight during an oil spill is dark, gelatinous masses of “mousse”—an oil and water emulsion that floats on the water, sticking to everything with which it comes into contact. Mousse usually causes the majority of the environmental damage during an oil spill by the process of mechanical toxicity, as it suffocates and smothers organisms that ingest it or are covered by it. Seabirds and furry marine mammals are highly susceptible to this process, succumbing to exposure, dehydration, or starvation. Crude oil is a complex mixture of thousands of different chemicals called hydrocarbons, named after a molecular structure based on hydrogen and carbon atoms. Different hydrocarbons vary in their chemical properties, toxicity, and behavior during an oil spill. The major groups are classified by molecular geometry and weight. The low-molecular-weight molecules (aliphatics) are single-bonded, chain-shaped molecules, such as gasoline. They are the most chemically reactive and volatile, and they are acutely toxic. These compounds tend to evaporate or burn easily during 444
Ocean pollution and oil spills an oil spill and therefore do not persist in the environment for long periods. Intermediate-molecular-weight hydrocarbons, or aromatics, are ringshaped molecules, such as benzene. They are also highly reactive and cause biological impacts because of both acute and chronic toxicity. Aromatic hydrocarbon compounds are more environmentally persistent than aliphatics. Since many are carcinogens, they can cause different forms of biological damage, disease, and death even after a long time period and in low doses. The high-molecular-weight oil compounds are mostly polycyclic aromatic hydrocarbons structured of ring shapes bonded together to form molecules. Although they are not very chemically reactive and do not dissolve well in water, many are carcinogenic. They tend to be very environmentally persistent. For hundreds of millions of years before humans evolved, oil was “spilled” naturally into the world’s oceans by natural oil seeps—fractures in the earth’s crust that tap deep, oil-bearing rocks. A variety of natural processes act to reduce the environmental impacts of this oil, and these same processes also take place during a human-caused oil spill. Oil is dispersed from the oil slick and into the larger environment by five basic processes. Evaporation of the low-molecular-weight hydrocarbon compounds removes most of the oil relatively quickly. Sunlight can degrade additional oil in a process called photodegradation if the oil is exposed for enough time. Because oil is an organic substance, additional oil is removed by natural biodegradation thanks to “oil-eating” microorganisms. Most of the rest of the oil either washes up onto a coastal area or breaks up into heavy “tar balls” rich in high-molecular-weight hydrocarbons that eventually sink. Some oil spills put so much oil into the environment that these processes cannot respond quickly enough to prevent environmental damage. Other factors can also enhance environmental damage from oil spills. Some types of oil or refined petroleum products are more toxic than others. Oil spills in cold climates generally cause more damage because cold temperatures retard evaporation and the microbial metabolic rates necessary for rapid oil removal. Furthermore, sunlight is often of low intensity, which retards photodegradation. Wave conditions and tidal currents can affect how much oil washes up onto a coastal area and how rapidly it is moved elsewhere or removed. Finally, the amount of environmental damage from an oil spill is highly dependent on the type of coastal environment oiled in the spill, as coastal environments vary in density (or biomass) and varieties of wildlife. Coastlines also vary in the degree to which they are sheltered from natural oil-removal processes. In general, rocky headlands, wave-cut rock platforms, and reefs exposed to high wave activity suffer far less dam445
Ocean pollution and oil spills age during an oil spill than do sheltered marshes, tidal flats, and mangrove forests. The damage on beaches is related to the grain size of the beach sediment. Fine-sand beaches are relatively flat and hard-packed, and oil does not soak into the sediment or persist for long. Oil will soak deeply into coarse sand, gravel, and shell beaches, causing more damage over a longer period. Most of what has been learned about oil spill behavior, environmental damage, and oil spill cleanup techniques comes from studying past spills. In most cases, spill prevention is far cheaper and more effective than spill response, and cleanup efforts usually capture very little of the spilled oil. Ixtoc I The Ixtoc I spill of June 3, 1979, was the result of an explosion, or “blowout,” of an offshore oil well that was drilling into a subsurface oil reservoir. Although human error was definitely a factor, the cause of the blowout remains unresolved. It has been blamed on the use of drilling mud that was not dense enough to counteract the pressure of the oil and gas at depth, as well as on the improper installation of the blowout preventer—a fail-safe device used on drilling rigs to prevent just this type of disaster. The result was a continuous 290-day oil spill, during which an estimated 475,000 metric tons of crude oil (one metric ton equals approximately five barrels) were released into the environment. In addition to doing considerable environmental damage on the coast of Mexico, oil fouled much of the barrier island coast of Texas. However, most of the oil did not make it to shore, and the final accounting for this spill gives a good indication of the long-term fate of spilled oil in offshore areas: 1 percent burned at the spill site, 50 percent evaporated, 13 percent photodegraded or biodegraded, 7 percent washed up on the coast (6 percent in Mexico, 1 percent in Texas), 5 percent was mechanically removed by skimmers and booms, and 24 percent sank to the seafloor (assumed by mass balance). The Exxon Valdez The Exxon Valdez oil spill—which occurred in Prince William Sound, Alaska, on March 24, 1989—is a good example of how environmental damage follows human error and inadequate response. After departing Port Valdez with a full cargo, the Exxon Valdez oil tanker struck a well-charted submerged rock reef located 1.6 kilometers outside the shipping lane. The ship was under the command of an unlicensed third mate in calm seas and left the shipping lane with permission from the Coast Guard to avoid ice. However, it strayed too close to the reef before evasive action was attempted. The captain was under the influence of alcohol during events leading to the 446
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Seabirds are often casualties of ocean oil spills, succumbing to exposure, dehydration, starvation, suffocation, or the oil’s toxicity. In 1989, experts estimated that, in addition to thousands of sea otters and deer, more than half a million seabirds died as a result of the Exxon Valdez oil spill in Prince William Sound, Alaska. (PhotoDisc)
accident. His blood alcohol level nine hours after the grounding was measured at 0.06 percent; the estimate at the time of the accident was 0.19 percent—almost twice the legal level for drivers in California. Convicted of negligence and stripped of his commander’s license, he was subsequently employed as an instructor to teach others to operate supertankers. Leaking oil was observed immediately. Oil-spill response crews funded by Exxon and the Alyeska Pipeline Consortium—oil companies that used the Port Valdez terminal—were poorly prepared and reacted too slowly and with inadequate equipment. The first response arrived ten hours after the accident with insufficient booms and skimmers. Chemical dispersants applied to break up the oil slick were ineffective in the calm seas and caused the oil slick to thin and spread more rapidly. Four days later, the weather changed: 114-kilometer-per-hour winds mixed the oil with seawater, creating a frothy mousse. More than 65,000 metric tons of oil spilled over several weeks. About 15,600 square kilometers of ocean and 1,300 kilometers of shoreline were affected. Federal estimates of wildlife mortality include 3,500 to 5,500 otters; 580,000 seabirds; and 300 deer poisoned by eating oiled kelp. Economic damages totaled more than $5 billion. The long-term effects on commercial 447
Ocean pollution and oil spills marine organisms, larval organisms, and bottom-dwelling life are not known. Exxon promised to clean nearly 500 kilometers of shoreline by September, 1989, but cleaned only 2 kilometers during the first month after the spill. Exxon and its contractors used a variety of cleanup techniques, including placing booms and skimmers, sopping up oil with absorbent materials, scraping oil by hand from rocks, stimulating the growth of oileating bacteria cultures, and washing coastal areas with cold water, hot water, and steam. The use of hot water and steam was effective at cosmetically removing surface oil, but it did not remove oil that had soaked into the sediment; the technique killed most organisms that had escaped the oil. The oil washed from the beach was to be collected by booms and skimmers offshore, but this process was so inefficient that much of the oil migrated to tide pools that had not been affected by the spill directly. Ironically, only eighteen months after the spill, life had returned to oiled coasts that had received little or no cleanup, while beaches cleaned with hot water were still relatively sterile and required several years to repopulate. Exxon announced that it would not return to clean more shoreline in 1990 but relented under threat of a court order from the Coast Guard to enforce federal cleanup requirements. During the summer of 1990, shoreline cleanup resumed, including application of fertilizer to stimulate growth of naturally occurring oil-eating bacteria, a technique that is not very efficient in the cold waters of southern Alaska. The tale of the Exxon Valdez is not complete without mentioning that the Port Valdez Coast Guard did not have state-of-the-art radar equipment for monitoring ship movement in this heavily used and environmentally sensitive area. In the early 1980’s, federal and state funds for monitoring the Port Valdez oil companies’ compliance with oil-spill preparedness legislation had been cut by more than 50 percent. The original environmental impact statement for oil-handling activity in Prince William Sound included an agreement that defines cleanup responsibility for oil spills. Exxon, as the company responsible for the spill, was to pay the first $14 million of cleanup costs, with $86 million in additional cleanup funds from the Alyeska contingency fund. Thus, the maximum financial responsibility to oil companies from a spill was $100 million unless the spill was judged to be caused by negligence. Cleanup activities ceased eighteen months after the spill with total expenditure of $2.2 billion; most of this at taxpayer expense. In 1994, a federal court unanimously awarded $5.3 billion in punitive and compensatory damages, the largest-ever jury award, to some thirty-five thousand people impacted by the spill. By June, 1999, Exxon had yet to pay a single dollar as the case continued through the legal pro448
Ocean pollution and oil spills cess. Finally, it is interesting to note that Exxon’s estimate of cleanup costs in late 1989 were $500 million, and it carried $400 million of oil spill liability insurance. Exxon saved $22 million by not building the Exxon Valdez with a double hull; its 1988 annual profits were $5,300 million. According to National Oceanic and Atmospheric Administration (NOAA) estimates, less than 1 percent of Exxon Valdez’s oil burned at the site, 20 percent evaporated, 8 percent was mechanically removed, and nearly 72 percent was deposited on the seafloor. According to Exxon’s estimates, 7 percent of the oil burned at the site, 32 percent evaporated, 9 percent photodegraded or biodegraded, 15 percent was mechanically removed, and 37 percent was assumed deposited on the seafloor. Operation Desert Storm The February, 1991, Operation Desert Storm oil spill—the largest oil spill in history—occurred when the Iraqi military opened valves and pumps at Sea Island Terminal, a tanker loading dock located 16 kilometers off the coast of Kuwait. This facility has a production capacity of 100,000 barrels per day, about three Exxon Valdez loads each week. The Iraqis also opened plugs on five Kuwaiti tankers, spilling an additional 60,000 barrels. The estimate for the entire spill is 6 million barrels, or roughly 30 times the volume of the Exxon Valdez. About 650 square kilometers of coast were heavily contaminated. Three days after starting the spill, the Iraqis ignited the oil leaking from the terminal. This was the best thing to happen from an environmental perspective. During most spills, more oil is removed by natural evaporation than by any cleanup technique; igniting the oil merely speeds up this process. Burning can be an important mechanism for removing oil from the sea and avoiding environmental damage, and tests have shown purposeful ignition in open water away from the coast to be an excellent oil-slick fighting strategy. However, this must be done within the first few hours of the spill—in order to maintain the fire, the slick must be more than 1 millimeter thick and must contain relatively little emulsified water. To maintain thickness, the slick is best surrounded with fireproof booms. However, at the time of the Operation Desert Storm spill, almost all the fireproof booms in the world were in Prince William Sound. Saudi Arabia also used dispersants on portions of the slick, but this effort was too late to be effective before a thick mousse had formed. The prime objectives of causing the spill were to hamper an amphibious military landing by oiling the beaches and to disrupt desalinization of drinking water at Khafji and Jubail, the two primary sources of potable water for Saudi Arabia. The Saudis used booms to protect the plant intakes with great success. The retreating Iraqis also ignited more than seven hun449
Ocean pollution and oil spills dred of about one thousand inland wells, resulting in an additional 6 million barrels per day burned. This volume eventually made the marine spill insignificant, and the burning created 3 percent of total global carbon emissions during the time period of the event. The Arabian Gulf is an unusual body of water. It is very shallow (average 33 meters) and is nearly enclosed as a marine basin. Because it is also microtidal (the tidal range is less than 0.6 meter), it flushes out slowly (once every two hundred years, compared with once every few days for Prince William Sound). It is also important to remember that this is not a pristine marine environment. Natural oil seeps are very common, there is a general lack of environmental standards and poor cooperation among Persian Gulf nations, and virtually no oil spill preparations or equipment were present in this part of the world. Earlier spills had occurred in the region, but they typically were associated with ongoing wars; the hostile environment made it difficult to utilize spill abatement specialists and equipment. For example, during the Iran-Iraq War, Iraq attacked an Iranian offshore platform (Nowruz) in 1982, spilling more than 2 million barrels of oil, a volume nearly half as large as the Operation Desert Storm spill. Losses of marine mammals and birds were great, and populations had not rebounded by the time of Operation Desert Storm. During the Operation Desert Storm oil spill, about 180 kilometers of Saudi Arabian coastline were oiled (65 kilometers were severely damaged), and oil reached south as far as the United Arab Emirates and Bahrain. Much of the southern Kuwaiti coast (sea-grass beds, marsh, and mangroves) was severely damaged, and about 25 percent of the Saudi shrimp industry was lost. Although some twenty thousand wading birds were killed, no deaths of dolphins or dugongs were reported. However, these animals suffered greatly during the Iran-Iraq War. Estimates of the time required for ecological renewal of the Persian Gulf following the Operation Desert Storm spill (one to four years) were relatively short for two reasons: The high water temperature results in high microbial activity and biodegradation of the oil, and much of the oil was burned. James L. Sadd See also: Acid deposition; Lakes and limnology; Marine biomes; Pollution effects; Reefs. Sources for Further Study Alaska Wilderness League. Preventing the Next Valdez: Ten Years After Exxon’s Spill New Disasters Threaten Alaska’s Environment. Washington, D.C.: Alaska Wilderness League, 1999. 450
Ocean pollution and oil spills Etkin, Dagmar Schmidt. Financial Costs of Oil Spills in the United States. Arlington, Mass.: Cutter Information, 1998. _______. Marine Spills Worldwide. Arlington, Mass.: Cutter Information, 1999. Hall, M. J. Crisis on the Coast. Portland, Oreg.: USCG Marine Safety Office, 1999. Smith, Roland. The Sea Otter Rescue: The Aftermath of an Oil Spill. New York: Puffin Books, 1999.
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OLD-GROWTH FORESTS Types of ecology: Biomes; Ecosystem ecology; Restoration and conservation ecology Ancient ecosystems, old-growth forests consist of trees that have never been harvested. These forests are, in some cases, the only habitat for a number of plant and animal species.
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he timber industry views large, old trees as a renewable source of fine lumber, but environmentalists see them as part of an ancient and unique ecosystem that can never be replaced. In the 1970’s scientists began studying the uncut forests of the Pacific Northwest and the plants and animals that inhabited them. In a U.S. Forest Service publication, Ecological Characteristics of Old-Growth Douglas-Fir Forests (1981), Forest Service biologist Jerry Franklin and his colleagues showed that these forests were not just tangles of dead and dying trees but rather a unique, thriving ecosystem made up of living and dead trees, mammals, insects, and fungi. Old-Growth Forest Ecosystem The forest usually referred to as old growth occurs primarily on the western slope of the Cascade Mountains in southeast Alaska, southern British Columbia, Washington, Oregon, and Northern California. The weather there is wet and mild, ideal for the growth of trees such as Douglas fir, cedar, spruce, and hemlock. Studies have shown that there is more biomass, including living matter and dead trees, per acre in these forests than anywhere else on earth. Trees can be as tall as 300 feet (90 meters) with diameters of 10 feet (3 meters) or more and can live as long as one thousand years. The forest community grows and changes over time, not reaching biological climax until the forest primarily consists of hemlock trees, which are able to sprout in the shade of the sun-loving Douglas fir. One of the most important components of the old-growth forest is the large number of standing dead trees, or snags, and fallen trees, or logs, on the forest floor and in the streams. The fallen trees rot very slowly, often taking more than two hundred years to completely decompose. During this time they are important for water storage, as wildlife habitat, and as “nurse logs” where new growth can begin. In fact, seedlings of some trees, such as western hemlock and Sitka spruce, have difficulty competing with the mosses on the forest floor and need to sprout on the fallen logs. Another strand in the complex web of the forest consists of mycorrhizal 452
Old-growth forests fungi (mycorrhizae), which attach themselves to the roots of the trees and enhance their uptake of water and nutrients. The fruiting bodies of these fungi are eaten by small mammals such as voles, mice, and chipmunks, which then spread the spores of the fungi in their droppings. There are numerous species of plants and animal wildlife that appear to be dependent on this ecosystem to survive. Protecting the Forest By the 1970’s most of the trees on timber industry-owned lands had been cut. Their replanted forests, known as second growth, would not be ready for harvest for several decades, so the industry became increasingly dependent on public lands for their raw materials. Logging of old growth in the national forests of western Oregon and Washington increased from 900 million board feet in 1946 to more than 5 billion board feet in 1986. Environmentalists claimed that only 10 percent of the region’s original forest remained. Determined to save what was left, they encouraged the use of the evocative term “ancient forest” to counteract the somewhat negative connotations of “old growth.” Then they were given an effective tool in the northern spotted owl. This small bird was found to be dependent on
Old-growth forests in the Pacific Northwest are the only habitat for not only the famous endangered northern spotted owl but also a host of other wildlife species. (PhotoDisc) 453
Old-growth forests old growth, and its listing under the federal Endangered Species Act in 1990 caused a decade of scientific, political, and legal conflict. Under law, the U.S. Forest Service was required to protect enough of the owl’s habitat to ensure its survival. An early government report identified 7.7 million acres of forest to be protected for the bird. Later, the U.S. Fish and Wildlife Service recommended 11 million acres. In 1991 U.S. District Court judge William Dwyer placed an injunction on all logging in spotted owl habitat until a comprehensive plan could be finalized. The timber industry responded with a prediction of tens of thousands of lost jobs and regional economic disaster. In 1993 President Bill Clinton convened the Forest Summit conference in Portland, Oregon, to work out a solution. The Clinton administration’s plan, though approved by Judge Dwyer, satisfied neither the industry nor the environmentalists, and protests, lawsuits, and legislative battles continued. As the twentieth century came to an end, timber harvest levels had been significantly reduced, the Northwest’s economy had survived, and additional values for old-growth forests were found: habitat for endangered salmon and other fish, a source for medicinal plants, and a repository for benefits yet to be discovered. The decades-long controversy over the forests of the Northwest had a deep impact on environmental science as well as natural resource policy and encouraged new interest in other native forests around the world, from Brazil to Malaysia to Russia. Joseph W. Hinton See also: Endangered animal species; Forests; Habitats and biomes; Lakes and limnology; Mountain ecosystems; Rain forests; Rain forests and the atmosphere; Savannas and deciduous tropical forests; Slash-and-burn agriculture; Taiga; Tundra and high-altitude biomes. Sources for Further Study Dietrich, William. The Final Forest: The Battle for the Last Great Trees of the Pacific Northwest. New York: Penguin Books, 1993. Durbin, Kathie. Tree Huggers: Victory, Defeat, and Renewal in the Northwest Ancient Forest Campaign. Seattle: Mountaineers, 1996. Kelly, David, and Gary Braasch. Secrets of the Old Growth Forest. Salt Lake City, Utah: Gibbs-Smith, 1988. Maser, Chris. Forest Primeval: The Natural History of an Ancient Forest. Corvallis: Oregon State University Press, 2001.
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OMNIVORES Types of ecology: Behavioral ecology; Ecoenergetics Omnivores are animals that eat both plants and animals. They are found in all types of animals, including arthropods, fish, birds, and mammals. Omnivore diets may vary seasonally.
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any animals are either herbivores, which eat only plant food, or carnivores, which eat only the flesh of other animals. The preference for one type of food or the other depends largely on the type of digestive system that the animal has, and the resources it can put into its “energy budget.” Ecological Advantages Meat is generally easier to digest and requires a less complex digestive system and a relatively short intestinal tract. However, in order to get meat, carnivores have to invest a lot of time hunting their prey, and the outcome of a hunt is always uncertain. The food of herbivores is much easier to obtain, since plants do not move and all the herbivore has to do is graze on the grasses, leaves, or algae readily available around it. However, the cellulose that plants are made of is very tough to digest, and thus herbivores must have a much lengthier and more complex digestive tract than carnivores. Many herbivores are ruminants, with multipart stomachs, which have to chew and digest their food more than once in order to get adequate nutrition from it. Carnivores and herbivores are also vulnerable to a loss of their food source. Herbivores whose digestive systems are specialized to process only one type of food will starve if that food becomes scarce as a result of drought or some other climatic change. Carnivores often have specialized hunting patterns that cannot be changed if the prey (usually herbivores) become scarce due to loss of their own food source. Omnivores maximize their ability to obtain food by having digestive tracts capable of processing both plant and animal food, although they are usually not capable of digesting the very tough plant material, such as grasses and leaves, that many large herbivores eat. Omnivores may also be scavengers, eating whatever carrion they may come across. Omnivores often lack the specialized food-gathering ability characteristic of pure carnivores and herbivores. Many animals often thought of as carnivores are actually omnivores, eating both plants and animals. 455
Omnivores Diversity of Omnivores Omnivores can be found among all types of animals, living on land and in water. They include fish, mollusks, arthropods, birds, and mammals. Most insects are either herbivores, such as grasshoppers, or carnivores such as mantises. However some, such as yellow jacket wasps, are omnivores, eating other insects, fruit, and nectar. Omnivorous snails and slugs eat algae, leaves, lichens, insects, and decaying plant and animal matter. Their main organ for eating is called a radula, a tonguelike, toothed organ that is drawn along rocks, leaves, or plants to scrape off food; it is also used to bore holes through shells of other mollusks, to get to their flesh. Omnivorous fish include the common carp, goldfish, catfish, eels, and minnows. Since a fish’s food is often suspended in the medium through which the fish swims—water—being able to gulp up whatever comes into its mouth is an efficient way for a fish to eat. Similarly, bottom-feeders (fish that suck up material from the floor of whatever body of water they inhabit) also benefit from not needing to sort through the material before they ingest it. Many birds are omnivores, such as robins, ostriches, and flamingos. The pink or red color of flamingos occurs because they eat blue-green algae and higher plants which contain the same substances that make tomatoes red. They also eat shrimp and small mollusks. Mammal omnivores include bears; members of the weasel family, such as skunks; the raccoon family (raccoons and coatimundis); monkeys; apes; and humans. Raccoons and coatis, found only in the Americas, eat insects, crayfish, crabs, fish, amphibians, birds, small mammals, nuts, fruits, roots, and plants. Like other omnivores, they also eat carrion. Bears eat grass, roots, fruits, insects, fish, small or large mammals, and carrion. Sanford S. Singer See also: Balance of nature; Biomass related to energy; Food chains and webs; Herbivores; Nutrient cycles; Predation; Trophic levels and ecological niches. Sources for Further Study Kay, Ian. Introduction to Animal Physiology. New York: Springer-Verlag, 1999. Lauber, Patricia. Who Eats What? New York: HarperTrophy, 1995. Llamas, Andreu. Crustaceans: Armored Omnivores. Milwaukee: Gareth Stevens, 1996. McGinty, Alice B. Omnivores in the Food Chain. Logan, Iowa: Powerkids Press, 2002. 456
OZONE DEPLETION AND OZONE HOLES Types of ecology: Ecotoxicology; Global ecology Ozone occurs naturally in the atmosphere and absorbs ultraviolet radiation from the sun. In the past few decades, a “hole” in the atmosphere’s ozone layer has been recorded over Antarctica, and its size, although fluctuating, has increased over time. Scientists are concerned with the damage to all living organisms from ultraviolet radiation if the atmosphere’s ozone continues to decrease. Ozone in the Atmosphere Ozone, although only a minor component of the atmosphere, plays a vital role in the survival of life on earth. Ozone molecules absorb high-energy ultraviolet (UV) radiation, which humans perceive as light, from the sun. Absorption of ultraviolet radiation in the ozone layer, a region of the stratosphere that contains the maximum concentration of ozone, prevents most such light from reaching the surface of the planet. If none of the sun’s ultraviolet radiation were blocked by the ozone layer, it would be difficult for most forms of life, including humans, to survive on land. The concentration of ozone in the atmosphere is highly variable, changing with altitude, geographic location, time of day, time of year, and prevailing local atmospheric conditions. Long-term fluctuations in ozone concentration are also seen, some of which are related to the solar sunspot cycle. While long-term average ozone concentrations are relatively stable, short-term fluctuations of as much as 10 percent in total column abundance of ozone as a result of the natural variability in ozone concentration are often observed. Discovery of a “Hole” Beginning in the early 1970’s, a new and unexpected decrease in stratospheric ozone concentration was first observed. The decrease was localized in geography to the Southern Polar region, and in time to early spring (which begins in October in the Southern Hemisphere). The initial decrease in ozone was small, but by 1980, decreases in total column abundance of ozone of as much as 30 percent were being seen, well outside the range of variation expected as a result of random fluctuations. This seasonal destruction of stratospheric ozone above Antarctica, which by 1990 had reached 50 percent of the total column abundance of ozone, was soon given the label “ozone hole.” 457
Ozone depletion and ozone holes
Average Size of the Ozone Hole, 1980-2000 30
Size (million square kilometers)
25
Area of North America
20
15
Area of Antarctica
10
5
Ozone values < 220 Dobson units Average area - 30 day maximum Vertical lines = minimum & maximum area
0 1980
1985
1990 Year
1995
2000
Source: Goddard Space Flight Center. National Aeronautics and Space Administration. http:\\toms.gsfc.nasa.gov\multi\oz_hole_area.jpg; accessed April 15, 2002.
The Role of CFCs While it was initially unclear whether formation of the Antarctic ozone hole stemmed from natural causes or from anthropogenic effects on the environment, extensive field studies combined with the results of laboratory experiments and computer modeling of the atmosphere quickly led to a consistent and detailed explanation for ozone-hole formation. The formation of the ozone hole has two principal causes: chemical reactions that occur generally throughout the stratosphere, and special conditions that exist in the Antarctic region. Under normal conditions, the concentration of ozone in the stratosphere is determined by a balance between reactions that remove ozone and those that produce ozone. The removal reactions are mainly catalytic chain reactions, in which trace atmospheric chemical species destroy ozone molecules without themselves being consumed. In such processes, it is possible for one chain carrier to remove many ozone molecules before being itself removed. The trace species involved in ozone removal include hydrogen oxides and nitrogen oxides, formed primarily by naturally oc458
Ozone depletion and ozone holes curring processes, and chlorine and bromine atoms and their corresponding oxides. A major source of chlorine in the stratosphere is the decomposition of a class of compounds called chlorofluorocarbons (CFCs). Such compounds can be used in refrigeration and air conditioning, as aerosol propellants, and as solvents. Chlorofluorocarbons are extremely stable in the lower atmosphere, with lifetimes of several decades. The main fate of chlorofluorocarbons is slow migration into the stratosphere, where they absorb ultraviolet light and release chlorine atoms. The chlorine atoms produced from the breakdown of chlorofluorocarbons in the stratosphere provide an additional catalytic process by which stratospheric ozone can be destroyed. A similar set of reactions involving a class of bromine-containing compounds called halons, used in some types of fire extinguishers, leads to additional ozone destruction. By 1986, the average global loss of stratospheric ozone caused by the release of chlorofluorocarbons, halons, and related compounds into the environment was estimated to be 2 percent. The Antarctic Stratosphere While the decomposition and subsequent reaction of chlorofluorocarbons and other synthetic compounds explains the small general decline in ozone concentration observed in the stratosphere, additional processes are needed to account for the more massive seasonal ozone depletion observed above Antarctica. These processes involve a set of special conditions that in combination are unique to the stratosphere above Antarctica. During daylight hours, a portion of the chlorine present in the stratosphere is tied up in the form of reservoir species, compounds such as hydrogen chloride and chlorine nitrate that do not react with ozone. This slows the rate of removal of ozone by chlorine. Processes that directly or indirectly involve absorption of sunlight transform reservoir species into ozone-destroying chlorine atoms. During the Antarctic winter, when sunlight is entirely absent, stratospheric chlorine is rapidly converted into reservoir species. In the absence of additional chemical processes, the onset of spring in Antarctica and the return of sunlight would convert a portion of the reservoir compounds into reactive chlorine species and reestablish the balance between ozone-producing and ozone-destroying processes. However, the extremely low temperatures occurring in the stratosphere above Antarctica during the winter months leads to the formation of polar stratospheric clouds, which, because of the extremely low concentration of water vapor in the stratosphere, do not form during other seasons or outside the polar regions of the globe. The ice crystals that compose the clouds act as cata459
Ozone depletion and ozone holes lysts that convert reservoir species into diatomic chlorine and other gaseous chlorine compounds that, in the presence of sunlight, re-form ozonedestroying species. At the same time, the nitrogen oxides found in the reservoir species are converted into nitric acid, which remains attached to the ice crystals. As these ice crystals are slowly removed from the stratosphere by gravity, the potential for conversion of active forms of chlorine into reservoir species is greatly reduced. Because of this, when spring arrives, large amounts of ozone-destroying chlorine species are produced by the action of sunlight, and only a small fraction of this reactive chlorine is converted into reservoir species. The increased rate of ozone removal caused by the abundance of reactive chlorine present in the stratosphere leads to ozone depletion and formation of the ozone hole. An additional process important in formation of the ozone hole is the unique air-circulation pattern in the stratosphere above Antarctica. During the winter and early spring, a vortex of winds circulates about the South Pole. This polar vortex minimizes movement of ozone and reservoir-forming compounds from other regions of the stratosphere. As this polar vortex breaks up in midspring, ozone concentrations in the Antarctic stratosphere return to normal levels, and the ozone hole gradually disappears. Study and Interpretation Researchers utilize a great diversity of devices and techniques in their study and interpretation of atmospheric ozone. One popular technique is the use of models. A good model is one that simulates the interrelationships and interactions of the various parts of the known system. The weakness of models is that, often, not enough is known to give an accurate picture of the total system or to make accurate predictions. Most modeling is done on computers. Scientists estimate how fast chemicals such as CFCs and nitrous oxide will be produced in the future and build a computer model of the way these chemicals react with ozone and with one another. From this model, it is possible to estimate future ozone levels at different altitudes and at different future dates. Arctic Depletion? Similar processes appear to be at work in the Arctic stratosphere, leading to ozone depletion, as in the Antarctic; however, the National Oceanic and Atmospheric Administration (NOAA) Aeronomy Laboratory in Boulder, Colorado, reported a discrepancy between observed ozone depletion and predicted levels, based on models that account accurately for the Antarctic depletions. This report suggests that some other mechanism is at work in the Arctic. Thus, good models can be very useful in studying new data. 460
Ozone depletion and ozone holes There are two models favored by most scientists in this area. Some scientists put forth a chemical model that says the depletion is caused by chemical events promoted by the presence of chlorofluorocarbons created by industrial processes. Acceptance of this model was promoted by the discovery of fluorine in the stratosphere. Fluorine does not naturally occur there, but it is related to CFCs. The other model assumes that the ozone hole was formed by dynamic air movement and mixing. This model best fits data gathered by ozone-sensing balloons that sample altitudes up to 30 kilometers and then radio the data back to Earth. Ozone depletion is confined to air between 12 and 20 kilometers. While the total ozone depletion is 35 percent, different strata showed various amounts of depletion from 70 to 90 percent. Surprisingly, about half the ozone was gone in twenty-five days. This finding does not fit the chemical model very well. Besides ozone-sensing balloons, satellites are of much help. The National Aeronautics and Space Administration (NASA) obtains measurements with its Nimbus 7 satellite. Ozone measurements made by this satellite helped to develop flight plans for the specialized aircraft NASA also deploys in ozone studies. NASA’s ER-2 aircraft is a modified U-2 reconnaissance plane that carries instruments up to 20 kilometers in altitude for seven-hour flights to 80 degrees north latitude. A DC-8, operating during the same period, is able to survey the polar vortex, owing to its greater range. In addition, scientists utilize many meteorological techniques and instruments, including chemical analysis of gases by means of infrared spectroscopy, mass spectroscopy and gas spectroscopy combined, gas chromatography, and oceanographic analysis of planktonic life in the southern Atlantic, Pacific, and Indian oceans. As new research methods become available, they are applied to this essential study. Public Health Concerns Atmospheric ozone provides a gauze of protection from the lethal effects of ultraviolet radiation from the sun. This ability to absorb ultraviolet radiation protects all life-forms on the earth’s surface from excessive ultraviolet radiation, which destroys the life of plant and animal cells. Currently, between 10 and 30 percent of the sun’s ultraviolet B (UV-B) radiation reaches the earth’s surface. If ozone levels were to drop by 10 percent, the amount of UV-B radiation reaching Earth would increase by 20 percent. Present-day UV-B levels are responsible for the fading of paints and the yellowing of window glazing and for car finishes becoming chalky. These kinds of degradation will accelerate as the ozone layer is depleted. There could also be increased smog, urban air pollution, and a worsening of the problem of acid rain in cities. In humans, UV-B causes sunburn, snow 461
Ozone depletion and ozone holes blindness, skin cancer, cataracts, and excessive aging and wrinkling of skin. Skin cancer is the most common form of cancer—more than 400,000 new cases are reported every year in the United States alone. The National Academy of Sciences has estimated that each 1 percent decline in ozone would increase the incidence of skin cancer by 2 percent. Therefore, a 3 percent depletion in ozone would produce some 20,000 more cases of skin cancer in the United States every year. Ecological Concerns Many other forms of life—from bacteria to forests and crops—are adversely affected by excessive radiation as well. Ultraviolet radiation affects plant growth by slowing photosynthesis and by delaying germination in many plants, including trees and crops. Scientists have a great concern for the organisms that live in the ocean and the effect ozone depletion may have on them. Phytoplankton, zooplankton, and krill (a shrimplike crustacean) could be greatly depleted if there were a drastic increase in ultraviolet A and B. The result would be a tremendous drop in the population of these free-floating organisms. These organisms are important because they are the beginning of the food chain. Phytoplankton use the energy of sunlight to convert inorganic compounds, such as phosphates, nitrates, and silicates, into organic plant matter. This process provides food for the next step in the food chain, the herbivorous zooplankton and krill. They, in turn, become the food for the next higher level of animals in the food chain. Initial studies of this food chain in the Antarctic suggest that elevated levels of ultraviolet radiation impair photosynthetic activity. Recent studies show that a fifteen-day exposure to UV-B levels 20 percent higher than normal can kill off all anchovy larvae down to a depth of 10 meters. There is also concern that ozone depletion may alter the food chain and even cause changes in the organism’s genetic makeup. An increase in the ultraviolet radiation is likely to lower fish catches and upset marine ecology, which has already suffered damage from human-made pollution. On a worldwide basis, fish presently provides 18 percent of all the animal protein consumed. International Response The United Nations Environmental Program (UNEP) is working with governments, international organizations, and industry to develop a framework within which the international community can make decisions to minimize atmospheric changes and the effects they could have on the earth. In 1977, UNEP convened a meeting of experts to draft the World Plan of Action on the Ozone Layer. The plan called for a program of re462
Ozone depletion and ozone holes search on the ozone layer and on what would happen if the layer were damaged. In addition, UNEP created a group of experts and government representatives who framed the Convention for the Protection of the Ozone Layer. This convention was adopted in Vienna in March, 1985, by twenty-one states and the European Economic Community and has subsequently been signed by many more states. The convention pledges states that sign to protect human health and the environment from the effects of ozone depletion. Action has already been taken to protect the ozone layer. Several countries have restricted the use of CFCs or the amounts produced. The United States banned the use of CFCs in aerosols in 1978. Some countries, such as Belgium and the Nordic countries, in effect banned CFC production altogether. George K. Attwood and Jeffrey A. Joens See also: Acid deposition; Deforestation; Global warming; Greenhouse effect; Pollution effects; Rain forests and the atmosphere. Sources for Further Study Bast, Joseph L., Peter J. Hill, and Richard C. Rue. Eco-Sanity: A Common Sense Guide to Environmentalism. Lanham, Md.: Heartland Institute, 1994. Cagin, Seth, and Philip Dray. Between Earth and Sky: How CFCs Changed Our World and Endangered the Ozone Layer. New York: Pantheon Books, 1993. Firor, John. The Changing Atmosphere: A Global Challenge. New Haven, Conn.: Yale University Press, 1990. Fisher, David E. Fire and Ice: The Greenhouse Effect, Ozone Depletion, and Nuclear Winter. New York: Harper & Row, 1990. Graedel, T. E., and Paul J. Crutzen. Atmospheric Change: An Earth System Perspective. New York: W. H. Freeman, 1993. Roan, Susan. Ozone Crisis: The Fifteen-Year Evolution of a Sudden Global Emergency. New York: John Wiley & Sons, 1989. Rowland, F. Sherwood. “Stratospheric Ozone Depletion.” Annual Review of Physical Chemistry 42 (1991): 731. Shell, E. R. “Weather Versus Chemicals.” The Atlantic 259 (May, 1987): 2731. Somerville, Richard C. J. The Forgiving Air: Understanding Environmental Change. Los Angeles: University of California Press, 1996.
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PALEOECOLOGY Types of ecology: Evolutionary ecology; Paleoecology Paleoecology is the study of ancient organisms and their relationships to one another and to their environments. The characteristics of ancient environments may be determined by examining rock and fossil features.
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s a field of science, paleoecology is most closely related to paleontology, the study of fossils. It is also related to paleoclimatology, paleogeography, and a number of other areas of study dealing with the distant past. All these disciplines have a handicap in common: Because they deal with the past, scientists are unable to apply the usual scientific criteria of direct observation and measurement of phenomena. Therefore, they look to a number of different methods whereby evidence of past conditions and organisms can be deduced. Dendrochronology One of the most intensively investigated paleoecological problems has been the changing environments associated with the ice ages of the past million years. Analysis of pollen from bogs in many parts of the world indicates that there have been at least four advances and retreats of glaciers during that period. Evidence for this is the changing proportions of pollen from tree species found at the various depths of bogs. In North America, for example, spruces (indicators of cool climate) formerly lived much farther south than they do now. They were largely replaced almost eight thousand years ago by other tree species, such as oaks, which are indicative of warmer climates. This warming trend was a result of the latest glacial retreat. Tree-ring analysis, also known as dendrochronology, not only enables paleoecologists to date past events such as forest fires and droughts but also allows them to study longer-term cycles of weather and climate, especially those of precipitation and temperature. In addition, trees serve as accumulators of past mineral levels in the atmosphere and soil. Lead levels of tree wood showed a sharp increase as the automobile became common in the first half of the twentieth century because of lead additives in gasoline. Tree rings formed since the 1970’s have shown a decrease in lead because of the decline in use of leaded fuels. Tree-ring analysis has also been a valuable tool for archaeologists’ study of climatic changes responsible for shifting patterns of population and agriculture among native Americans of the southwestern United States. 464
Paleoecology The Fossil Record Fossil evidence is the chief source of paleoecological information. A fossil bed of intact clam shells with both valves (halves) present in most individuals, for example, usually indicates that the clams were preserved in the site in which they lived (called autochthonous deposition). Had they been transported by currents or tides to another site of deposition (allochthonous deposition), the valves would have been separated, broken, and worn. Similarly, many coal beds have yielded plant fossils that indicate that their ancient environments were low-lying swamp forests with sluggish drainage periodically flooded by water carrying a heavy load of sand. The resulting fossils may include buried tree stumps and trunks with roots still embedded in their original substrate and numerous fragments of twigs, leaves, and bark within the sediment. Certain dome- or mushroom-shaped structures called stromatolites are found in some of the most ancient of earth’s sedimentary rocks. These structures may be several meters in diameter and consist of layers of material trapped by blue-green algae (cyanobacteria). Such structures are currently being formed in shallow, warm waters. Uniformitarian interpretation of the three-billion-year-old stromatolites is that they were formed under similar conditions. Their frequent association with mud cracks and other shallow- and above-water features leads to the interpretation that they were formed in shallow inshore environments subject to frequent exposure to the air. Relative oceanic temperature can be estimated by observing the direction in which the shells of certain planktonic organisms coil. The shell of Globigerina pachyderma coils to the left in cool water and to the right in warmer water. Globigerina menardii shells coil in an opposite fashion—to the right in cool water and to the left in warmer water. Uniformitarian theory leads one to believe that ancient Globigerina populations responded to water temperature in a similar manner. Sea-bottom core samples showing fossils with left- or right-coiling shells may be used to determine the relative water temperature at certain periods. Eighteen-thousand-year-old sediments taken from the Atlantic Ocean show a high frequency of lefthanded pachyderma and right-handed menardii shells. Such observations indicate that colder water was much farther south about eighteen thousand years ago, a date that corresponds to the maximum development of the last Ice Age. Fossil Deposition Fossil arrangement and position can be a clue to the environments in which the organisms lived or in which they were preserved. Sea-floor cur465
Paleoecology rents can align objects such as small fish and shells. Not only can the existence of the current be inferred, but also its direction and velocity can be determined. Currents and tides can create other features in sediments which are sometimes indicators of environment. If a mixture of gravel, sand, silt, and clay is being transported by a moving body of water such as a stream, tide, or current, the sediments will often become sorted by the current and be deposited as conglomerates—sandstones, siltstones, and shales. Such graded bedding can be used to determine the direction and velocity of currents. Larger particles, such as gravel, would tend to be deposited nearer the sediment source than smaller particles such as clay. Similarly, preserved ripple marks indicate current direction. Mud cracks in a rock layer indicate that the original muddy sediment was exposed to the atmosphere at least for a time after its deposition. Fossil Composition Certain minerals within fossil beds or within the fossil remains themselves can sometimes be used to interpret the paleoenvironment. The presence of pyrite in a sediment almost always indicates that the sedimentary environment was deficient in oxygen, and this, in turn, often indicates deep, still water. Such conditions exist today in the Black Sea and even in some deep lakes, with great accumulations of dead organic matter. The method of preservation of the remains of the fossilized organism can be an indication of the environment in which the creature lived (or died). Amber, a fossilized resin, frequently contains the embedded bodies of ancient insects trapped in the resin like flies on flypaper. This ancient environment probably contained resin-bearing plants (mostly conifers), and broken limbs and stumps that oozed resin to trap these insects. Mummified remains in desert areas and frozen carcasses in the northern tundra indicate the environments in which the remains were preserved thousands of years ago. Marks made on fossil parts by other organisms offer indirect evidence of the presence and activity of other species that might not have left fossil remains. Predators and scavengers can leave such marks on bones and shells by boring, scratching, and gnawing. One of the most controversial taphonomic problems in paleoecology is distinguishing between tooth marks left by animal scavengers and predators on bones and those marks left by the stone and bone tools of early human ancestors. Fossil Assemblages and Trace Fossils Fossil assemblages (thanatocoenoses) are the most commonly used indicators of ancient environments. The use of any fossil in interpreting the past 466
Paleoecology must be subject to several qualifications. The fossil record is sparse for most groups of organisms because fossilization itself is a relatively rare event. Rapid burial of the remains and the presence of hard body parts (wood, shells, bones, and teeth) are only two of several fossilization prerequisites that must usually be met. This means that terrestrial organisms and soft-bodied organisms are seldom fossilized. Events leading to fossilization after the death of an organism (taphonomy) usually destroy the soft tissues through decay and scavenging and often disrupt and distort the remaining hard parts through transportation and weathering. An additional taphonomic problem is encountered when clumps or clusters of fossil remains are located. Without careful study, it is difficult to determine whether these assemblages are truly representative of the groupings of the organisms in life or if they are simply coincidental aggregations of such items as shells and limbs that were swept together by currents or wind and thus not indicative of the living situation and environment. Because of limitations on the interpretation of ancient environments by the use of fossilized body parts, trace fossils are often more reliable indicators of environmental conditions. Trace fossils are preserved tracks, burrows, trails, and other indirect indications of the presence of an organism. The presence of marine worm burrows, for example, can indicate environmental factors such as salinity and depth. Such traces are not transported from one site to another. Transportation results in their destruction. Whenever these imprints are found, therefore, paleoecologists are able to make some inferences about the environment in which they were formed. Stratigraphy One of the most important methods to be mastered by paleoecologists is stratigraphy, the science of correlating and determining the age of rock layers with those of the fossils contained within these layers or formations. Rock layers or strata are not usually connected over large regions. While they might have been deposited as sediments at the same time and under the same conditions, subsequent erosion has usually made the layers discontinuous. Stratigraphers attempt to correlate discontinuous rock strata by measuring and describing them and by noting the presence of unique fossils called index fossils. If two strata are correlated, then they were probably deposited during approximately the same period, although there may be a gradation of conditions. For example, there may be a layer of sediment deposited at the same time, but under nearshore conditions at one spot and under offshore conditions at another. Relative ages are determined by using the law of superposition: Older rocks lie beneath younger rocks. One can say that a certain 467
Paleoecology stratum is older than, the same age as, or younger than another layer, depending upon their relative positions. Absolute ages (estimated age in years before the present) are determined by measuring the amounts of certain radioactive elements within igneous rocks. Such radiometric age determinations are of less value for sedimentary rocks since they give the age of the minerals of the rock, not the age of the rock itself. Related Fields Paleoecological data are applicable to other, related paleo-fields of the earth and life sciences. The study of fossils, paleontology, is enhanced by the inclusion of information about the fossil organisms’ environments and relationships with other organisms. Paleontologists should attempt to reconstruct ancient environments because organisms did not exist alone or in vacuums: They lived in dynamic biological communities. Paleogeography relies heavily on paleoecological information to discern the locations, directions, and time intervals of glaciation, deposition of sediments, temperature, and other environmental variables. This information has been used to determine the past positions of continents and has been a valuable contribution to scientists’ knowledge of continental drift. Paleoclimatologists, who study ancient regional and planetwide conditions, must make use of local bits of paleoecological information to see the big picture of climate. One of the major concerns of paleoclimatology is the recognition of planetary climatic cycles and associated environmental and biological cycles. If there is a repeated recurrence of global environmental change, then predictions about future climatic change become more accurate and probable. P. E. Bostick See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Evolution: definition and theories; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Natural selection; Nonrandom mating, genetic drift, and mutation; Punctuated equilibrium vs. gradualism; Speciation; Species loss. Sources for Further Study Agashe, Shripad N. Paleobotany: Plants of the Past, Their Evolution, Paleoenvironment, and Application in Exploration of Fossil Fuels. Enfield, N.H.: Science Publishers, 1997. Arduini, Paolo, and Giorgio Teruzzi. Simon and Schuster’s Guide to Fossils. New York: Simon & Schuster, 1986. 468
Paleoecology Bennett, K. D. Evolution and Ecology: The Pace of Life. New York: Cambridge University Press, 1997. Brett, Carlton E., and Gordon C. Baird, eds. Paleontological Events: Stratigraphic, Ecological, and Evolutionary Implications. New York: Columbia University Press, 1997. Cowen, Richard. History of Life. 3d ed. Malden, Md.: Blackwell Science, 2000. Davis, Richard A. Depositional Systems: A Genetic Approach to Sedimentary Geology. Englewood Cliffs, N.J.: Prentice-Hall, 1983. Dodd, J. Robert, and Robert J. Stanton, Jr. Paleoecology: Concepts and Applications. 2d ed. New York: John Wiley & Sons, 1990. National Research Council. Commission on Geosciences, Environment, and Resources. Board on Earth Sciences and Resources. Effects of Past Global Change on Life. Washington, D.C.: National Academy Press, 1995. Newton, Cathryn, and Léo Laporte. Ancient Environments. 3d ed. Englewood Cliffs, N.J.: Prentice-Hall, 1989. Shipman, Pat. Life History of a Fossil: An Introduction to Taphonomy and Paleoecology. Cambridge, Mass.: Harvard University Press, 1993.
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PESTICIDES Types of ecology: Agricultural ecology; Ecotoxicology Pesticides are substances designed to kill unwanted plants, fungi, or animals that interfere, directly or indirectly, with human activities. The unintended impacts of pesticides such as DDT have been to change ecosystems and their components.
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he major types of pesticides in common use are insecticides (to kill insects), nematocides (to kill nematodes), fungicides (to kill fungi), herbicides (to kill weeds), and rodenticides (to kill rodents). Herbicides and insecticides make up the majority of the pesticides applied in the environment. Biopesticides are beneficial microbes, fungi, insects, or animals that kill pests. While the use of pesticides has mushroomed since the introduction of monoculture (the agricultural practice of growing only one crop on a large amount of acreage), the application of toxins to control pests is by no means new. Insecticides: History of Use The use of sulfur as an insecticide dates back before 500 b.c.e. Salts from heavy metals such as arsenic, lead, and mercury were used as insecticides from the fifteenth century until the early part of the twentieth century, and residues of these toxic compounds are still being accumulated in plants that are grown in soil where these materials were used. In the seventeenth and eighteenth centuries, natural plant extracts, such as nicotine sulfate from tobacco leaves and rotenone from tropical legumes, were used as insecticides. Other natural products, such as pyrethrum from the chrysanthemum flower, garlic oil, lemon oil, and red pepper, have long been used to control insects. In 1939 the discovery of dichloro-diphenyl-trichlorethane (DDT) as a strong insecticide opened the door for the synthesis of a wide array of synthetic organic compounds to be used as pesticides. Chlorinated hydrocarbons such as DDT were the first group of synthetic pesticides. Other commonly used chlorinated hydrocarbons have in the past included aldrin, endrin, lindane, chlordane, and mirex. Because of their low biodegradability and persistence in the environment, they proliferated up the food chain and became concentrated in predators, such as birds and animals butchered for human consumption. The use of these compounds was therefore banned or severely restricted in the United States, but only after years of use. 470
Pesticides Organophosphates such as malathion, parathion, and methamidophos have replaced the chlorinated hydrocarbons. These compounds biodegrade in a fairly short time but are generally much more toxic to humans and other animals than the compounds they replaced. In addition, they are water-soluble and therefore more likely to contaminate water supplies. Carbamates such as carbaryl, maneb, and aldicarb have also been used in place of chlorinated hydrocarbons. These compounds rapidly biodegrade and are less toxic to humans than organophosphates, but they are less effective in killing insects. Herbicides Herbicides are classified according to their method of killing rather than their chemical composition. As their name suggests, contact herbicides such as atrazine and paraquat kill when they come in contact with a plant’s leaf surface. Contact herbicides generally disrupt the photosynthetic mechanism. Systemic herbicides such as diuron and fenuron circulate throughout the plant after being absorbed. They generally mimic the plant hormones and cause abnormal growth to the extent that the plant can no longer supply sufficient nutrients to support growth. Soil sterilants such as triflurain, diphenamid, and daiapon kill microorganisms necessary for plant growth and also act as systemic herbicides.
The spraying of herbicides and pesticides remains a standard agricultural practice in the cultivation of both food crops and ornamental crops such as these tulips. (PhotoDisc) 471
Pesticides Current Use In the United States, approximately 55,000 different pesticide formulations are available, and Americans apply about 500 million kilograms (1.1 billion pounds) of pesticides each year. Fungicides account for 12 percent of all pesticides used by farmers, insecticides account for 19 percent, and herbicides account for 69 percent. These pesticides have been used primarily on four crops: soybeans, wheat, cotton, and corn. Approximately $5 billion is spent each year on pesticides in the United States, and about 20 percent of this is for nonfarm use. On a per-unit-of-land basis, homeowners apply approximately five times as much pesticide as do farmers. On a worldwide basis, approximately 2.5 tons (2,270 kilograms) of pesticides are applied each year. Most of these chemicals are applied in developed countries, but the amount of pesticide used in developing countries is rapidly increasing. Approximately $20 billion is spent worldwide each year, and this expenditure is expected to increase in the future, particularly in the developing countries. Despite current concerns about their toxicity and biomagnification, pesticide use has had a beneficial impact on the lives of humans by increasing food production and reducing food costs. Even with pesticides, pests reduce the world’s potential food supply by as much as 55 percent. Without pesticides, this loss would be much higher, resulting in increased starvation and higher food costs. Pesticides also increase the profit margin for farmers. It has been estimated that for every dollar spent on pesticides, farmers experience an increase in yield worth three to five dollars. Pesticides appear to work better and faster than alternative methods of controlling pests. These chemicals can rapidly control most pests, are cost-effective, can be easily shipped and applied, and have a long shelf life compared to alternative methods. In addition, farmers can quickly switch to another pesticide if genetic resistance to a given pesticide develops. Perhaps the most compelling argument for the use of pesticides is the fact that pesticides have saved lives. It has been suggested that since the introduction of DDT, the use of pesticides has prevented approximately seven million premature human deaths from insect-transmitted diseases such as sleeping sickness, bubonic plague, typhus, and malaria. Perhaps even more lives have been saved from starvation because of the increased food production resulting from the use of pesticides. It has been argued, therefore, that this one benefit outweighs the potential health risks of pesticides. In addition, new pesticides are continually being developed, and safer and more effective pest control may be available in the future. 472
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The publication of Rachel Carson’s classic Silent Spring (1962), which outlined the ecotoxicity of the pesticide DDT, helped stimulate the environmental movement of the 1960’s. (Library of Congress)
Environmental Concerns In spite of all the advantages of using pesticides, their benefit must be balanced against the potential environmental damage they can cause. An ideal pesticide would have the following characteristics: It should not kill any organism other than the target pest; it would in no way affect the health of nontarget organisms; it would degrade into nontoxic chemicals in a relatively short time; it would prevent the development of resistance in the organism it is designed to kill; and it would be cost-effective. Since no currently available pesticide meets all of these criteria, a number of environmental problems have developed, one of which is broad-spectrum poisoning. Most, if not all, chemical pesticides are not selective; they kill a wide range of organisms rather than just the target pest. Killing beneficial insects, such as bees, lady bird beetles, and wasps, may result in a range of problems. For example, reduced pollination and explosions in the populations of unaffected insects can occur. When DDT was first used as an insecticide, many people believed that it was the final solution for controlling many insect pests. Initially, DDT dramatically reduced the number of problem insects; within a few years, however, a number of species had developed genetic resistance to the chemical and could no longer be controlled with it. By the 1990’s there were approximately two hundred insect species with genetic resistance to DDT. Other chemicals were designed to replace DDT, but many insects also developed resistance to these newer insecticides. As a result, although many synthetic 473
Pesticides chemicals have been introduced to the environment, the pest problem is still as great as it ever was. Depending on the type of chemical used, pesticides remain in the environment for varying lengths of time. Chlorinated hydrocarbons, for example, can persist in the environment for up to fifteen years. From an economic standpoint, this can be beneficial because the pesticide has to be applied less frequently, but from an environmental standpoint, it is detrimental. In addition, when many pesticides are degraded, their breakdown products, which may also persist in the environment for long periods of time, can be toxic to other organisms. Pesticides may concentrate as they move up the food chain, a process called biomagnification. All organisms are integral components of at least one food pyramid. While a given pesticide may not be toxic to species at the base, it may have detrimental effects on organisms that feed at the apex because the concentration increases at each higher level of the pyramid. With DDT, for example, some birds can be sprayed with the chemical without any apparent effect, but if these same birds eat fish that have eaten insects that contain DDT, they lose the ability to metabolize calcium properly. As a result, they lay soft-shelled eggs, which causes deaths of most of the offspring. Pesticides can be hazardous to human health. Many pesticides, particularly insecticides, are toxic to humans, and thousands of people have been killed by direct exposure to high concentrations of these chemicals. Many of these deaths have been children who were accidentally exposed to toxic pesticides because of careless packaging or storage. Numerous agricultural laborers, particularly in developing countries where there are no stringent guidelines for handling pesticides, have also been killed as a result of direct exposure to these chemicals. Workers in pesticide factories are also a high-risk group, and many of them have been poisoned through jobrelated contact with the chemicals. Pesticides have been suspected of causing long-term health problems such as cancer. Some of the pesticides have been shown to cause cancer in laboratory animals, but there is currently no direct evidence to show a cause-and-effect relationship between pesticides and cancer in humans. D. R. Gossett See also: Biomagnification; Biopesticides; Genetically modified foods; Integrated pest management; Soil contamination. Sources for Further Study Altieri, Miguel A. Agroecology: The Science of Sustainable Agriculture. 2d ed. Boulder, Colo.: Westview Press, 1995. 474
Pesticides Carson, Rachel. Silent Spring. 1962. Reprint. Thorndike, Maine: G. K. Hall, 1997. Mannion, Antionette M., and Sophia R. Bowlby. Environmental Issues in the 1990’s. Chichester, N.Y.: John Wiley & Sons, 1992. Milne, George W. A., ed. Ashgate Handbook of Pesticides and Agricultural Chemicals. Burlington, Vt.: Ashgate, 2000. Nadakavukaren, Anne. Man and Environment: A Health Perspective. 2d ed. Prospect Heights, Ill.: Waveland Press, 1990. Pierce, Christine, and Donald VanDeVeer. People, Penguins, and Plastic Trees. 2d ed. Belmont, Calif.: Wadsworth, 1995.
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PHEROMONES Types of ecology: Behavioral ecology; Chemical ecology; Physiological ecology Pheromones are chemicals or mixtures of chemicals that are used as messages between members of a species. They are integral parts of the social communication within most species. They may prove to be of great value in pest control and in enhancing agricultural production.
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heromones are chemical signals. Originally defined to include only signals between individuals of the same animal species, the term has been generalized to designate any chemical or chemical mixture that, when released by one member of any species, affects the physiology or behavior of another member of the same species. “Pheromone” is also one of a set of terms developed to express the chemical interactions in ecological communities. All pheromones are semiochemicals that carry information between members of a single species. To do so, the pheromone must be released into the atmosphere or placed on some structure in the organism’s environment. It is thus made available to other members of the species for interpretation and response. It is also available to members of other species, however, so it is a potential allelochemical. Types of Pheromones There are two general types of pheromone: those that elicit an immediate and predictable behavioral response, called releaser or signal pheromones, and those that bring about a less obvious physiological response, called primer pheromones (because they prime the system for a possible behavioral response). Pheromones are also categorized according to the messages they carry. There are trail, marker, aggregation, attractant, repellant, arrestant, deterrent, stimulant, alarm, and other pheromones. Their functions are suggested by the terms used to name them. To appreciate fully the complexity of the interactions under consideration, it is important to remember that a pheromone may also be acting as a kairomone, allomone, or hormone. For example, klipspringer antelope mark vegetation in their environment with a chemical secreted from a special gland. Other klipspringer investigate the marks to gather information on the marking individual. Ticks that parasitize the klipspringer, however, are also attracted to the chemical marks and thus increase their chance of 476
Pheromones attaching to a host when the mark is renewed or when another klipspringer investigates it. The tick is using the pheromone as a kairomone. Pheromones can act as allomones as well, though the interaction is sometimes less direct. Bolas spiders produce the sex-attractant pheromone of a female moth and use it to lure male moths to a trap. The spider uses the moth pheromone as an allomone. Pheromonal Compounds and Strategies The chemical compounds that act as pheromones are numerous and diverse. Most are lipids or chemical relatives of the lipids, including many steroids. Even a single pheromonal message may require a number of different compounds, each present in the proper proportion, so that the active pheromone is actually a mixture of chemical compounds. Different physical and chemical characteristics are required for pheromones with different functions. Attractant pheromones must generally be volatile to permit atmospheric dispersal to their targets. Many female insects emit sex-attractant pheromones to advertise their readiness to mate. The more widely these can be dispersed, the more males the advertisement will reach. On the other hand, many marking pheromones need not be especially volatile because they are placed at stations which are checked periodically by the target individuals. The klipspringer marking pheromone is an example. Some pheromones are exchanged by direct contact, and these need not have any appreciable volatile component. Many mammals rub, lick, and otherwise contact one another in social contexts and exchange pheromones at these times. Specificity also varies for pheromones with different functions. Sex attractants usually need to be very specific, directed only to members of the opposite sex and the same species. Alarm pheromones, on the other hand, need not be so specific. These pheromones simply alert other members of the same species to a disturbance. It is usually harmless, and sometimes even helpful, to alert members of other species as well. In keeping with this argument, related groups of ant species produce species-specific sex-attractant pheromones: Each female attracts only males of its own species. In contrast, alarm pheromones of any species in the group will stimulate defensive reactions in individuals of many in the species. Pheromonal systems are not organized in any standard way in different species. Many mites and ticks also have nonspecific alarm pheromones. Surprisingly, some groups also have nonspecific sex-attractant pheromones. In these cases, the specificity necessary for reproductive efficiency is generated by species-specific mating stimulant pheromones. These pheromones are produced by a female after males have been attracted to her. They stim477
Pheromones ulate mating behavior, but only in males of the same species. Thus the required specificity is achieved by a different mechanism. This is only one of many examples of the diversity of pheromonal schemes among organisms. Pheromone Sources and Receptors The sources of pheromones are also diverse. Some pheromones are produced by specialized glands; many insect species have glands specialized for the production of pheromones. One example is the harvester ant’s alarm pheromone, which is produced in the mandibular gland at the base of the jaws. Other pheromones seem to be by-products of other bodily functions. The lipids of mammalian skin are probably primarily important in waterproofing and in maintaining the outer layer of the skin, but many also function as pheromones. The reproductive tract is an important source of pheromones in many species. These usually act as sex-attractant or sex-stimulant pheromones or as signal pheromones that give information on the sexual state of the emitter. The urine and feces of many species also contain pheromones that are used to mark territory boundaries and to transmit other information about the marking individual. Many pheromones seem to be produced not by the sending organism alone but by microorganisms living on the skin or in the glands or cavities of the sender’s body. These microbes convert products of their host into the actual signal molecules, or pheromones, used by the host. The receptors for pheromones are also of many different types, and the chemical receptors for taste and smell are often involved. In vertebrates, the vomeronasal organ (Jacobson’s organ) seems to be an important receptor for many pheromones. It is a pouch off the mouth or nasal passages, and it contains receptors similar to those for smell. It is nonfunctional in humans, but it functions in more primitive mammals and seems to be of great importance to snakes and other reptiles. Insects and other invertebrates have many specialized structures for receiving pheromonal messages. Perhaps the best-known example is the feathery antennae of many male moths, which are receptors for the female moth’s sex-attractant pheromone. Some pheromones seem to be absorbed through the skin or internal body linings and to bring about their effects by attaching to some unknown internal receptor. Prevalence in Nature Pheromones are widespread in nature, occurring in most, if not all, species. Most are poorly understood. The best-known are those found in insects, partly because of their potential use in the control of pest populations and 478
Pheromones partly because the relative simplicity of insect behavior allowed for rapid progress in the identification of pheromones and their actions. Despite these advantages, much remains to be learned even about insect pheromones. Mammalian pheromones are not as well known, although they may also be of economic importance. The more complex behavior of mammals makes the study of their responses to pheromones much more difficult. Research Methods Both behavioral and chemical techniques are required to study pheromones and other semiochemicals. The observation of behavior, either in nature or in captivity, often suggests pheromonal functions. These hypothesized functions are then tested by presenting the pheromone to a potentially responsive organism and observing the response. Situations may be arranged which demand the subject’s response to a particular pheromone under otherwise natural conditions. Alternatively, the organisms may be observed in enclosures to help control the experimental context. The presentation of the hypothetical pheromone may be in the form of another organism of the same species or some structure to which the presumed pheromone has been applied. The observed response (or lack of response) gives information on the status of the presented chemical as a pheromone in that behavioral context. While the pheromonal function of secretions from a gland or other source can be determined from these behavioral tests, the tests can give information on specific chemical compounds only if the compounds can be isolated and identified. The isolation and identification of pheromonal compounds are challenging because of the great complexity of the secretions in which they are found and the exceptionally small amounts that are required to elicit a response. Many separation and identification techniques are used. One of the most powerful is a combination of gas chromatography and mass spectrometry. Gas chromatography is used to separate and sometimes to identify chemicals that are volatile or can be made volatile. The unknown chemical is mixed with an inert gas, called the mobile phase of the gas chromatography system. This mixture is passed through a tube containing a solid, called the stationary phase. The inert gas does not interact with the solid; however, many of the compounds mixed with it do, each to an extent determined by the characteristics of the compound and the characteristics of the stationary phase. Some members of the mixture will interact very strongly with the solid and so move slowly through the tube, whereas others may not interact with the solid at all and so pass through rapidly. Other 479
Pheromones members of the mixture interact at intermediate strengths and so spend intermediate amounts of time in the tube. The different compounds are recorded and collected separately as they exit from the tube. For identification, the compounds are often passed on to a mass spectrometer. In mass spectrometry the compound is broken up into electrically charged particles. The particles are then separated according to their mass-to-charge ratio, and the relative number of particles of each mass-tocharge ratio is recorded and plotted. The original compound can usually be identified by the pattern produced under the specific conditions used. After separation and identification, the individual chemicals may be subjected to behavioral studies. Uses for Pheromones Pheromones and other semiochemicals are of interest simply from the standpoint of understanding communication between living things. In addition, they have the potential to provide effective, safe agents for pest control. The possibilities include sex-attractant pheromones to draw pest insects of a particular species to a trap (or to confuse the males and keep them from finding females) and repellant pheromones to drive a species of insect away from a valuable crop species. One reason for the enthusiasm generated by pheromones in this role is their specificity. Whereas insecticides generally kill valuable insects as well as pests, pheromones will often be specific for one or a few species. These chemicals were presented as a panacea for insect and other pest problems in the 1970’s, but most actual attempts to control pest populations failed. Many people in the field have suggested that lack of understanding of the particular pest and its ecological context was the most common cause of failure. They maintain that pest-control applications must be made with extensive knowledge and careful consideration of pest characteristics and the ecological system. In this context, pheromones have become a part of integrated pest management (IPM) strategies, in which they are used along with the pest’s parasites and predators, resistant crop varieties, insecticides, and other weapons to control pests. In this role, pheromones have shown great promise. Some consideration has been given to the control of mammalian pests with pheromones, though this field is not as well developed as that of insect control. Pheromonal control of mammalian reproduction has received considerable attention for other reasons: Domestic mammals are of great economic importance, and many wild mammalian species are endangered to the point that captive breeding has been attempted. The manipulation of reproductive pheromones may be used to enhance reproductive potentials 480
Pheromones in both cases. The complexity of mammalian behavioral and reproductive systems, however, and the subtle changes brought about by mammalian pheromones present a particular challenge. As with insect pest control, the key to progress is a complete understanding of the entire system being manipulated. Pheromones and other semiochemicals are of great potential economic importance as substitutes for or adjuncts to toxic pesticides in pest management. Mammalian reproductive pheromones are being explored as tools to enhance reproductive efficiency in domestic and endangered mammals. A complete understanding of the complex roles of pheromones in each of the systems being managed is necessary for success in all these endeavors. Carl W. Hoagstrom See also: Allelopathy; Biopesticides; Communication; Defense mechanisms; Displays; Ethology; Insect societies; Isolating mechanisms; Metabolites; Reproductive strategies. Sources for Further Study Agosta, William C. Chemical Communication: The Language of Pheromones. New York: Scientific American Library, 1992. Albone, Eric S. Mammalian Semiochemistry: The Investigation of Chemical Signals Between Mammals. New York: John Wiley & Sons, 1984. Booth, William. “Revenge of the ‘Nozzleheads.’ ” Science 239 (January 8, 1988): 135-137. Carde, Ring T., and Albert K. Minks, eds. Insect Pheromone Research: New Directions. New York: Chapman and Hall, 1997. Mayer, Marion S., and John R. McLaughlin. Handbook of Insect Pheromones and Sex Attractants. Boca Raton, Fla.: CRC Press, 1991. Mitchell, Everett R., ed. Management of Insect Pests with Semiochemicals: Concepts and Practice. New York: Plenum, 1981. Mittler, Thomas E., Frank J. Radovsky, and Vincent H. Resh, eds. Annual Review of Entomology. Vol. 46. Palo Alto, Calif.: Annual Reviews, 2000. Nordlund, Donald A., Richard L. Jones, and W. Joe Lewis, eds. Semiochemicals: Their Role in Pest Control. New York: John Wiley & Sons, 1981. Vandenbergh, John G., ed. Pheromones and Reproduction in Mammals. New York: Academic Press, 1983. Wilson, Edward O. “Pheromones.” Scientific American 206 (May, 1963): 100114.
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PHYTOPLANKTON Types of ecology: Ecoenergetics; Ecotoxicology Most plankton are microscopic and are usually single-celled, a chain of cells, or a loose group of cells. Algal and cyanobacterial plankton are referred to as phytoplankton.
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he term “plankton,” from Greek planktos for “wandering,” is applied to any organism that floats or drifts with the movement of the ocean water. Whereas the heterotrophic crustaceans and larvae of animals are referred to as zooplankton, phytoplankton phytoplankton (literally, “plant” plankton) refer to a collection of diverse, largely algal and cyanobacterial, microorganisms. The phytoplankton include diatoms, unicellular cyanobacteria and coccolithophorids in nutrient-poor waters, and cryptomonads. They manufacture organic material from carbon dioxide, usually through photosynthesis, and therefore occupy the key trophic level of producers, at the base of the food chain. Phytoplankton are responsible for one-half of the world’s primary photosynthesis and produce one-half of the oxygen in the atmosphere. Eighty to ninety percent of the weight of phytoplankton is water, with the rest made up of protein, fat, salt, carbohydrates, and minerals. Some species have compounds of calcium or silica that make up their shells or skeletons. Phytoplankton include many of the algal phyla: Chrysophyta (chrysophytes), Phaeophyta (golden-brown algae), coccolithophores, silicoflagellates, and diatoms. The most common type of phytoplankton is the diatom (phylum Bacillariophyta), a single-celled organism that can form complex chains. Dinoflagellates (phylum Dinophyta) are the most complex of the phytoplankton. They are unicellular and mobile. Green algae (phylum Chlorophyta) are usually found in estuaries or lagoons in the late summer and fall. Some species can cause toxic algal blooms associated with coastal pollution and eutrophication. Cyanobacteria (often called bluegreen algae but not true algae) are prominent near shore waters with limited circulation and brackish waters. Role in the Food Chain Phytoplankton are primary producers, responsible for half the world’s primary photosynthesis: the conversion of light energy and inorganic matter into bioenergy and organic matter. Each year, 28 billion tons of carbon and 482
Phytoplankton 250 billion to 300 billion tons of photosynthetically produced materials are generated in the oceans by phytoplankton. All animal organisms eliminate carbon dioxide into the atmosphere, and plants remove carbon dioxide from the air through photosynthesis. In the oceans’ carbon cycle, carbon dioxide from the atmosphere dissolves in the ocean. Photosynthesis by marine plants, mainly phytoplankton, converts the carbon dioxide into organic matter. Carbon dioxide is later released by plants and animals during respiration, while carbon is also excreted as waste or in the dead bodies of organisms. Bacteria decompose organic matter and release the carbon dioxide back into the water. Carbon may be deposited as calcium carbonate in biogenous sediments and coral reefs (made of skeletons and shells of marine organisms). Because they are primary producers of organic matter through photosynthesis, phytoplankton play a key role in the world’s food chain: They are its very beginning. Sunlight usually penetrates only 200 to 300 feet deep into ocean waters, a region called the photic zone. Most marine plant and animal life and feeding take place in this zone. Phytoplankton, the first level in the marine food chain, are the primary food source for zooplankton and larger organisms. These microscopic plants use the sun’s energy to absorb minerals to make basic nutrients and are eaten by herbivores, or plant eaters. Herbivores are a food source for carnivores, the meat eaters. In temperate zones, phytoplankton increase greatly in the spring, decline in the summer, and increase again in the fall. Zooplankton (animal plankton) are at their maximum abundance after the spring increase, and their grazing on the phytoplankton causes a decrease in phytoplankton population in the summer. Fish and invertebrates that eat zooplankton become more abundant and so on, up the food chain. Krill, planktonic crustaceans, and larvae commonly eaten by whales, fish, seals, penguins, and seabirds feed on diatom phytoplankton. Red Tides The term “red tide” is applied to red, orange, brown, or bright-green phytoplankton blooms, or even to blooms that do not discolor the water. Red tides are poorly understood and unpredictable. No one is certain what causes the rapid growth of a single species of phytoplankton, although they can blossom where sunlight, dissolved nutrient salts, and carbon dioxide are available to trigger photosynthesis. Dense phytoplankton blooms occur in stable water where lots of nutrients from sewage and runoff are available. Natural events, such as storms and hurricanes, may remobilize populations buried in the sediment. These nuisance blooms, usually caused by dinoflagellates, which turn the water a reddish brown, 483
Phytoplankton and cyanobacteria, are becoming more frequent in coastal waters, possibly because of increased human populations and sewage. In shallower bodies of water, such as bays and estuaries, nutrients from winter snow runoffs, spring rains, tributaries, and sewage bring about spring and summer blooms. Some of the poisons produced during red tides are the most powerful toxins known. The release of toxins by dinoflagellates may poison the higher levels of the food chain as well as suppress other phytoplankton species. These toxins cause high mortality in fish and other marine vertebrates. They can kill the whales and seabirds that eat contaminated fish. Dinoflagellates produce a deadly neurotoxin called saxitoxin, which is fifty times more lethal than strychnine or curare. Commercial shellfish, such as mussels, clams, and crabs, can store certain levels of the toxin in their bodies. People who eat contaminated shellfish may experience minor symptoms, such as nausea, diarrhea, and vomiting, or more severe symptoms such as loss of balance, coordination and memory, tingling, numbness, slurred speech, shooting pains, and paralysis. In severe cases, death results from cardiac arrest. When the toxins are blown ashore in sea spray, they can cause sore throats or eye and skin irritations. Toxic blooms costs millions of dollars in economic losses, especially for fisheries which cannot harvest some species of shellfish. Smaller fish farms can be devastated. Additionally, coastal fish deaths foul beaches and shore water with decaying bodies, which can cripple tourism in the coastal regions. Not all blooms are harmful, but they do affect the marine environment. Even when no toxins are released, massive fish kills can result when the large blooms of phytoplankton die. When the blooming phytoplankton population crashes, bacterial decomposition depletes the oxygen in the water, which in turn reduces water quality, and fish and other marine animals suffocate. Virginia L. Hodges See also: Biomass related to energy; Eutrophication; Food chains and webs; Marine biomes; Nutrient cycles; Trophic levels and ecological niches. Sources for Further Study Castro, Peter, and Michael Huber. Marine Biology. 3d ed. Boston: McGrawHill, 2000. Cousteau, Jacques. The Ocean World. New York: Harry N. Abrams, 1985. 484
Phytoplankton Levinton, Jeffrey S. Marine Biology: Function, Biodiversity, Ecology. New York: Oxford University Press, 1995. Sumich, James L. An Introduction to the Biology of Marine Life. 5th ed. Dubuque, Iowa: William C. Brown, 1992.
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POISONOUS ANIMALS Types of ecology: Behavioral ecology; Chemical ecology; Physiological ecology Animal poisons, or venoms, are used both as a defense mechanism and as a predatory strategy. These toxins can be delivered by biting, stinging, or body contact. Poisonous species occur throughout the animal kingdom and include snakes, insects, spiders and other arachnids, mammals, lizards, and fish.
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ubstances that cause disease symptoms, injure tissues, or disrupt life processes on entering the body are poisons. When ingested in large quantities, most poisons kill. Poisons can be contacted from minerals, in vegetable foods, or through animal attack. Any poison of animal origin is a venom. Venoms are delivered by biting, stinging, or other body contact. These animal poisons are used to capture prey or in self-defense. Often, it seems that the ability to make venom arose in animals that were too small, too slow, or too weak to maintain an ecological niche otherwise. The most familiar poisonous animals are snakes, insects, spiders, and some other arachnids. Poisonous species, however, occur throughout the animal kingdom, including a few mammals and lizards, and some fish. The severity of venom effects depends on its chemical nature, the nature of the contact mechanisms, the amount of venom delivered, and victim size. For example, all spiders are poisonous. However, their venom is usually dispensed in small amounts that do not affect humans. Hence, few spiders kill humans, though they kill prey and use venom in self-defense very effectively. Chemically, venoms vary greatly. Snake venoms are mixtures of enzymes and toxins. Study of their effects led to the identification of hemotoxins, which cause blood vessel damage and hemorrhage; neurotoxins, which paralyze nerves controlling heart action and respiration; and clotting agents, which excessively promote or prevent blood clotting. Cobras, coral snakes, and arachnids all have neurotoxic venoms. Lizards, Arthropods, and Insects Only two species of poisonous lizard are known: Gila monsters and beaded lizards (both holoderms). They inhabit the southwestern deserts of the United States and Mexico. They do not strike like snakes; rather, they bite, hold on, and chew to apply their venom. Holoderm bites kill prey but rarely kill humans. Beaded lizards grow to three feet long and Gila monsters grow to two feet long. 486
Poisonous animals Most poisonous arthropods are spiders and scorpions. Both use venom to subdue or kill prey. As stated earlier, few spiders endanger humans because their venom is weak and is not injected in large quantities, but some species have very potent venom and harm or even kill humans. Best known of these are black widow spiders. Though rarely lethal to humans, black widow bites cause cramps and paralysis. All of the approximately six hundred scorpion species, of sizes between one and ten inches, have tail-end stingers. Large, tropical scorpions can kill humans, while American scorpions are smaller and less dangerous. Scorpions are more dangerous than spiders because they crawl into shoes and other places where their habitat overlaps with that of humans. Many insects, such as caterpillars, bees, wasps, hornets, and ants, use venom in self-defense or to paralyze prey to feed themselves or offspring. Caterpillars use poison spines for protection. Bees, wasps, hornets, and ants use stingers for the same purpose. The venom of insects also kills many organisms that seek to prey on them. Humans, however, are rarely killed by insect bites. Such bites are usually mildly to severely painful for a period from a few minutes to several days. However, for some humans who are particularly sensitive, severe anaphylaxis occurs, in some cases followed by death. Poisonous Snakes Poisonous snakes are colubrids, elapids, or vipers, depending on their anatomic characteristics. All have paired, hollow fangs in the front upper jaw. The fangs fold back against the upper palate when not used, and when a snake strikes they swing forward to inject a venom that attacks the victim’s blood and tissues. The heads of poisonous snakes are scale-covered and triangular. Such snakes are found worldwide and include pit vipers, named for the pits on each side of the head that contain heat receptors. The pits detect warm-blooded prey, mostly rodents, in the dark. Pit vipers include rattlesnakes, moccasins, copperheads, fer-de-lance, and bushmasters. The populations and species of American and European poisonous snakes differ. In North America, twenty such snake types occur: elapid coral snakes and copperheads, sixteen rattler types, and cottonmouths (all vipers). Vipers are found everywhere but Alaska. Rattlers have the widest habitat, as shown by their abundance in the snake-rich Great Plains, Mississippi Valley, and southern Appalachia. In contrast, copperheads and cottonmouths are abundant in Appalachia and the Mississippi Valley, respectively. Mexican poisonous snakes are divided into two ranges: the northern, from the U.S.-Mexican border to Mexico City, and the southern, south of Mexico City. In the north, snakes are mostly rattlers, as in the con487
Poisonous animals tiguous United States. Coral snakes and pit vipers are plentiful in the south. Most perilous are the five- to eight-foot fer-de-lance, whose venom kills many humans. All South American vipers live in tropical environments, except for rattlesnakes. Rattlers prefer arid environments, although some are also found in tropical climates. Bushmasters, the largest South American vipers, and elapid coral snakes are nocturnal and rarely endanger humans. Tropical rattlers and lance-headed vipers, somewhat less nocturnal, kill many. Europe has few snakes, due to its cool climates and scarce suitable habitats. Its few vipers range almost to the Arctic Circle. Eastern Mediterranean regions hold most of the European vipers. There are many poisonous snakes in Africa and Asia. North Africa, mostly desert, has few snakes. Central Africa’s diverse poisonous snakes are colubrid, elapid, and viper types. Elapids include dangerous black mambas, twelve to fourteen feet long, and smaller cobras, which also occur in South Africa. Among diverse vipers, the most perilous are Gaboon vipers and puff adders. The Middle East, mostly desert, has few poisonous snakes. Southeast Asia has the most poisonous snakes in the world, elapids, colubrids, and vipers. This is due to snake habitats that range from semiarid areas to rain forests. The huge human population explains why this area has the world’s highest incidence of snakebite and related deaths. Vipers bite most often, but elapids cause a larger portion of deaths. The Far East snake population is complex, and its snakebite incidence is also high. Its important poisonous snakes are pit vipers. Australia and New Guinea have large numbers of poisonous snakes. Australia has 65 percent of the world’s snakes, while New Guinea has 25 percent. Also, sea snakes occur offshore and in some rivers and lakes. However, these countries have few snakebite deaths, because of the small size and nocturnal nature of most of the indigenous snakes. Poisonous Fish and Amphibians Venomous fish are dangerous to those who enter the oceans, especially fishermen who take them from their nets. The geographical distribution of these fish is like all other fish. The highest population density is in warm temperate or tropical waters. Numbers and varieties of poisonous fish decrease with proximity to the North and South Poles, and they are most abundant in Indo-Pacific and West Indian waters. A well-known group of poisonous fish, the stingrays (dasyatids), inhabit warm, shallow, sandy-to-muddy ocean waters. Dasyatids lurk almost completely buried, awaiting prey that they sting to death with barbed, venomous teeth in their tails. The tail poison is made in glands at the bases of the teeth. Small, freshwater dasyatids are found in South 488
Poisonous animals American rivers, such as the Amazon, hundreds of miles from the river mouths. Stingrays near Australia grow to fifteen-foot lengths. The wide distribution of stingrays and their danger to humans are mentioned in the writings of Aristotle in the third century b.c.e. and they played a role in the death of John Smith in 1608, who was killed by a stingray while exploring Chesapeake Bay. Also well known are the venomous Scorpaenidae fish family, many members of which cause very painful stings. Zebrafish and stonefish are good examples. Both, like all scorpaenids, have sharp spines supporting dorsal fins. The spines, used in self-defense, have venom glands. The most deadly fish venom is that of the stonefish, which, when stepped on, can kill humans. Frogs and Toads Poisonous animals that endanger by contact are exemplified not only by the zebrafish and stonefish just mentioned but also by poisonous frogs or toads. Most such frogs and toads live in Africa and South America. Poison dart frogs, for example, secrete poisons through the skin. In humans, the effects of contact with these poisons range from severe irritation to death. The poisons frighten away or kill most predators that attempt to eat the frogs. Ecological Significance The ecological function of poisonous animals is to keep down the population of insects, rodents, arachnids, and small fish. They thus contribute to maintaining the balance of nature. Poisonous land animals, such as scorpions and many poisonous snakes, are often nocturnal and add another dimension to pest control by nighttime predation. Sanford S. Singer See also: Allelopathy; Defense mechanisms; Genetically modified foods; Metabolites; Pheromones; Poisonous plants; Predation. Sources for Further Study Aaseng, Nathan. Poisonous Creatures. New York: Twenty-first Century Books, 1997. Edström, Anders. Venomous and Poisonous Animals. Malabar, Fla.: Krieger, 1992. Foster, Steven, and Roger Caras. Venomous Animals and Poisonous Plants. Boston: Houghton Mifflin, 1994. Grice, Gordon D. The Red Hourglass: Lives of the Predators. New York: Delacorte, 1998. 489
POISONOUS PLANTS Types of ecology: Chemical ecology; Physiological ecology Poisonous plants have evolved toxic substances that function to defend them against herbivores and thereby better adapt them for survival.
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fter evolving adaptations that facilitated colonization of terrestrial habitats, plants were confronted with a different type of problem. This was the problem of herbivory, or the inclination of many different types of organisms, from bacteria to insects to four-legged herbivores, to eat plants. Pressures from herbivory drove many different types of plants, from many different families, to evolve defenses. Some of these defenses included changes in form, such as the evolution of thorns, spikes, or thicker, tougher leaves. Other plants evolved to produce chemical compounds that make them taste bad, interrupt the growth and life cycles of the herbivores, make the herbivores sick, or kill them outright. Phytochemicals One of the most interesting aspects of plants, especially prevalent in the angiosperms (flowering plants), is their evolution of substances called secondary metabolites, sometimes referred to as phytochemicals. Once considered waste products, these substances include an array of chemical compounds: alkaloids, quinones, essential oils, terpenoids, glycosides (including cyanogenic, cardioactive, anthraquinone, coumarin, and saponin glycosides), flavonoids, raphides (also called oxalates, which contain needle-like crystals of calcium oxalate), resins, and phytotoxins (highly toxic protein molecules). The presence of many of these compounds can characterize whole families, or even genera, of flowering plants. Effects on Humans The phytochemicals listed above have a wide range of effects. In humans, some of these compounds will cause mild to severe skin irritation, or contact dermatitis; others cause mild to severe gastric distress. Some cause hallucinations or psychoactive symptoms. The ingestion of many other types of phytochemicals proves fatal. Interestingly, many of these phytochemicals also have important medical uses. The effects of the phytochemicals are dependent on dosage: At low doses, some phytochemicals are therapeutic; at higher doses, some can kill. 490
Poisonous plants Alkaloids Alkaloids are nitrogenous, bitter-tasting compounds of plant origin. More than three thousand alkaloids have been identified from about four thousand plant species. Their greatest effects are mainly on the nervous system, producing either physiological or psychological results. Plant families producing alkaloids include the Apocynaceae, Berberidaceae, Fabaceae, Papaveraceae, Ranunuculaceae, Rubiaceae, and Solanaceae. Some well-known alkaloids include caffeine, cocaine, ephedrine, morphine, nicotine, and quinine. Glycosides Glycosides are compounds that combine a sugar, usually glucose, with an active component. While there are many types of glycosides, some of the most important groups of potentially poisonous glycosides include the cyanogenic, cardioactive, anthraquinone, coumarin, and saponin glycosides. Cyanogenic glycosides are found in many members of the Rosaceae and are found in the seeds, pits, and bark of almonds, apples, apricots, cherries, peaches, pears, and plums. When cyanogenic glycosides break down, they release a compound called hydrogen cyanide. Two other types of glycosides, cardioactive glycosides and saponins, feature a steroid molecule as part of their chemical structure. Digitalis, a cardioactive glycoside, in the right amounts can strengthen and slow the heart rate, helping patients who suffer from congestive heart failure. Other cardioactive glycosides from plants such as milkweed and oleander are highly toxic. Saponins can cause severe irritation of the digestive system and hemolytic anemia. Anthraquinone glycosides exhibit purgative activities. Plants containing anthraquinone glycosides include rhubarb (Rheum species) and senna (Cassia senna). Household Plants Many common household plants are poisonous to both humans and animals. One family of popular household plants that can cause problems is the Araceae, the philodendron family, including plants such as philodendron and dieffenbachia. All members of this family, including these plants, contain needlelike crystals of calcium oxalate that, when ingested, cause painful burning and swelling of the lips, tongue, mouth, and throat. This burning and swelling can last for several days, making talking and even breathing difficult. Dieffenbachia is often referred to by the common name of dumb cane, because eating it makes people unable to talk for a few days. 491
Poisonous plants
Foxgloves, a common ornamental garden flower, produce cardiac glycosides with strong physiological effects on heart muscle. Although highly toxic, if processed in the right amounts these glycosides can strengthen and slow the heart rate, helping patients who suffer from congestive heart failure. (PhotoDisc)
Landscape Plants Many landscape plants are also poisonous. For example, the yew (genus Taxus), commonly planted as a landscape plant, is deadly poisonous. Children who eat the bright red aril, which contains the seed, are poisoned by the potent alkaloid taxine. Yews are poisonous to livestock as well, causing death to horses and other cattle. Death results from cardiac or respiratory failure. Other poisonous landscape and garden plants include oleander, rhododendrons, azaleas, hyacinths, lily of the valley, daffodils, tulips, and Starof-Bethlehem. Many legumes are also toxic, including rosary pea, lupines, and wisteria. Castor bean plant, a member of the family Euphorbiaceae, produces seeds that are so toxic that one seed will kill a child and three seeds are fatal to adults. The toxin produced by the seeds is called ricin, which many scientists consider to be the most potent natural toxin known. Arrow Poisons Toxic plant and animal products have been used for thousands of years in hunting, executions, and warfare. Usually the poisonous extracts were smeared on arrows or spears. The earliest reliable written evidence for these uses comes from the Rigveda from ancient India. Arrow poisons come in many different varieties, and most rain-forest hunters have their own secret blend. South American arrow poisons are generically called curare. 492
Poisonous plants There are more than seventy different plant species used in making arrow poisons. Two of the main arrow poison plants are woody vines from the Amazon: Strychnos toxifera and Chondodendron tomentosum. Some types of curare have proven medically useful. They are used as muscle relaxants in surgery, which lessens the amount of general anesthetic needed. A plant called Strychnos nux-vomica from Asia yields the poison strychnine, a stimulant of the central nervous system. In ancient times, toxic plant products were also commonly used in executions. Many people were expert, professional poisoners in the ancient world. They could select a poison that would take days or even months to take effect, thus ensuring, for example, that an unfaithful spouse or lover would not suspect the reason for his or her lingering illness. On occasions when a more rapid result was required, a strong dose or more powerful poison could be prescribed. Poison Ivy Toxicodendron radicans, commonly known as poison ivy, is well known for causing contact dermatitis. Poison ivy is a member of the Anacardiaceae, or cashew family, and is a widespread weed in the United States and southern Canada. It grows in a variety of habitats: wetlands, disturbed areas, and the edges of forests. It has many forms, appearing as either a shrub or a woody vine which will grow up trees, houses, fences, and fence posts. It has alternate leaves with three leaflets, forming the basis of the old saying “Leaves of three, let it be.” After poison ivy flowers, it develops clusters of white or yellowish-white berries. Related species are poison oak, western poison oak, and poison sumac, which some scientists consider to be different types of poison ivy. Roughly half the world’s population is allergic to poison ivy. Very sensitive people develop a severe skin rash; about 10 percent of the people who are allergic require medical attention after exposure. The chemical compound causing the allergic reaction is called urushiol, a resin found in all parts of the plant. Urushiol is so potent that in some individuals, just one drop produces a reaction. Inhaling smoke from burning poison ivy can result in eye and lung damage. For some people, mere contact with the smoke from burning poison ivy can trigger a reaction. Urushiol lasts forever; in herbaria, dried plants one hundred years old have given unlucky botanists contact dermatitis. Carol S. Radford See also: Allelopathy; Defense mechanisms; Genetically modified foods; Metabolites; Pheromones; Poisonous animals; Predation. 493
Poisonous plants Sources for Further Study Burrows, George E., and Ronald J. Tyrl. Toxic Plants of North America. Ames: Iowa State University Press, 2001. Levetin, Estelle, and Karen McMahon. Plants and Society. 2d ed. Boston: WCB/McGraw-Hill, 1999. Lewis, Walter H., and Memory P. F. Elvins-Lewis. Medical Botany: Plants Affecting Man’s Health. New York: John Wiley and Sons, 1997. Simpson, Beryl B., and Molly Conner Ogarzaly. Economic Botany: Plants in Our World. 3d ed. Boston: McGraw-Hill, 2000.
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POLLINATION Types of ecology: Community ecology; Physiological ecology Pollination—the transfer of pollen from anther to stigma in flowering plants or from male cone to ovules in gymnosperms—accounts for a wide variety of ecological interactions in communities of organisms.
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ollination is the process, in sexually reproducing plants (both angiosperms and gymnosperms), whereby the male sperm and female egg are joined via transfer of pollen (male microspore). If the anthers and stigmas of the plants involved have the same genetic makeup or they are produced on the same plant, the type of pollination is called self-pollination. If anthers and stigmas are from plants with different genetic makeups, the type of pollination is called cross-pollination. Self-pollination is efficient because pollen from the anther of a flower can be transferred easily onto the stigma of the same flower, owing to the proximity of the two parts. On the other hand, cross-pollination is risky because the transfer of pollen involves long distances and precise destinations, both of which depend on animal pollinators. In areas with few animal pollinators, the opportunities for cross-pollination may be greatly reduced (one of the many reasons that preserving biological diversity is an important ecological issue). In spite of the risk associated with cross-pollination, most flowers have mechanisms that promote this kind of pollination. Cross-pollination increases the likelihood that offspring are vigorous, healthy, fertile, and able to survive even if the environment changes. Self-pollination leads to offspring that are less vigorous, less productive, and more subject to inbreeding depression (weakening of the offspring as a result of inbreeding). When certain consumers forage among plants for food, they often come in contact with flowers. Many insects and other animals become dusted with pollen, and in the course of their travel they unintentionally but effectively bring about pollination. Throughout the evolutionary history of flowering plants, many pollinators have coevolved with plants. Coevolution occurs when the floral parts of a plant and the body parts and behavior of the pollinators become mutually adapted to each other, thereby increasing the effectiveness of their interaction. In many instances, the relationship between the plant and pollinator has become highly specialized, resulting in mutualism, which is interaction where both organisms benefit from each other. 495
Pollination In the case of pollination by animals, the pollinator receives a reward from the flower in the form of food. When the pollinator moves on, the plant’s pollen is transferred to another plant. The adaptations between the flower and its pollinators can be intricate and precise and may even involve force, drugs, deception, or sexual enticement. In flowering plants, pollination is mostly due to insects or wind, but birds, bats, and rodents also act as pollinators for a number of plants. Insects Insect pollination occurs in the majority of flowering plants. There is no single set of characteristics for insect-pollinated flowers, because insects are a large and diverse group of animals. Rather, each plant may have a set of reproductive features that attracts mostly a specific species of insect. The principal pollinating insects are bees, although many other kinds of insects act as pollinators, including wasps, flies, moths, butterflies, ants, and beetles. Bees have body parts suitable for collecting and carrying nectar and pollen. Their chief source of nourishment is nectar, but they also collect pollen for their larvae. The flowers that bees visit are generally brightly colored and predominantly blue or yellow—rarely pure red, because red appears black to bees. The flowers they visit often have distinctive markings that function as guides that lead them to the nectar. Bees can perceive
Honeybees are well known for their contribution to plant propagation, carrying pollen from flower to flower. This relationship has coevolved over time; the bees are dependent on the flowers, and vice versa. (PhotoDisc) 496
Pollination ultraviolet (UV) light (a part of the spectrum not visible to humans), and some flower markings are visible only in UV light, making patterns perceived by bees sometimes different from those seen by humans. Many beepollinated flowers are delicately sweet and fragrant. Moth- and butterfly-pollinated flowers are similar to bee-pollinated flowers in that they frequently have sweet fragrances. Some butterflies can detect red colors, and so red flowers are sometimes pollinated by them. Many moths forage only at night; the flowers they visit are usually white or cream-colored because these colors stand out against dark backgrounds in starlight or moonlight. With their long mouthparts, moths and butterflies are well adapted for securing nectar from flowers with long, tubeshaped corollas (the petals collectively), such as larkspur, nasturtium, tobacco, evening primrose, and amaryllis. The flowers pollinated by beetles tend to have strong, yeasty, spicy, or fruity odors. They are typically white or dull in color, in keeping with the diminished visual sense of their pollinators. Although some beetlepollinated flowers do not secrete nectar, they furnish pollen or other foods which are available on the petals in special storage cells. Birds Birds and the flowers that they pollinate are also adapted to each other. Birds do not have a highly developed sense of smell, but they have a keen sense of vision. Their flowers are thus frequently bright red or yellow and usually have little, if any, odor. The flowers are typically large or are part of a large inflorescence. Birds are highly active pollinators and tend to use up their energy very rapidly. Therefore, they must feed frequently to sustain themselves. Many of the flowers they visit produce copious quantities of nectar, assuring the birds’ continued visitation. The nectar is frequently produced in long floral tubes, which prevent most insects from gaining access to it. Examples of bird-pollinated flowers are red columbine, fuchsia, scarlet passion flower, eucalyptus, hibiscus, and poinsettia. Bats and Rodents Bat-pollinated flowers are found primarily in the tropics, and they open only at night, when the bats are foraging. These flowers are dull in color, and like bird-pollinated flowers, they are large enough for the pollinator to insert part of its head inside. The plants may also consist of ball-like inflorescences containing large numbers of small flowers whose stamens readily dust the visitor with pollen. Bat-pollinated flowers include bananas, mangoes, kapok, and sisal. Like moth-pollinated flowers, flowers that attract bats and small rodents open at night. Mammal-pollinated flow497
Pollination ers are usually white and strongly scented, often with a fruity odor. Such flowers are large, to provide the pollinators enough pollen and nectar to fulfill their energy requirements. The flowers are also sturdy, to bear the frequent and vigorous visits of these small mammals. Orchid Pollinators The orchid family has pollinators among bees, moths and butterflies, and beetles. Some of the adaptations between orchid flowers and their pollinators are extraordinary. Many orchids produce their pollen in little sacs called pollinia, which typically have sticky pads at the bases. When a bee visits such a flower, the pollinia are usually deposited on its head. In some orchids, the pollinia are forcibly “slapped” on the pollinator through a trigger mechanism within the flower. In some orchids, a petal is modified so that it resembles a female wasp or bee. Male wasps or bees emerge from their pupal stage before the females and can mistake the orchids for potential mates. They try to copulate with these flowers, and while they are doing so, pollinia are deposited on their heads. When the wasps or bees visit other flowers, the pollinia are caught in sticky stigma cavities. When moths and butterflies pollinate orchids, the pollinia become attached to their long tongues by means of sticky clamps instead of pads. The pollinia of certain bog orchids become attached to the eyes of the female mosquitoes that pollinate them. After a few visits, the mosquitoes are blinded and unable to continue their normal activities (a good example of a biological control within an ecosystem). Among the most bizarre of the orchid pollination mechanisms are those whose effects are to dunk the pollinator in a pool of watery fluid secreted by the orchid itself and then permit the pollinator to escape underwater through a trap door. The route of the insect ensures contact between the pollinia and stigma surfaces. In other orchids with powerful narcotic fragrances, pollinia are slowly attached to the drugged pollinator. When the transfer of pollinia has been completed, the fragrance abruptly fades away, and the insect recovers and flies away. Wind and Water Wind pollination is common in those plants with inconspicuous flowers, such as grasses, poplars, walnuts, alders, birches, oaks, and ragweeds. These plants lack odor and nectar and are, hence, unattractive to insects. Furthermore, the petals are either small or absent, and the sex organs are often separate on the same plant. In grasses, the stigmas are feathery and expose a large surface to catch pollen, which is lightweight, dry, and easily blown by the wind. Because wind-pollinated flowers do not depend on an498
Pollination imals to transport their pollen, they do not invest in the production of rewards for their visitors. However, they have to produce enormous quantities of pollen. Wind pollination is not efficient because most of the pollen does not end up on the stigmas of appropriate plants but on the ground, bodies of water, and in people’s noses (a major cause of allergic reactions). Wind pollination is successful in cases where a large number of individuals of the same species grow fairly close together, as in grasslands and coniferous forests. Water pollination is rare, simply because fewer plants have flowers that are submerged in water. Such plants include the sea grasses, which release pollen that is carried passively by water currents. In some plants, such as the sea-nymph, pollen is threadlike, thus increasing its chances of coming in contact with stigmas. In eelgrass, the entire male flower floats. Danilo D. Fernando See also: Adaptations and their mechanisms; Animal-plant interactions; Coevolution; Communities: ecosystem interactions; Communities: structure; Reproductive strategies; Symbiosis. Sources for Further Study Barth, Friedrich G. Insects and Flowers: The Biology of a Partnership. Princeton, N.J.: Princeton University Press, 1991. Proctor, Michael, Peter Yeo, and Andrew Lack. The Natural History of Pollination. Portland, Oreg.: Timber Press, 1996. Raven, Peter H., Ray F. Evert, and Susan E. Eichhorn. Biology of Plants. 6th ed. New York: W. H. Freeman/Worth, 1999.
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POLLUTION EFFECTS Type of ecology: Ecotoxicology Pollutants in soil, water, and atmosphere have created enormous problems for the living world. Destroyed habitats and polluted food sources and drinking water for animals have caused deformations in animal growth, development, and reproduction, as well as a shortening of life span, all of which contribute to an accelerated decrease in biodiversity and the extinction of more species.
D
uring the last decade of the twentieth century, the ecological problems predicted by environmental scientists decades previously began to accelerate in a variety of ways. These included the human population explosion, food imbalances, inflation brought about by energy resource scarcity, acid rain, toxic and hazardous wastes, water shortages, major soil erosion, a punctuated ozone layer, and greenhouse effects. As a result of pollution, decreases in biodiversity and the extinction of both plant and animal species has accelerated. The burning and cutting of thousands of square miles of rain forests not only destroyed habitats for numerous animal species but also caused irreversible damage to ecosystems and climates. Industrialization and the expansion of the human population had left relatively few places on earth undisturbed. Heavy dependence upon fossil fuels for energy and synthetic chemicals has resulted in the dumping of millions of metric tons of nonnatural compounds and chemicals into the environment. Recurrent drought and famine in Africa testify to human mischief toward Mother Nature. The well-being of animals as well as humans will not be protected against the ecological consequences of human actions by remaining ignorant of those actions. Effective measures taken to reduce pollution and protect natural resources and the environment first come with a recognition of these problems. The ignorance and inaction of ordinary citizens will lead to disastrous consequences for the environment, threatening humanity’s very existence. Sources and Types of Pollution Among the primary sources of pollution are agrichemicals such as fertilizers, insecticides, fungicides, and herbicides. The application of excess chemical fertilizers applied to soil hampers natural cycling of nutrients, depletes the soil’s own fertility, and destroys the habitats of thousands of small animals residing in the soil. Farm runoff carries priceless topsoil, ex500
Pollution effects pensive fertilizer, and animal manure into rivers and lakes, where these potential resources become pollutants and cause eutrophication and the subsequent death of fish and other wildlife. In the city, water pours from sidewalks, rooftops, and streets, picking up soot, silt, oil, heavy metals, and garbage. It races down gutters into storm sewers, carrying household pollutants from cleaning solutions to prescription medications, and a weakly toxic soup gushes into the nearest stream, river, or ocean. Many of these chemicals also seep into the ground, causing contamination of groundwater. Plants and factories manufacturing these chemical products are another source of pollutants and contamination. Burning fossil fuels releases greenhouse gases, carbon dioxide, and methane. Coupled with deforestation in many regions of the world, carbon dioxide concentration in the atmosphere has steadily climbed, from 290 parts per million in 1860 to 370 parts per million in 1990, a more than 25 percent rise due to industrialization. The resultant global warming will have far-reaching effects on plants, animals, and humans in ways still not understood. Acid rain, a result of overcharging the atmosphere with nitric oxides and sulfur dioxide (two gases also released by burning of fossil fuels), has increased the acidity of soil and lakes to levels at which many organisms cannot survive. The most acidic rain is concentrated in the Northeast of the United States. In New York’s Adirondack Mountains, for instance, acid rain has made about a third of all the lakes and ponds too acidic to support fish. First, much of the food web that sustains the fish was destroyed. Clams, snails, crayfish, and insect larvae die first, then amphibians, and finally fish. The detrimental effect is not limited to aquatic animals. The loss of insects and their larvae and small aquatic animals has contributed to a dramatic decline in the population of black ducks that feed on them. The result is a crystal-clear lake, beautiful but dead. Another serious problem created by the chemical industry is ozone depletion. Chlorofluorocarbon (CFC) compounds contain chlorine, fluorine, and carbon. Since their development in the 1930’s, these compounds were widely used as coolants in refrigerators and air conditioners, as aerosol spray propellants, as agents for producing Styrofoam, and as cleansers for electronic parts. These chemicals are very stable and for decades were considered to be safe. Their stability, however, turned out to be a real problem. They were in gaseous form and rose into the atmosphere. There, the high energy level of ultraviolet (UV) light breaks them down, releasing chlorine atoms, which in turn catalyzes the breakdown of ozone to oxygen gas. As a result of the decline of ozone and the punctuation of the ozone layer, UV radiation has risen by an average of 8 percent per decade since the 1970’s. 501
Pollution effects
Air Pollutant Emissions by Pollutant and Source, 1998
Source Fuel Combustion (stationary sources) Electric utilities Industrial Other fuel combustion Residential Subtotal Industrial processes Chemical and allied product manufacturing Metals processing Petroleum and related industries Other Subtotal Solvent utilization Storage and transport Waste disposal and recycling Highway vehicles Light-duty gas vehicles and motorcycles Light-duty trucks Heavy-duty gas vehicles Diesels Subtotal 2 Off highway 3 Miscellaneous Total emissions
Volatile Sulfur Nitrogen Organic Carbon Lead Particulates1 Dioxide Oxides Compounds Monoxide (tons)
302 245 544 432 1,091
13,217 2,895 609 127 16,721
6,103 2,969 1,117 742 10,189
54 161 678 654 893
417 1,114 3,843 3,699 5,374
68 19 416 6 503
65
299
152
396
1,129
175
171 32
444 345
88 138
75 496
1,495 368
2,098 NA
339 607 6 94 310
370 1,458 1 3 42
408 786 2 7 97
450 1,417 5,278 1,324 433
56
130
2,849
2,832
27,039
12
40 8 152 257 461 31,916 34,742
99 11 86 326 1,084 12 19,647
1,917 323 2,676 7,765 5,280 328 24,454
2,015 257 222 5,325 2,461 786 17,917
18,726 3,067 1,554 50,386 19,914 8,920 89,454
7 — NA 19 503 NA 3,972
632 54 3,624 2,327 2 NA 80 NA 1,154 620
Source: Adapted from U.S. Environmental Protection Agency, National Air Pollutant Emission Trends, 1900-1998, EPA-454/R-00-002. From Statistical Abstract of the United States: 2001 (Washington, D.C.: U.S. Bureau of the Census, 2001). Note: In thousands of tons, except as indicated. — Represents or round to zero. NA Not available 1 Represents both particulates of less than 10 microns and particulate dust from sources such as agricultural tilling, construction, mining, and quarrying, paved roads, unpaved roads, and wind erosion. 2 Includes emissions from farm tractors and other farm machinery, construction equipment, industrial machinery, recreational marine vessels, and small general utility engines such as lawn mowers. 3 Includes emissions such as from forest fires and other kinds of burning, various agricultural activities, fugitive dust from paved and unpaved roads, and other construction and mining activities, and natural sources.
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Pollution effects This depletion of the ozone layer poses a threat to humans, animals, plants, and even microorganisms. Long-Range Impacts of Pollution The degradation of air, land, and water as a result of the release of chemical and biological wastes has wide-ranging effects on animals. On a large scale, pollution destroys habitats and produces population crashes and even the extinction of species. Hazardous chemicals introduced into the environment sometimes render an environment unfit for life (as at Love Canal, New York, or Times Beach, Missouri). At the individual level, pollution causes abnormalities in growth, development, and reproduction. Hazardous chemicals, introduced either intentionally (such as fertilizers, herbicides, and pesticides) or through neglect (as with industrial wastes), have a variety of detrimental, sometimes devastating effects on animals. They affect the metabolism, growth and development, reproduction, and average life spans of many species. A few examples will illustrate the effects of chemical pollution on animals. In the 1940’s, the new insecticide dichloro-diphenyl-trichloroethane (DDT) was regarded as a miracle. It saved millions of lives in the tropics by killing the mosquitoes that spread deadly malaria. DDT saved millions more lives with increased crop yields resulting from DDT’s destruction of insect pests. This miraculous pesticide, however, turned out to be a longlasting nemesis to many species of wildlife and the environment. In the United States, ecologists and wildlife biologists during the 1950’s and 1960’s witnessed a stunning decline in the populations of several predatory birds, especially fish-eaters, such as bald eagles, cormorants, ospreys, and brown pelicans. The population decline drove the brown pelican and bald eagle close to extinction. In 1973, the U.S. Congress passed the Endangered Species Act, which banned the use of DDT. The once-threatened species have somewhat recovered since. In the mid 1950’s, the World Health Organization used DDT on the island of Borneo to control malaria. DDT entered food webs through a caterpillar. Wasps that fed on caterpillars were first destroyed. Gecko lizards that ate the poisoned insects accumulated high levels of DDT in their bodies. Both geckos and the village cats that ate the geckos died of DDT poisoning. The rat population exploded with its natural enemy, cats, eliminated. The village was then threatened with an outbreak of plague, carried by the uncontrolled rats. Although DDT has been banned in much of the world, there is a growing concern over the effects of a number of chlorinated compounds. These chemicals, described as “environmental estrogens,” interfere with normal sex hormone functions by mimicking the effects of the hormone estrogen 503
Pollution effects or enhancing estrogen’s potency. High levels of chlorinated compounds, such as dioxin and polychlorinated biphenyls (PCBs), in the Great Lakes have led to a sharp decline in populations of river otters and a variety of fish-eating birds, including the newly returned bald eagles. These chemicals are also the cause of deformed offspring, or eggs that never hatch. In Florida’s Lake Apopka, a spill of chlorinated chemicals in 1980 led to a 90 percent drop in the birthrate of the lake’s alligators. These are only a few examples of the detrimental effects on various animals by synthetic chemicals. Air Pollution Air pollution leads to acid rain and the greenhouse effect, as well as damage to the ozone layer. Acid rain drops out of the skies onto areas at great distances from the source of the acids and destroys forests and lakes in sensitive regions. As a result, fish populations are dwindling or being eliminated in lakes and streams by a lower pH caused by acid deposition. The strongest evidence comes from data collected from the past twenty-five to forty-five years in Adirondack lakes and in Nova Scotia rivers. Studies during this period clearly show declines in acid-sensitive species. Similar results were obtained from analyzing fish population and water acidity in Maine, Massachusetts, Pennsylvania, and Vermont. The consensus is that fish populations would be eliminated if the surface waters acidify to between pH 5.0 to pH 5.5. The effects of acid rain on other animals are indirect, either through the dwindling fish population (as a food source for other animals) or stunted forest growth (disturbance to habitats). The effect of global warming on the animal kingdom is also a serious and complex issue. As global temperature rises, ice caps in polar regions and glaciers melt, ocean waters expand in response to atmospheric warming, and thus the sea level elevates. The expected sea level rise will flood coastal cities and coastal wetlands. These threatened ecosystems are habitats and breeding grounds for numerous species of birds, fish, shrimp, and crabs, whose populations could be severely diminished. The Florida Everglades will virtually disappear if the sea level rises two feet. The impact of global warming on forests could be profound. The distribution of tree species is exquisitely sensitive to average annual temperature, and small changes could dramatically alter the extent and species composition of forests. This in turn could dramatically alter the population distribution of animals, and hence biodiversity. The effect of the punctuated ozone layer on animals is yet to be fully understood. It is known that the high energy level of UV radiation can damage biological molecules, including the genetic material deoxyribonu504
Pollution effects cleic acid (DNA), causing mutation. In small quantities, UV light helps the skin of humans and many animals produce vitamin D and causes tanning. However, in large doses, UV causes sunburn and premature aging of skin, skin cancer, and cataracts, a condition in which the lens of the eye becomes cloudy. Due to UV radiation’s ability to penetrate, even animals covered by hair and thick fur cannot escape from these detrimental effects. Ozone damage costs U.S. farmers over $2 billion annually in reduced crop yields. All who depend on forestry and agriculture may bear a much higher cost if the emission of pollutants that destroy ozone are not regulated soon. Possible Remedies The various types of pollution all have serious effects on the plant and animal species that share this planet. It is all too easy to document the impacts of pollution on human health and ignore their effects on the rest of the living world. Any possible remedies to alleviate these problems should start with education, the realization of these problems at an individual as well as a global level. The tasks seem to be insurmountable, and no organization, no country can do it alone. It takes willingness to accept short-term inconvenience or economic sacrifice for long-term benefit. A couple of examples serve to illustrate what can be done to alleviate the problems of pollution. Synthetic chemical pollutants that are poisoning both people and wildlife could be largely eliminated without disrupting the economy, as reported in a study published in 2000 by the Worldwatch Institute, a Washington, D.C.-based environmental organization. The report presents strong evidence from three sectors that are major sources of these pollutants— paper manufacturing, pesticides, and PVC plastics—to show that nontoxic options are available at competitive prices. Agricultural pollution can be mitigated, significantly reduced, or virtually eliminated through the use of proper regulation and economic incentives. Farmers from Indonesia to Kenya are learning how to use less of various chemicals while boosting yields. Since 1998, all farmers in China’s Yunnan Province have eliminated their use of fungicides, while doubling rice yields, by planting more diverse varieties of the grain. In most, if not all, cases, the question is not whether it is possible to alleviate the pollution of the environment; rather, it is whether we realize the urgency and/or are willing to take a high road to do it. For the common well-being of generations to come, better approaches have to be taken to preserve the environment and biodiversity. Ming Y. Zheng 505
Pollution effects See also: Acid deposition; Biological invasions; Biomagnification; Biopesticides; Deforestation; Eutrophication; Genetically modified foods; Integrated pest management; Invasive plants; Ocean pollution and oil spills; Ozone depletion and ozone holes; Pesticides; Phytoplankton; Slash-andburn agriculture; Waste management. Sources for Further Study Brown, Lester. State of the World 2000. New York: W. W. Norton, 2000. Hill, Julia B. The Legacy of Luna: The Story of a Tree, a Woman, and the Struggle to Save the Redwoods. San Francisco: HarperSanFrancisco, 2000. Johnson, Arthur H. “Acid Deposition: Trends, Relationships, and Effects.” Environment 28, no. 4 (May, 1986): 6-11, 34-39. Lippmann, Morton, ed. Environmental Toxicants: Human Exposures and Their Health Effects. 2d ed. New York: John Wiley & Sons, 2000. Sampat, Payal. Deep Trouble: The Hidden Threat of Groundwater Pollution. Washington, D.C.: Worldwatch Institute, 2000.
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POPULATION ANALYSIS Type of ecology: Population ecology Many animal populations are becoming threatened or endangered, primarily due to loss of suitable habitat. Population analysis enables biologists to examine the factors which lead to declines in animal populations and thus is important in the management of wild species.
A
population is a group of organisms belonging to the same species that occur together in the same time and place. Population analysis is the study of biological populations, with the specific intent of understanding which factors are most important in determining population size. Populations can change over time. They increase or decrease in size, and their change in size can depend on a wide variety of factors. For example, a wildlife biologist might be interested in studying the population of porcupines that inhabits a hemlock forest or the population of bark beetles that lives on a particular tree. Population analysis is the study of biological populations, with the specific intent of understanding which factors are most important in determining population size. Factors such as the per capita rates of birth and death, the population density, age structure, and sex ratio all contribute to determine population size. Understanding how these factors interact to influence population size is critical if biologists hope to manage populations of organisms at sustainable levels for hunting or fishing and if conservation biologists hope to prevent populations from going extinct. Discrete vs. Continuous Populations In order to conduct a population analysis, one must first determine whether the population of interest is best understood as discrete or continuous. A discrete population is one in which important events such as birth and death happen during specific intervals of time. A continuous population is one in which births, deaths, and other events take place continuously through time. Many discrete populations are those with nonoverlapping generations. For example, in many insect populations, the adults mate and lay eggs, after which the adults die. When the juveniles achieve adulthood, their parental generation is no longer living. In contrast, most continuous populations also have overlapping generations. For instance, in antelope jackrabbits (Lepus alleni), females may give birth at any time during the year, and members of several generations occur together in space and time. 507
Population analysis Mathematical Models The dynamics of animal populations are affected by a wide variety of demographic factors, including the population birthrate, death rate, sex ratio, age structure, and rates of immigration and emigration. In order to understand the effects of these factors on a population, biologists use population models. A model is an abstract representation of a concrete idea. The representation created by the model boils the concrete idea down into a few critical components. By building and examining population models, population analysts investigate the relative importance of different factors to the dynamics of a given population. A basic mathematical model of population size is as follows: Nt+1 − Nt + B − D + I − E
(equation 1)
where Nt+1 equals the population size after one time interval, Nt equals the total number of individuals in the population at the initial time, B equals the number of births, D equals the number of deaths, I equals the number of immigrants into the population, and E equals the number of emigrants leaving the population. This simple model boils population size down to just four factors, B, D, I, and E. This model is not meant to be a true or precise representation of the population; rather, it is meant to clarify the importance of the factors of birth, death, immigration, and emigration on population size. To use the same model to examine the rate of growth of a population through time, it can be rearranged as follows: Nt+1 − Nt = B − D + I −E
(equation 2)
That is, the increase or decrease in the population size between time intervals t and t + 1 is reflected by the number of births, deaths, immigrants, and emigrants. When population biologists choose to focus specifically on the importance of birth and death in population dynamics, population models are simplified by temporarily ignoring the effects of immigration and emigration. In this case, the degree of change in the population between time intervals t and t + 1 becomes: Nt+1 − Nt = B − D
(equation 3)
It is usually safe to assume that the total number of births (B) and deaths (D) in a population is a function of the total number of individuals in the population at the time, Nt. For example, if there are only ten females in a 508
Population analysis population at time t, it would be impossible to have more than ten births in the population. More births and deaths are possible in larger populations. If B equals the total number of births in the population, then B is equal to the rate at which each individual in the population gives birth, times the total number of individuals in the population. Likewise, the total number of deaths, D, will be equal to the rate at which each individual in the population might die times the total number of individuals in the population. In other words: B = bNt and D = dNt
(equation 4)
where b and d represent the per capita rate of birth and death, respectively. Given this understanding of B and D, the original model becomes Nt+1 − Nt = (bNt) − (dNt) or Nt+1 − Nt = (b − d)Nt
(equation 5)
It would be useful to find a variable that can represent per capita births and deaths at the same time. Biologists define r as the per capita rate of increase in a population, which is equal to the difference between per capita births and per capita deaths: r=b−d
(equation 6)
Thus, the equation that examines the changes in population size between time intervals t and t + 1 becomes: Nt+1 − Nt = rNt
(equation 7)
A numerical example works as follows. In a population that originally has 1,000 individuals, a per capita birthrate of 0.1 birth per year and a per capita death rate of 0.04 death per year, the net change in the population size between the year t and t + 1 would be: r = 0.1 − 0.04 = 0.06 Nt+1 − Nt = 0.06(1000) = 60 In other words, the population would increase by sixty individuals over the course of one year. 509
Population analysis Continuous Populations This model works for populations in which events take place during discrete units of time, such as a population of squirrels in which reproduction takes place at only two specific times in a single year. In contrast, many populations are continuously reproductive. That is, at any given time, any female in the population is capable of reproducing. When these conditions are met, time is viewed as more fluid than discrete, and the population exhibits continuous growth. Models of population growth are slightly different when births and deaths are continuous rather than discrete. One way to imagine the difference between a population with continuous rather than discrete growth is to imagine a population in which each time interval is infinitesimally small. When these conditions are met, the model for population growth becomes: δN/δt = rN
(equation 8)
where δN/δt represents the changes in numbers in the population over very short time intervals. The per capita rate of increase (r) can now also be called the instantaneous rate of increase because the population is one with minute time intervals. Choosing the Right Model How does a population biologist select the best model? Which model is best depends on exactly what it is that a scientist is trying to understand about a population. In the first model presented above (equation 1), the different effects of birth, death, immigration and emigration can be compared relative to one another. In the second model, the effects of immigration and emigration are ignored and the effects of birth and death are summarized into one constant called the per capita rate of increase (equations 7 and 8). If the scientist is trying to understand the cumulative effects of B, D, I, and E on the population, then equation 1 would represent a good model. On the other hand, if the scientist is trying to understand how births and deaths influence the net changes in population size, equation 7 or 8 would be a better model. When dealing with a continuous rather than a discrete population, equation 8 represents the rate of population growth as a function of per capita births and per capita deaths in the population. Equation 8 represents a population that is growing exponentially without bound. In other words, regardless of the population size at any given time, the per capita rate of increase remains the same. It would be reasonable to assume that per capita rates of increase can actually change with changes in overall population 510
Population analysis size. For example, in a population of bark beetles inhabiting the trunk of a tree, many more resources are available to individual beetles when the population is small. Resources must be shared between more and more individuals as the population size increases, which can result in changes to the per capita rate of increase. A model of population growth that incorporates the effect of overall population density on the per capita rate of increase might look like this: δN/δt = r(1 − N/K)N
(equation 9)
where K is equal to the carrying capacity, the maximum number of individuals in the population that there are adequate resources to support. The per capita rate of increase in equation 9 is not simply r by itself, but becomes r(1 − N/K). The per capita rate of increase is a function of rates of birth and death scaled by the population size and the carrying capacity of the habitat. If the population is very large relative to the number of individuals that the habitat can support, then N ≈ K, and the expression (1 − N/K) becomes approximately equal to 0. When so, equation 9 takes the following form: δN/δt = r(0)N = 0
(equation 10)
and the rate of population growth is zero. In other words, the population has ceased growing. On the other hand, if the population is very small relative to the number of individuals the habitat can support, then N << K and the expression (1 − N/K) becomes approximately equal to 1. When so, equation 9 takes the form δN/δt = r(1)N = rN
(equation 11)
and the rate of population growth remains a function of the rates of birth and death, but not the population size or carrying capacity. Thus, equation 9 represents what is called density-dependent growth. Sex Ratio and Age Structure The model set forth in equation 9 takes into account only those ways in which births, deaths, and population density relative to carrying capacity influence population growth. Sometimes it is helpful to understand how other factors such as the sex ratio and age structure in a population influence rates of growth. For example, deer hunters are not always allowed to take equal numbers of bucks and does from a population. Similarly, fisher511
Population analysis men are often restricted in the size of fish they are allowed to keep when fishing. These wildlife management and population analysis restrictions on the sex and size of animals that can be hunted arise from the fact that both age and sex can influence population growth rates. Models that incorporate the effects of age structure and population sex ratios will not be covered here. Suffice it to say that a population that consists mostly of young individuals yet to reproduce will grow more quickly than an equally sized population of mostly older individuals who have finished reproducing. Similarly, a population with a highly skewed sex ratio that has many more males than females will not grow as quickly as a population of equal size in which the number of males and females is equal. Erika L. Barthelmess See also: Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Demographics; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Human population growth; Nonrandom mating, genetic drift, and mutation; Population fluctuations; Population genetics; Population growth; Reproductive strategies; Speciation; Species loss. Sources for Further Study Gardali, Thomas, et al. “Demography of a Declining Population of Warbling Vireos in Coastal California.” The Condor 102, no. 3 (August, 2000): 601-609. Hastings, Alan. Population Biology: Concepts and Models. New York: Springer-Verlag, 1997. Hedrick, Philip W. Population Biology: The Evolution and Ecology of Populations. Boston: Jones and Bartlett, 1984. Johnson, Douglas H. “Population Analysis.” Research and Management Techniques for Wildlife and Habitats, edited by Theodore A. Bookhout. 5th ed. Bethesda, Md.: The Wildlife Society, 1994.
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POPULATION FLUCTUATIONS Type of ecology: Population ecology The simplest realistic models of population growth produce populations that rise to some level and then stay there. These models cannot produce the complicated array of fluctuations observed in natural populations. Fluctuations vary in period from a few weeks to many decades and can reach sufficient amplitude to threaten populations (and entire species) with extinction.
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he number of organisms making up a population is never constant; it always changes over time. The populations of some species change in predictable or cyclical ways, whereas populations of other species frequently exhibit seemingly unpredictable and noncyclic changes. Fluctuations in population size may be caused by changes in the population’s environment; for example, seasonal changes in temperature or moisture produce seasonal fluctuations in population size. Resource limitations may produce density-dependent reductions in the growth rate of a population, which, if the reduction is not instantaneous, can result in oscillations in population size. Interactions with other species also produce population fluctuations; mathematical models of predator-prey systems typically produce oscillations in the abundance of both predators and prey. Finally, natural or anthropogenic disturbances often reduce the size of a population, which then either recovers its former abundance over time or declines further to local (or global) extinction. The Time Scales of Population Fluctuations Population fluctuations occur over many different time scales. On a geologic time scale (occurring over millions of years), species arise, increase to some level of abundance, and finally become extinct. These long-term patterns of species abundance provide a background for understanding population fluctuations that occur over ecological time (over days, weeks, years, or centuries). Fluctuations on these briefer time scales draw most of the attention of ecologists interested in population dynamics. Many species of animals, including numerous insects and several small vertebrates, exhibit a more or less annual life cycle, characterized by increasing numbers and higher levels of activity during the summer (or wet season) and by dormancy or decreasing numbers during the winter (or dry season). Even highly mobile animals, such as birds, exhibit a strong seasonal pattern of abundance, if viewed from a local perspective; in North 513
Population fluctuations America, for example, most songbirds migrate to more tropical latitudes in the fall and to temperate latitudes in the spring, thereby producing a yearly cycle of abundance in each location. Yearly cycles of abundance are predictable and easily explainable in terms of seasonal patterns of temperature, moisture, and sunlight. Of more interest to ecologists are population fluctuations that appear to be random or unpredictable from year to year or those fluctuations that occur out of synchrony with climatic cycles. Regular Fluctuations Nonseasonal fluctuations are of two main types: those that exhibit more or less regular cycles of abundance over several years and those that seem to fluctuate irregularly or noncyclically. A three- to four-year cycle of abundance is characteristic of several species of mice, voles, and other rodents found in far northern latitudes. Probably the best-known example of this type of cycle is that observed in lemming species in the northern tundra of Europe and North America. Lemming populations exhibit very high densities every three to four years, with such low densities in the intervening years that they are difficult to locate and study. This boom-or-bust cycle is apparently caused by alternating selection regimes. When lemmings are rare, high reproductive capacity and nonaggressive social behavior are favored, and the population grows rapidly. As the growing population becomes more crowded, aggressive individuals are favored, because they can hold territories, secure mates, and protect offspring better than passive individuals. The aggressive interactions, however, inhibit reproductive capacity, increase mortality attributable to fighting and infanticide, and expose more lemmings to predation as subordinate individuals are forced by dominants to occupy more marginal habitats. The behavioral changes that occur in response to crowding apparently persist for some time even as the density declines, so that aggressive interactions and a depressed birthrate continue until the lemming population reaches very low levels. Finally, passive individuals with high reproductive rates are again favored, and the cycle repeats. Although the breeding cycles of many predators, including snowy owls, weasels, and foxes, are tied to lemming abundance, it appears that the regular fluctuation of lemming populations is a product of crowding and resource limitation rather than of a classical predator-prey cycle; that is, there is no tight coupling between the population fluctuations of lemmings and those of their predators. There is, however, a tight coupling between the population cycles of the snowshoe hare and the Canadian lynx. Beginning in 1800, the Hudson’s Bay Company kept records of furs produced each year. Both the hare and the lynx showed a regular ten-year 514
Population fluctuations cycle, with the peaks in lynx abundance occurring about a year behind the hare’s peak abundances. Since the hare is a major food source for the lynx in northern Canada, it is logical to assume that this is a coupled oscillation of population sizes, precisely as predicted by classical predator-prey theory. Some regular cycles of abundance appear to have evolved as a means of avoiding predation rather than being a direct reduction caused by predation. There is a periodicity in the populations of cicadas and locusts. The hypothesized explanation is that predators cannot reproduce rapidly enough to increase their population sizes quickly in response to the sudden availability of a large food supply. When millions of adult cicadas appear above ground for a few weeks after surviving for seventeen years as nymphs in the soil, predators cannot possibly consume them all: No predator could specialize on adult cicadas unless it also had a seventeenyear cycle. Several northern bird populations (such as crossbills, grosbeaks, and waxwings) fluctuate dramatically, in some years rising to several times their usual levels. This fluctuation may be a response to changing habitat quality. These bird populations always produce as many eggs as food availability and their natural fecundity allow, even though many offspring will not survive. In a good year, a higher proportion of the offspring survives, and the population experiences an irruption, often leading to intense competition and consequent expansion of the range of the population. In subsequent years, population size returns to preirruption levels. Thus, these fluctuations are entirely consistent with normal density-dependent processes responding to a fluctuating environment. Irregular Fluctuations Population fluctuations that occur irregularly or noncyclically often appear to be responses to natural disturbances rather than to density-dependent processes or predator-prey relationships. For example, blue grouse persists at a relatively low level of abundance in coniferous forests until a fire occurs. The species rapidly increases in number following a fire and gradually diminishes again as the forest regenerates over the next several decades. The population fluctuations of some species are not easily attributed to disturbance or to any other single cause. For example, swarming locusts typically remain at low abundance in a restricted area for several years; then, apparently without warning, they may increase more than a hundredfold and swarm over large areas, consuming large amounts of vegetation. The locust outbreak lasts for several years, then the population 515
Population fluctuations declines as rapidly as it initially increased. In the early part of the twentieth century, it was discovered that locusts exhibit two phases: a solitary phase, corresponding to low abundance, and a gregarious phase, corresponding to an outbreak. While it is still not known how locusts transform from one phase to another, it is clear that several stages are involved and that weather conditions seem to initiate a transformation. Moisture seems to be the most important determinant, because of its influence on nymph development and survival, on egg development, and on predator abundance, but wind and plant nitrogen levels have also been implicated. Furthermore, it appears that environmental conditions are only effective in inducing a phase transformation if a certain concentration of locusts already exists and if the existing locusts are adequately sensitive to crowding. Measuring Fluctuations There are two parts to the study of population fluctuation: detecting and measuring the pattern of the fluctuation and identifying the underlying causes of the fluctuation. In general, any method designed for measuring population size can be used repeatedly over time to detect fluctuations in the population. Reference to a specialized textbook on ecological sampling techniques is strongly recommended when using any of these methods, in order to assure validity of the sampling for subsequent statistical analysis. The mark-recapture method is commonly used with animal populations. There are many variants of this technique, but they all involve capturing and marking some number of individuals, then releasing them; after some time period appropriate to the study, a second sample is captured and the proportion of marked individuals in the second sample (those that are “recaptured”) is recorded. This proportion is used to estimate the size of the population at the time when the individuals were originally marked. The quadrat method is used primarily with plants and other sessile organisms. Plots (called quadrats) are laid out, either randomly or in some pattern; all individuals within the plots constitute a sample. Quadrats are usually square, but any regular shape may be used. The appropriate size of each quadrat depends on the sizes of organisms to be sampled and on their spatial distribution. If nondestructive sampling techniques are used, the same quadrats may be sampled repeatedly; otherwise, new quadrats must be established for each sampling episode. A variety of plotless techniques are available for sessile organisms, in lieu of the quadrat method. These techniques were developed to eliminate some of the uncertainties associated with selecting proper quadrat size 516
Population fluctuations and location. Most plotless methods locate points on the ground, then measure distances to nearby organisms; each plotless technique identifies the individuals to be measured in a slightly different way. None of these techniques is adequate by itself to identify the origin or cause of any fluctuation in population size. Experimental manipulation of a population is necessary to elucidate the underlying mechanisms and determining factors. Populations of small, rapidly reproducing species (such as species of Paramecium or Daphnia) can be manipulated in the laboratory, and hypothesized causes of fluctuation can be tested under controlled conditions. This has been done primarily to develop theoretical predictions regarding environmental conditions (such as temperature, moisture, and humidity), resource limitations and fluctuations, and the effects of predators and competitors. Identifying Causes of Fluctuation The most interesting examples of population fluctuation, however, occur over spatial and temporal scales too large to handle in the laboratory. Their underlying mechanisms must be elucidated in the field. Because suites of factors typically produce the complex patterns of population fluctuation observed in nature, an effective field study must include all relevant factors. Generally, the most effective studies have been those that have sought to understand the complete life history of a species. Superb examples include the long-term studies of the wolves of Isle Royal National Park, by David Mech and colleagues, and the equally ambitious studies of the grizzly bears of Yellowstone National Park and surrounding areas by Frank and John Craighead and their many coworkers. Most equilibrium models of population dynamics are capable of producing regular oscillations that mimic the patterns observed in nature. If the model parameters are properly manipulated, many of these models can produce apparently random fluctuation. More sophisticated models have been constructed that incorporate a mathematical equivalent of random environmental fluctuation, although they usually still assume that a population has a tendency to stabilize and that environmental change simply prevents stabilization. The underlying assumption of almost all these models is that species normally exist at equilibrium. This assumption is consistent with the long-held belief that there is a “balance of nature”— that species exist in harmony with their environment. If an entire species is considered, perhaps the assumption of equilibrium is warranted, at least for extended periods; yet at the level of the population, fluctuation is the rule—indeed, it may be that extreme fluctuation is the rule. As noted earlier, many populations fluctuate so markedly that 517
Population fluctuations they often disappear; they are reestablished only by colonization from large populations within dispersal range. If populations become too small or too isolated from one another, this colonization cannot occur. Additionally, because small populations are more subject to extinction associated with fluctuation, there is additional risk of species extinction if only small populations remain. The problem of extinction is severe, since habitat destruction is occurring at an unprecedented rate on a global scale. The fragments of intact habitat that remain because of inaccessibility or preservation efforts contain populations that are smaller and more isolated than in the past. If an isolated population fluctuates markedly, resulting in its extinction from a habitat fragment, its replacement by recolonization is unlikely. Furthermore, the genetic variation maintained by a complex population structure within a species is reduced. As the genetic variation within a species is lost, the ability of a species to respond to environmental change is reduced, and extinction of the species is more likely. Ultimately, if populations normally fluctuate severely enough that they can be expected to become extinct at frequent intervals, then effective conservation requires the maintenance of pathways for exchange and dispersal of individuals among populations within a species. It also requires the preservation of the largest population size possible to allow for normal fluctuation without extinction. Alan D. Copsey See also: Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Demographics; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Human population growth; Nonrandom mating, genetic drift, and mutation; Population analysis; Population genetics; Population growth; Reproductive strategies; Speciation; Species loss. Sources for Further Study Begon, Michael, Martin Mortimer, and David J. Thompson. Population Ecology: A Unified Study of Animals and Plants. 3d ed. Cambridge, Mass.: Blackwell Science, 1996. Gotelli, Nicholas J. A Primer of Ecology. 3d ed. Sunderland, Mass.: Sinauer Associates, 2001. Krebs, Charles J. Ecology: The Experimental Analysis of Distribution and Abundance. 4th ed. New York: HarperCollins College Publishers, 1994. Krebs, Charles J., and J. H. Myers. “Population Cycles in Small Mammals.” Advances in Ecological Research 8, 1974): 267-399. 518
Population fluctuations Mech, L. David. The Wolf: The Ecology and Behavior of an Endangered Species. Garden City, N.Y.: Doubleday, 1970. Smith, Robert Leo. Elements of Ecology. 4th ed. San Francisco: Benjamin/ Cummings, 2000. Wohrmann, K., and S. K. Jain, eds. Population Biology: Ecological and Evolutionary Viewpoints. New York: Springer-Verlag, 1990.
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POPULATION GENETICS Type of ecology: Population ecology Population genetics is the analysis of genes and genetic traits in populations to determine how much variability exists, what maintains the variability, how selection (natural or controlled) affects a population, and what the mechanisms of evolution are.
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lassical genetics deals with the rules of genetic transmission from parents to offspring, developmental genetics deals with the role of genes in development, and molecular genetics looks at the molecular basis of genetic phenomena. Population genetics uses information from all three fields and helps explain why populations are so variable, why some harmful traits are common, why most animals and plants reproduce sexually, how evolution works, why some animals are altruistic in a cutthroat world, and how new species arise. Mutations and Natural Selection Simple observation reveals that animals are highly variable. Some dogs are big, others small; some wiry, others big boned; some long-haired, others curly; some with special talents such as herding or retrieving, others with none; and some with diseases or defects, others normal. All of these are the result of various genes combined with environmental influences. Unless an animal is an identical twin, no one else shares that individual’s genotype and no one ever will. Population genetics looks at variability in a population and examines its sources and the forces that maintain it. Variability can come from genetic mutations. For example, about one child in ten thousand is born with dominant achondroplasia (short-legged dwarfism). Some children with the trait inherit the condition from an affected parent, but most have normal parents. They are therefore the result of a new mutation. Many mutations are deleterious and are eventually eliminated from the population by the lowered survival or fertility rates of those who have the mutation, but while they remain in the population, they add to its variability. Occasionally, a seemingly harmful mutation persists, for example, the gene that causes sickle-cell disease, a severe disease characterized by red blood cells that become sickle shaped in certain laboratory tests. The causative gene is recessive, meaning that two copies are needed to produce the anemia, but the disease is very common in some parts of Africa. The harmful, anemia-causing gene persists in the popula520
Population genetics tion because if a person has only one gene with the trait rather than two, that gene confers resistance to malaria, the major cause of debility in that part of the world. Although the genes in these two examples have large and conspicuous effects, the great majority of mutations and the great bulk of genetic variability in the population are the result of a large number of genes with individually small effects, often detected only through statistics. The variability of quantitative traits such as size is due mainly to the cumulative action of many individual genes, each of which produces its small effect. The average size stays roughly constant from generation to generation because individuals who are too large or too small are at a disadvantage. However, such individuals continuously arise from new mutations. The driving force in evolution is natural selection, that is, the differential survival and fertility of different genotypes. New mutations occur continuously. Most of these are harmful, although usually only mildly so, but a small minority are beneficial. The rules of Mendelian inheritance ensure that the genes are thoroughly scrambled every generation. Natural selection acts like a sieve, retaining those genes that produce favorable phenotypes in the various combinations and rejecting others. Such a process, acting over eons of time, has produced the variety and specific adaptations that can be found throughout the animal kingdom. The Hardy-Weinberg Law and Selfish Genes Although evolutionary progress is the result of natural selection, most selection does not accomplish any systematic change. Most selection is directed at maintaining the status quo—eliminating harmful mutations, keeping up with transitory changes in the environment, and eliminating statistical outliers (extremes of variation). Most of the time, evolutionary change is very slow. In most populations, mating is essentially random in that mates do not choose each other because of the genes they carry. There are exceptions, of course, but for the most part, random mating can be assumed. This permits a great simplification known as the Hardy-Weinberg rule. This rule says that if the proportion of a certain gene, say A, in the population is p and of another, say a, is q, then the three genotypes AA, Aa, and aa are in the pro2 2 portions p , 2pq, and q , respectively. (Remember that p and q are fractions between zero and one.) This is a simple application of elementary probability and the binomial theorem. Furthermore, after a few generations of random mating, genotypes at different loci also equilibrate, which means that the frequency of a composite genotype is the product of the frequencies at the constituent loci. The reason that this is so useful is that the num521
Population genetics ber of genotypes is enormous, but a population can be characterized by a much smaller number of gene frequencies. Genotypes are transient, but genes may persist unchanged for many generations. This has led the great theorists of population genetics, J. B. S. Haldane and R. A. Fisher in England and Sewall Wright in the United States, to make the primary units the frequency of individual genes and develop theories around this concept, making free use of the simple consequences of random mating. Such a gene-centered view has been described by scholar Richard Dawkins as the “selfish gene.” A population can be thought of as a collection of genes, each of which is maximizing its chance of being passed on to future generations. This causes the population to become better adapted because those genes that improve adaptation have the best chance of being perpetuated. Kin Selection and Selfish Genes An extension of this notion is kin selection. The concept holds that, to the extent that behavior is determined by genes, individuals should be protective of close relatives because relatives share genes. The fact that brothers and sisters share half their genes should lead a brother to be half as concerned with his sister’s survival and reproduction as with his own. Many evolutionists believe that altruistic behavior in various animals, including humans, is the result of kin selection. The degree of self-sacrifice to protect a close relative is proportional to the fraction of shared genes. Parents regularly make sacrifices for their children, and this is what evolutionary theory would predict. One way in which populations depart from random mating is inbreeding, the mating of individuals more closely related than if they were randomly chosen. Related individuals share one or more ancestors, hence an inbred individual may get two copies of an ancestral gene, one through each parent. In this way, inbreeding increases the proportion of homozygotes. Because many deleterious recessive genes are hidden in the population, inbreeding can have a harmful effect by making genes homozygous. Similarly, if the population is subdivided into local units, mating mostly within themselves, these local units will be more homozygous than if the entire population mated at random. Small subpopulations will be more subject to purely random fluctuations in gene frequencies known as random genetic drifts. Therefore, subdivisions of a population often differ significantly, particularly with respect to unimportant genes. Views of Evolution: Gene-Centered vs. Genetic Drift The gene-centered view of evolution is not always accepted. Some evolu522
Population genetics tionists believe that it is simplistic to view an individual as a bag of genes, each trying to perpetuate itself. They emphasize that genes often interact in complicated ways, and that a theory that deals with only average gene effects is incomplete. Modern theories of evolution take such complications into account. This different viewpoint has led to a major controversy in evolution, one that has not yet been settled. Wright emphasized that many welladapted phenotypes depend on genes that interact in very specific ways; two or more genes may be individually harmful but when combined produce a beneficial effect. He argued that selecting genes on the basis of average effects cannot produce such combined effects. He believed that a population subdivided into many partially isolated units provides an opportunity for such interactions. An individual subpopulation, by random drift, might chance upon such a happy gene combination, in which case the whole population can be upgraded by migrants from this subpopulation. Whether evolutionary advance results from gene interactions in subpopulations, from mass selection in largely unstructured populations, or from a combination of both is a question that remains unresolved. Population genetics theory, along with the techniques of molecular genetics, has greatly deepened our knowledge of historical evolution. Most students of evolution are familiar with tree diagrams of common ancestry that show, for example, birds and mammals branching off from early ancestors. In the past these had to be constructed using external phenotypes and fossils. These techniques for measuring the relatedness of different species and determining their ancestral relations have been replaced by DNA sequencing, which produces much surer results. It has long been suspected that genes can persist for very long evolutionary periods, modifying slightly to perform new, often related but sometimes quite different functions. This belief has been confirmed repeatedly by molecular analysis. The similarity of the DNA sequences between some plant and animal genes is so great as to leave no doubt that they were both derived from a common ancestral gene a billion or more years ago. Neutral Mutation and Sexual Reproduction Most gene mutations have very small effects, and the smaller the effect, the less likely it is to be noticed. Molecular techniques have enabled scientists to detect changes in DNA without regard to the traits they cause or whether they have any effect at all. The Japanese geneticist Motoo Kimura has advanced the idea that most evolution at the DNA level is not the result of natural selection but simply the result of mutation and chance, a concept 523
Population genetics termed neutral mutation. In vertebrates, especially in mammals, most of the DNA has no known function. The functional genes make up a very small fraction of the total DNA. Many scientists believe that most DNA evolution outside the genes—and some within—is the result of changes that are so nearly neutral as to be determined by chance. How large a role random drift plays in the evolution of changes in functional proteins is still not certain. A few animals and a large number of plants reproduce asexually. Instead of reproducing by using eggs and sperm, the progeny are carbon copies of the parent. Asexual reproduction has obvious advantages. If females could reproduce without males, producing only female offspring like themselves, reproduction would be twice as efficient. However, despite its inherent inefficiency, sexual reproduction is the rule, undoubtedly because of the gene-scrambling process that sex produces. The ability of a species to produce and try out countless gene combinations confers an evolutionary advantage that outweighs the cost of males. Another advantage of gene scrambling is that it permits harmful mutations to be eliminated from the population in groups rather than individually. Population genetics is also concerned with the processes by which new species arise. Scientists believe that a population somehow becomes divided into two or more isolated groups, separated perhaps by a river, mountain range, or other geographical barrier. Each group then follows its own separate evolutionary course, and the groups’ dissimilar environments accentuate their differences. Eventually the two groups evolve so many differences that they are no longer compatible. The products of interspecies crosses, or hybrids, often do not develop normally or are sterile (like the mule). Sometimes the two species do not mate because they are so different. Research Methods Population genetics involves theory, observation, and experiment. Population genetics examines how genes are influenced by mutation, selection, population size, migration, and chance. Scientists develop mathematical models that embody these theories and compare the results obtained using the models with data from laboratory experiments or field observations. These genetic models have become more and more sophisticated to take into account complex gene interactions and increasingly realistic population structures. The models are further complicated by efforts to account for random processes. Often the mathematical geneticist relies on computers to perform complex analyses and computations. 524
Population genetics One of the simpler models, which makes the assumption that mating is random, is the Hardy-Weinberg principle. If the proportion of gene A in the population is p and that of gene a is q, then the three genotypes AA, Aa, and aa are in the proportions p2, 2pq, and q2, respectively. The proportion of Aa is 2pq rather than simply pq because this genotype represents two combinations, maternal A with paternal a and paternal A with maternal a. This principle can be used to predict the frequency of persons with malaria resistance from the incidence of sickle-cell anemia. If one-tenth of the genes are sickle-cell genes and the other nine-tenths are normal, the frequency of two genes coming together to produce an anemic child is 0.1 × 0.1, or 0.01. The frequency of those resistant to malaria, who have one normal and one sickle-cell gene, is 2 × 0.1 × 0.9, or 0.18. A slight extension of the calculation (using the rates of malaria infection and death from the disease) can be used to estimate the death rate from malaria. Another mathematical model can be formed based on the molecular genetics theory of neutral mutation. A neutral mutation, because it is not influenced by natural selection, has an expected rate of evolution that is equal to the mutation rate. Mathematical models embodying this theory are used to quantitatively predict what will happen in an experiment or what an observational study will find and act as a test of the theory. Neutral mutation theory is quite complicated and requires advanced mathematics. Observational population genetics consists of studying animals and plants in nature. Evolution rates are inferred from the fossil record. Field observations can determine the frequency of genes in different geographical areas or environments. The frequency of self- and crosspollination can often be observed directly. Increasingly, DNA analysis, which can detect relationships or alterations that are not visible, is being used to support field observations. For example, molecular markers have been used to determine parentage and relationship. DNA analysis revealed that certain birds that do not reproduce but care for the progeny of others are in fact close relatives, consistent with kin selection theory. Increasingly, population genetics has begun to rely on experimentation. Plants and animals can be used to study the process of selection, but to save time and reduce costs, most laboratory experiments involve small, rapidly reproducing organisms such as the fruit fly, Drosophila. Some of the most sensitive selection experiments have involved the use of a chemostat, a container in which a steady inflow of nutrients and steady outflow of wastes and excess population permits a population to maintain a stable number of rapidly growing organisms, usually bacteria. These permit very sensitive measurements of the effects of mutation. Evolutionary studies 525
Population genetics that would require eons if studied in large animals or even mice can be completed in a very short time. Uses of Population Genetics The greatest intellectual value of population genetics has been to provide a theory of evolution that is explanatory, quantitative, and predictive. Population genetics places knowledge of mutation, gene action, selection, inbreeding, and population structure in a unified framework. It brings together Charles Darwin’s theory of evolution by natural selection, Gregor Mendel’s laws of inheritance, and molecular genetics to create a coherent picture of how evolution took place and is still occurring. Population genetics has provided explanations for variability in a population, the prevalence of sexual rather than asexual reproduction, the origin of new species, and behavioral traits such as altruism. It has also provided an understanding of why some harmful diseases are found in the population. Population genetics has been used in animal and plant breeding to create rational selection programs. Using quantitative models, the results of various selection schemes can be compared and the best one chosen. A particularly telling example of a situation in which population genetics predicted an outcome that has become painfully obvious is the development of resistance to insecticides, herbicides, and antibiotics. As people used these products more and more, the insects, weeds, and bacteria they were trying to eliminate developed resistance, and new products had to be developed to replace those rendered ineffective. The development of resistance represents evolution by natural selection that took place not over hundreds or thousands of years but in just a few years. Probably the most problematic area of resistance is antibiotics because some treatable diseases are again threatening to become beyond the ability of medicine to cure. A major challenge to ecologists, microbiologists, physicians, and population geneticists is how to deal with the increasingly difficult problem of disease-producing microorganisms that are resistant to antibiotics. James F. Crow See also: Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Demographics; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Human population growth; Nonrandom mating, genetic drift, and mutation; Population analysis; Population fluctuations; Population growth; Reproductive strategies; Speciation; Species loss. 526
Population genetics Sources for Further Study Crow, James F. Basic Concepts in Population, Quantitative, and Evolutionary Genetics. New York: W. H. Freeman, 1986. Dawkins, Richard. The Blind Watchmaker. New York: W. W. Norton, 1986. _______. The Selfish Gene. Rev. ed. Oxford, England: Oxford University Press, 1999. Falconer, Douglas S. Introduction to Quantitative Genetics. 4th ed. New York: John Wiley & Sons, 1996. Fisher, R. A. The Genetical Theory of Natural Selection. Rev. ed. New York: Dover, 1958. Haldane, J. B. S. The Causes of Evolution. Reprint. Ithaca, N.Y.: Cornell University Press, 1993. Hartl, Daniel. A Primer of Population Genetics. 3d ed. Sunderland, Mass.: Sinauer Associates, 2000. Hartl, Daniel, and Andrew Clark. Principles of Population Genetics. 3d ed. Sunderland, Mass.: Sinauer Associates, 1997. Kimura, Motoo. The Neutral Theory of Molecular Evolution. Cambridge, England: Cambridge University Press, 1985. Maynard Smith, John. The Theory of Evolution. Cambridge, England: Cambridge University Press, 1993. Wright, Sewall. Evolution and the Genetics of Populations. 4 vols. Chicago: University of Chicago Press, 1968-1978.
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POPULATION GROWTH Type of ecology: Population ecology Populations typically grow when they are found on sites with abundant resources, and biologists have developed two models to describe growth. In exponential growth, the population is exposed to ideal conditions, and new individuals are added at an ever-increasing rate. Logistic growth recognizes that resources are eventually depleted, however, and that the population density ultimately stabilizes at some level, which is defined as the carrying capacity.
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n nature, organisms of a particular species rarely occur by themselves. Instead, they usually exist with other individuals of the same species. Biologists use the term “population” to refer to an aggregation of organisms of a given species that live in the same general location at the same time. In some cases, populations can be well defined, such as herds of cattle or flocks of geese. In other cases, the population is not well defined, often because several species may be found in the same location. For example, a meadow may contain intermingled populations of several species, including daisies, timothy grass, earthworms, and grasshoppers. Biologists have studied populations for many years. Many of those studies have been conducted to answer three separate but interrelated questions. First, how many individuals are there in a given population at a particular time? Second, how do those numbers change from one time to another? Third, what environmental factors are responsible for any population increases or decreases? Studies have shown that for most species of plants, animals, and microbes, the number of individuals in the population changes over time. Some populations increase steadily, other populations decrease, and still others fluctuate. Thus, populations, when viewed over time, are generally dynamic rather than static. Population Behaviors Most populations change so much through time because there is constantly turnover among individuals. That is, new individuals are constantly being born, hatched, or germinated, while others die. Moreover, animals are also able to enter a population by immigration and leave by emigration. Since the number of births and new immigrants hardly ever exactly matches the number of deaths and emigrants, the dynamic nature of populations should not be a surprise. Because changes in population size are common in nature, biologists have tried to understand the changes that are ob528
Population growth served. One approach has been to model populations; the model is a simplified graphical or mathematical summary of the actual changes that are occurring in the species of interest. The relationship between a model and the actual population that it represents is similar to that between a map and the area of land that it represents. Because modeling is such an important aspect of population biology, biologists who study population must often have a good background in mathematics. Perhaps the simplest mode of population behavior is the difference equation, which states that the number of individuals in a population at some specified time in the future is equal to the number at present, plus the number of births, minus the number of deaths, plus the number of new immigrants, minus the number of emigrants. Thus, by knowing how many individuals are on a site at a given time and knowing the usual number of births, deaths, immigrants, and emigrants, one can predict the number of individuals on the site at some future time. Obviously, the number of births, deaths, immigrants, and emigrants will vary from one place to another and from one time to another. For example, on a site with abundant food and space and with favorable physical conditions for growth and development, births and immigration will be much greater than deaths and emigration. Thus, the population will increase. Conversely, if food or space is limiting or if the physical conditions are more severe, losses to the population through death and emigration will equal or exceed gains through birth and immigration. Thus, the population will remain constant or decline. Biologists often are concerned about what happens in extreme conditions, because such conditions define the limits within which the population normally operates. When conditions are very bad, a population normally declines rapidly, often to the point of local extinction; when conditions are very good, a population will increase. That increase is attributable to the fact that each individual normally has the capacity to produce many offspring during its lifetime. For example, a woman could produce more than forty children if she conceived every time that she was fertile. Other individual organisms, particularly many invertebrates and plants, can produce hundreds of thousands of offspring in their lifetime. Birth and Death Rates At least three different traits influence the reproductive output of a given species. The first is the number of offspring per reproductive period (elephants produce only one child at a time, whereas flies can lay thousands of eggs). The second is the age at first reproduction (most dogs can reproduce when less than three years old, whereas humans do not usually become 529
Population growth fertile until they reach an age of thirteen or fourteen). The third is the number of times that an individual reproduces in its lifetime (salmon spawn, that is, lay eggs, only once before they die, whereas chickens lay eggs repeatedly). Even under ideal conditions, death must also be considered when examining population growth. Nearly all organisms have a maximum life span that is determined by their innate physiology and cannot be exceeded, even if they are supplied with abundant food and kept free from disease. Population biologists frequently express birth and death in the form of rates. This can be done by counting the number of new births and deaths in a population during a predetermined period of time and then dividing by the number of individuals in the population. That will give the per capita (per individual) birth and death rates. For example, suppose that during the course of a year there were thirty births and fifteen deaths in a population of one thousand individuals. That per capita birthrate would be 0.030 and the per capita death rate would be 0.015. Next, one can subtract the death rate from the birthrate to find the per capita rate of population growth. That rate should be greatest under ideal conditions, when the birthrate is greatest and the death rate is least. That per capita rate of population growth is called the “maximal intrinsic rate of increase” or the “biotic potential” by population biologists, and it is a very important attribute. It is often symbolized as rmax or referred to as “little r.” Normally, rmax is considered an inherent feature of a species. As one might expect, it varies greatly among different types of organisms. For example, rmax, expressed per year, is 0.02-1.5 for birds and large mammals, 4-50 for insects and small invertebrates, and as high as 20,000 for bacteria. Exponential Growth By knowing the intrinsic rate of increase and the number of organisms in a population, one can predict much about the behavior of a population under ideal conditions. The rate at which the population grows is merely the intrinsic rate of increase (rmax) multiplied by the number of individuals in the population. For example, suppose that there are ten individuals in a population whose annual rmax is 2. That population would increase by an annual rate of twenty (which would be a healthy increase). Next, suppose that one returned to that population at some later time when the population was fifty individuals. At that point, the annual rate of population increase would be one hundred new individuals (which would be an even healthier increase). If the rate of increase were measured when the population reached five hundred, the annual rate of increase would be one thousand individuals. 530
Population growth Under such circumstances, the population would keep on growing at an ever-increasing rate. That type of growth is called “exponential growth” by population biologists, and it typifies the behavior of many populations when placed under ideal conditions. If the number of individuals in a population undergoing exponential growth is plotted as a function of time, the curve would resemble the letter J. That is, it would be somewhat flat initially, but it would curve upward, and at some point it would be almost vertical. Exponential population growth has been observed to a limited extent in many different kinds of organisms, both in the laboratory and under field conditions. Examples include protozoans, small insects, and birds. It should be obvious, however, that no species could behave in this manner for long. If it did, it would overrun the earth (and indeed the universe) in a matter of time. Instead, population growth is slowed by limited resources, accumulated wastes, behavioral stresses, and/or periodic catastrophes caused by the environment. Logistic Growth Biologists have created a second model to account for the behavior of populations under finite resources and have called it logistic growth. If the number of individuals in a population undergoing logistic growth is plotted as a function of time, the curve would resemble a flattened S shape. In other words, the curve would initially be flat, but would then curve upward at a progressively faster rate, much like exponential growth. At some point (called the inflection point), however, the curve would begin to turn to the right and flatten out. Ultimately, the curve would become horizontal, indicating a constant population over time. An important aspect of pure logistic growth is that the population approaches, but does not exceed, a certain level. That level is called the carrying capacity, and is represented by the symbol K in most mathematical treatments of logistic growth. The carrying capacity is the maximum number of individuals that the environment can support, based on the space, food, and other resources available. When the number of individuals is much fewer than the carrying capacity, the population grows rapidly, much as in exponential growth. As the number increases, however, the rate of population growth becomes much less than the exponential rate. When the number approaches the carrying capacity, new population growth virtually ceases. If the population were to increase above the carrying capacity for some reason, there would be a net loss of organisms from the population. There are few studies that have documented logistic growth in nature. It would be necessary to watch a species in a habitat from the time of its first 531
Population growth introduction until its population stabilized. Such studies are necessarily of a very long duration and thus are not normally conducted. Logistic growth has been found in a number of experimental studies, however, particularly on small organisms, including protozoans, fruit flies, and beetles. An important aspect of logistic growth is that, as the population increases, the birthrate decreases and the mortality rate increases. Such effects may be attributable to reduced space within which the organism can operate, to less food and other resources, to physiological and behavioral stress caused by crowding, and to increased incidence of disease. Those factors are commonly designated as being density-dependent. They are considered much different from the density-independent factors that typically arise from environmental catastrophes such as flooding, drought, fire, or extreme temperatures. For many years, biologists argued about the relative importance of density-dependent versus density-independent factors in controlling population size. It is now recognized that some species are controlled by density-independent factors, whereas others are controlled by density-dependent factors. Classically, when a species undergoes logistic growth, the population is ultimately supposed to stabilize at the carrying capacity. Most studies that track populations over the course of time, however, find that numbers actually fluctuate. How can such variability be reconciled with the logistic model? On the one hand, the fluctuations may be caused by densityindependent factors, and the logistic equation therefore does not apply. On the other hand, the population may be under density-dependent control, and the logistic model can still hold despite the fluctuations. One explanation for the fluctuations could be that the carrying capacity itself changes over time. For example, a sudden increase in the amount of food available would increase the carrying capacity and allow the population to grow. A second explanation relates to the presence of time lags. That is, a population might not respond immediately to a given resource level. For example, two animals in a rapidly expanding population might mate when the number of individuals is less than the carrying capacity. The progeny, however, might be born several weeks or months later, into a situation in which the population has exceeded the carrying capacity. Thus, there would have to be a decline, leading to the fluctuation. Approaches to Studying Population Growth Two main approaches can be used to investigate logistic and exponential population growth among organisms. One approach involves following natural populations in the field; the other involves setting up experimental populations. Each approach has its benefits and drawbacks, and, ideally, 532
Population growth both should be employed. To study population growth in the field, it is important to study a species from the time that it first arrives on a site until its population stabilizes. Thus, any species already present are automatically eliminated from consideration unless they are brought to local extinction and a new population is then allowed to recolonize. Population growth studies can be profitably done on sites that are very disturbed and are beginning to fill up with organisms. Examples would be an abandoned farm field or strip mine, a newly created volcanic island, or a new body of water. Moreover, studies could also be done on a species that is purposely introduced to a new site. In either case, one needs to survey the population periodically to assess the number of individuals that it contains. The size of the population can be determined directly or by employing sampling techniques such as mark-recapture methodology. The number of individuals can then be plotted on a graph (on the y-axis) as a function of time (on the x-axis). To study population growth in experimental conditions, one sets up an artificial habitat according to the needs of the species in question. For example, investigators have examined population growth in protozoans (unicellular animals) by growing populations in test tubes filled with food dissolved in a known volume of water. Others have grown fruit flies in stoppered flasks. Still others have grown beetles in containers filled with oatmeal or other crushed grain. In those cases, it was typically necessary to replenish the food to keep the population going. Whenever the population was placed into an artificial habitat with a nonrenewable food source, it would generally consume all the food and then die out. More detailed experiments can be performed to test whether densitydependent mortality is occurring. Such experiments would involve setting up a series of containers with different densities of organisms and then following the mortality of those organisms. In theory, mortality rates should be highest in containers that have the greatest densities of organisms and lowest in containers with the sparsest populations. One could also examine the birthrate in those containers, with the expectation that birthrates should be highest in the sparsest containers and lowest in those that have the most organisms. The investigation should be long enough to allow the population to reach equilibrium at the carrying capacity. For short-lived organisms such as protozoans or insects, that could take days, weeks, or months. For longer-lived organisms such as fish or small mammals, one to several years may be required. For long-lived animals, a truly adequate study may take decades. Another consideration in studying exponential and logistic population growth is that immigration and emigration should be kept to a minimum. 533
Population growth Thus, organisms that are highly active, such as birds, large mammals, and most flying insects would be extremely difficult to study. Finally, one can set up numerous populations and expose each to a slightly different set of conditions. That would enable the researcher to ascertain which environmental factors are most important in determining the carrying capacity. For example, populations of aquatic invertebrates could be monitored under a range of temperature, salinity, pH, and nutrient conditions. Research Applications Since exponential growth is unrealistic in practical terms for almost all populations, its scientific usefulness is limited. The concepts derived from logistic growth, however, have important implications to biologists and nonbiologists alike. One important aspect of logistic growth is that the maximum rate of population growth occurs when the population is about half of the environment’s carrying capacity. When populations are very sparse, there are simply too few individuals to produce many progeny. When populations are dense, near the carrying capacity, there is not enough room or other resources to allow for rapid population growth. Based on that relationship, those who must harvest organisms can do so at a rate that allows the population to reestablish quickly. Those who can apply this concept in their everyday work include wildlife managers, ranchers, and fishermen. Indeed, quotas for hunting and fishing are often set in a way that allows for the population to be thinned sufficiently without depleting it too severely. Unfortunately, there are two problems that biologists must confront when they try to use the logistic model to help manage populations. The first is that it is often difficult to establish the carrying capacity for a given species on a particular site. One reason is that the populations of many species are profoundly affected by density-independent factors, as well as by other species, in highly complex and variable ways. Further, for reasons unclear to most biologists, some species have a maximum rate of population growth at levels well above or well below the level (one half of the carrying capacity) that is normally assumed. Thus, the logistic model typically gives only a very rough approximation for the ideal size of a population. However, the logistic model is useful because it emphasizes that all species have natural limits to the sizes of their populations. Kenneth M. Klemow See also: Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Demographics; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Human population growth; Nonran534
Population growth dom mating, genetic drift, and mutation; Population analysis; Population fluctuations; Population genetics; Reproductive strategies; Speciation; Species loss. Sources for Further Study Brewer, Richard. The Science of Ecology. 2d ed. Philadelphia: Saunders College Publishing, 1994. Elseth, Gerald D., and Kandy D. Baumgardner. Population Biology. New York: Van Nostrand, 1981. Gotelli, Nicholas J. A Primer of Ecology. 3d ed. Sunderland, Mass.: Sinauer Associates, 2001. Hutchinson, G. Evelyn. An Introduction to Population Ecology. New Haven, Conn.: Yale University Press, 1978. Kormondy, Edward J. Concepts of Ecology. 4th ed. Englewood Cliffs, N.J.: Prentice-Hall, 1996. Krebs, Charles J. Ecology: The Experimental Analysis of Distribution and Abundance. 5th ed. San Francisco: Benjamin/Cummings, 2001. Raven, Peter, H., and George B. Johnson. Biology. 5th ed. St. Louis: Times Mirror/Mosby, 1999. Wilson, Edward O., and William Bossert. A Primer of Population Biology. Sunderland, Mass.: Sinauer Associates, 1977.
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PREDATION Type of ecology: Behavioral ecology The relationships among predators and their prey in natural communities are varied and complex. These interactions provide clues as to how natural populations regulate one another, as well as to how to preserve and manage exploited populations more successfully.
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redation is an interaction between two organisms in which one of them, the predator, derives nutrition by killing and eating the other, the prey. Obvious examples include lions feeding on zebras and hawks eating rodents, but predation is not limited to interactions among animals. Birds that feed on seeds are legitimate predators since they are killing individual organisms (embryonic plants) to derive energy. There are a number of species of carnivorous plants, such as sundews and pitcher plants, that capture and consume small animals to obtain nitrogen in habitats that otherwise lack sufficient quantities of that nutrient. Most animals that feed on plants (herbivores) do not kill the entire plant and therefore are not really predators. Exceptions to this generalization are some insects that reach infestation levels, such as gypsy moths or locusts, and can kill the plants upon which they feed. The majority of herbivore-plant associations, however, are more properly described as parasite-host interactions in which the host plant may suffer damage but does not die. There are special cases in which parasitism and predation may be combined. One of these is the interaction between parasitoid wasps and their hosts, usually flies. Adult female parasitoids attack and inject eggs into fly pupae (the resting stage, during which fly larvae metamorphose into adults), and the larvae of the wasp consume the fly. The adult parasitoid is therefore a parasite, while the larval wasp acts as a predator. Predator-Prey Interactions Predator-prey interactions can be divided into two considerations: the effects of prey on predators, and the effects of predators on their prey. Predators respond to changes in prey density (the number of prey in the habitat) in two principal ways. The first is called numerical response, which means that predators change their numbers in response to changes in prey density. This may be accomplished by increasing or decreasing reproduction or by immigrating to or emigrating from a habitat. If prey density increases, predators may immigrate from other habitats to take advantage of 536
Predation this increased resource, or those predators already present may produce more offspring. When prey density decreases, the opposite will occur. Some predators, which are known as fugitive species, are specialized at finding habitats with abundant prey, migrating to them, and reproducing rapidly once they are established. Cape May warblers are good at finding high densities of spruce budworms (a serious pest of conifers) and then converting the energy from their prey into offspring. This strategy allows the birds to persist only because the budworms are never completely wiped out; they are better at dispersing to new habitats than are the birds. The second response of predators to changing prey density is called functional response. The rate at which predators capture and consume prey depends upon the rate at which they encounter prey, which is a function of prey density. If the predator has a choice of several prey species, it may learn to prefer one of them. If that prey is sufficiently abundant, this situation results in a phenomenon known as switching, the concentration by the predator on the preferred prey. It may entail a change in searching behavior on the part of the predator, such that former prey items will no longer be encountered as frequently. Animals have evolved a number of defense mechanisms that reduce their probability of being eaten by predators. Spines on horned lizards,
A hungry bear nabs a salmon for lunch as the fish hurls itself upstream to spawn. (Corbis) 537
Predation threatening displays by harmless snakes, camouflage of many cryptic animals, toxic or distasteful chemicals in insects and amphibians, and simply rapid movement—all are adaptations that may have evolved in response to natural selection by predators. A predator that can learn to prefer one prey item over another is smart enough to learn to avoid less desirable prey. That capability is the basis for a phenomenon known as aposematism among potential prey species which are toxic and/or distasteful to their predators. Aposematic organisms advertise their toxicity by bright coloration, making it easy for predators to learn to avoid them, which in turn saves the prey population from frequent taste-testing. Many species of insects are aposematic. Monarch butterflies are bright orange with black stripes, an easy signal to recognize. They owe their toxicity to the milkweed plant, which they eat as caterpillars. The plant contains cardiac glycosides, which are very toxic. The monarch caterpillar is immune to the poison and stores it in its body so that the adult has a high concentration of it in its wings. If a bird grabs the butterfly in flight, it is likely to get a piece of wing first, and this will teach it not to try orange butterflies in the future. Some potential prey species that are not themselves toxic have evolved to resemble those that are; these are called Batesian mimics. Viceroy butterflies, which are not toxic, mimic monarchs very closely, so that birds cannot tell them apart. One limit to Batesian mimicry is that mimics can never get very numerous, or their predators will not get a strong enough message to leave them alone. Another kind of mimicry involves mimics that are as toxic as their models. The advantage with this type, Müllerian mimicry, is that the predator has to learn only one coloration signal, which reduces risk for both prey populations. In this relationship, the mimic population does not have to remain at low levels relative to the model population. A third type of mimicry is more insidious—aggressive mimicry, in which a predator resembles a prey or the resource of that prey in order to lure it close enough to capture. There are tropical praying mantises that closely resemble orchid flowers, thus attracting the bees upon which they prey. There are some species of fireflies that eat other species of fireflies, using the flashing light signal of their prey to lure them within range. The Choice of Prey What determines predator preference for prey? Since prey are a source of energy for the predator, it might be expected that predators would simply attack the largest prey they could handle. To an extent, this choice holds true for many predators, but there is a cost to be considered. The cost involves the energy a predator must expend to search for, capture, handle, 538
Predation and consume prey. In order to be profitable, a prey item must yield much more energy than it costs. Natural selection should favor reduction in energetic cost relative to energetic gain, the basis for optimal foraging theory. According to this theory, many predators have evolved hunting strategies to optimize the time and energy spent in searching for and capturing prey. Some predators, such as web-building spiders and boa constrictors, ambush their prey. The low energetic cost of sit-and-wait is an advantage in environments that provide plentiful prey. If encounters with prey become less predictably reliable, however, an ambush predator may experience starvation. Spiders can lower their metabolic energy requirements when prey is unavailable, whereas more mobile predators, such as boa constrictors, can simply shift to active searching. Probably because of the likelihood of facing starvation for extended periods of time, ambush predation is more common among animals that do not expend metabolic energy to regulate their body temperatures (ectotherms) than among those that do (endotherms). Some predators, such as wolves and lions, hunt in groups. This allows them to tackle larger (more profitable) prey than if they hunted alone. Solitary hunters generally have to hunt smaller prey. Natural communities consist of food webs, constructed of links (feeding relationships) among trophic levels. Each prey species is linked to one or more predators. Most predators in nature are generalists with respect to their prey. Spiders, snakes, hawks, lions, and wolves all feed on a variety of prey. Some of these prey are herbivores, but some are themselves predators. Praying mantises eat grasshoppers (herbivores), but they also eat spiders (carnivores) and each other. Thus, generalist predators have a bitrophic niche, in that they occupy two trophic levels at the same time. Predation and Population Fluctuation It is an open question whether predators and prey commonly regulate each other’s numbers in nature. There are many examples of cyclic changes in abundance over time, in which an increase in prey density is followed by an increase in the numbers of predators, and then the availability of prey decreases, also followed by a decrease in predators. Are predators causing their prey to fluctuate, or are prey responding to some other environmental factor, such as food supply? In the second case, prey may be regulated by food, and in turn, may be regulating predators, but not the reverse. Predators can sometimes determine the number of prey species that can coexist in a habitat. If a predator feeds on a prey species that could outcompete (competitively exclude) other prey species in a habitat, it may free more resources for those other species. This relationship is known as the keystone effect. Empirical studies have indicated that the number of 539
Predation
Although rare, plant predators exist. This “carnivorous” pitcher plant is formed with a hollow, tubular structure that contains fluid to trap small animals and insects to obtain nitrogen in habitats that otherwise lack sufficient quantities of that nutrient. (Digital Stock)
prey species in some communities is directly related to the intensity of predation (numerical and functional responses of predators) such that at low intensity, few species coexist because of competitive exclusion; at intermediate intensity, the diversity of the prey community is greatest; and at high intensity, diversity decreases because overgrazing begins to eliminate species. This intermediate predation hypothesis depends upon competition among prey species, which is not always the case. Studying Predation The central question in the study of predation is: To what extend do predators and their prey regulate one another? Most studies suggest that predators are usually food limited, but the extent to which they regulate their prey is uncertain. It is one thing to observe predators in nature and another to assess their importance to the dynamics of natural communities. Like other aspects of ecology, studies of predation can be descriptive, experimental, and/or mathematical. At the descriptive level, characteristics of both predator and prey populations are assessed: rates of birth and mortality, age structure, environmental requirements, and behavioral traits. Qualitative and quantitative information of this type is necessary before predictions can be made about 540
Predation the interactions between predator and prey populations. General lack of such information in natural ecosystems is largely responsible for failures at biological control of pests and management of exploited populations. Experimental studies of predation involve manipulation of predator and/or prey populations. A powerful method of testing the importance of predation is to exclude a predator from portions of its accustomed habitat, leaving other portions intact as experimental controls. In one such experiment, excluding starfish from marine intertidal communities of sessile invertebrates resulted in domination by mussels and exclusion of barnacles and other attached species; in the absence of the predator, one prey species was capable of competitively excluding others. This keystone effect depends upon two factors—that the prey assemblage structure is determined by competition and that the predator preferentially feeds on the species that is the best competitor in the assemblage. Clearly, not all food webs are likely to be structured in this way. Another method of experimental manipulation is to enhance the numbers of predators in a community. For complex natural communities, both additions and exclusions of predators have revealed direct (depression of prey) and indirect (enhancement) effects. Since generalist predators are bitrophic in nature, they may interact with other carnivores in such a way as to enhance the survival of herbivores that normally would fall victim. In one experiment, adding praying mantises to an insect community resulted in a decrease in spiders and a consequent increase in aphids, normally eaten by these spiders. Such results are not uncommon and contribute to the uncertainty of prediction. Mathematical models have been constructed to depict predator-prey interactions in terms of how each population affects the growth of the other. The simplest of these models, known as the Lotka-Volterra model for the mathematicians who developed it, describes a situation in which prey and predator populations are assumed to be mutually regulating. This model, which was developed for a single prey population and single predator species, has been modified by many workers to provide more realism, but it is far from predicting many competitive situations in complex natural communities. As with the rest of modern ecology, these different approaches must be blended in order to build a robust picture of how important predators are in natural ecosystems. This knowledge would allow more successful prediction of the outcomes of human intervention and more intelligent management of exploited populations. Predation is a key interaction in natural ecosystems; understanding the nature of this interaction is central to any understanding of nature itself. Lawrence E. Hurd 541
Predation See also: Balance of nature; Camouflage; Defense mechanisms; Displays; Ethology; Food chains and webs; Hierarchies; Mammalian social systems; Mimicry; Omnivores; Pheromones; Poisonous animals; Territoriality and aggression. Sources for Further Study Crawley, M. J., ed. Natural Enemies: The Population Biology of Predators, Parasites, and Diseases. Boston: Blackwell Scientific Publications, 1992. Ehrlich, Paul R., and Anne H. Ehrlich. Extinction: The Causes and Consequences of the Disappearance of Species. New York: Random House, 1981. Fabre, Jean Henri. The Life of the Spider. Translated by Alexander Teixeira de Mattos. New York: Dodd, Mead, 1916. Gause, G. F. The Struggle for Existence. Reprint. New York: Dover, 1971. Hassell, Michael P. Arthropod Predator-Prey Systems. Princeton, N.J.: Princeton University Press, 1978. Krebs, J. R., and N. B. Davies, eds. Behavioral Ecology: An Evolutionary Approach. 4th ed. Boston: Blackwell Scientific Publications, 1997. Levy, Charles Kingston. Evolutionary Wars: A Three-Billion Years Arms Race. New York: Basingstoke, 2000. Mowat, Farley. Never Cry Wolf. Boston: Atlantic-Little, Brown, 1963.
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PUNCTUATED EQUILIBRIUM VS. GRADUALISM Types of ecology: Evolutionary ecology; Population ecology; Speciation According to classical evolutionary theory, new species arise by gradual transformation of ancestral ones. Speciation theory of the 1950’s and 1960’s, however, predicted that new species arise from small populations isolated from the main population, where they diverge rapidly.
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n 1972, Niles Eldredge and Stephen Jay Gould applied a new concept of speciation to the fossil record, predicting that species should arise suddenly (“punctuated” by a speciation event) rather than gradually, and then persist virtually unchanged for millions of years in “equilibrium” before becoming extinct or speciating again. Although Charles Darwin’s most influential work was entitled On the Origin of Species by Means of Natural Selection (1859), in fact it did not address the problem in the title. Darwin was concerned with showing that evolution had occurred and that species could change, but he did not deal with the problem of how new species were formed. For nearly a century, no other biologists addressed this problem either. Darwin (and many of his successors) believed that species formed by gradual transformation of existing ancestral species, and this viewpoint (known as gradualism) was deeply entrenched in the biology and paleontology books for a century. In this view, species are not real entities but merely arbitrary segments of continuously evolving lineages that are always in the process of change through time. Paleontologists tried to document examples of this kind of gradual evolution in fossils, but remarkably few examples were found. The Allopatric Speciation Model By the 1950’s and 1960’s, however, systematists (led by Ernst Mayr) began to study species in the wild and therefore saw them in a different light. They noticed that most species do not gradually transform into new ones in the wild but instead have fairly sharp boundaries. These limits are established by their ability and willingness to interbreed with each other. Those individuals that can interbreed are members of the same species, and those that cannot are of different species. When a population is divided and separated so that formerly interbreeding individuals develop differences that prevent interbreeding, then a new species is formed. Mayr showed that, in 543
Punctuated equilibrium vs. gradualism nature, large populations of individuals living together (sympatric conditions) interbreed freely, so that evolutionary novelties are swamped out and new species cannot arise. When a large population becomes split by some sort of barrier so that there are two different populations (allopatric conditions), however, the smaller populations become isolated from interbreeding with the main population. If these allopatric, isolated populations have some sort of unusual gene, their numbers may be small enough that this gene can spread through the whole population in a few generations, giving rise to a new species. Then, when the isolated population is reintroduced to the main population, it has developed a barrier to interbreeding, and a new species becomes established. This concept is known as the allopatric speciation model. The allopatric speciation model was well known and accepted by most biologists by the 1960’s. It predicted that species arise in a few generations from small populations on the fringe of the range of the species, not in the main body of the population. It also predicted that the new species, once it arises on the periphery, will appear suddenly in the main area as a new species in competition with its ancestor. These models of speciation also treated species as real entities, which recognize one another in nature and are stable over long periods of time once they become established. Yet, these ideas did not penetrate the thought of paleontologists for more than a decade after biologists had accepted them. Eldredge and Gould’s Model In 1972, Niles Eldredge and Stephen Jay Gould proposed that the allopatric speciation model would make very different predictions about species in the fossil record than the prevailing dogma that they must change gradually and continuously through time. In their paper, they described a model of “punctuated equilibrium.” Species should arise suddenly in the fossil record (punctuation), followed by long periods of no change (equilibrium, or stasis) until they went extinct or speciated again. They challenged paleontologists to examine their biases about the fossil record and to see if in fact most fossils evolved gradually or rapidly, followed by long periods of stasis. In the years since that paper, hundreds of studies have been done on many different groups of fossil organisms. Although some of the data were inadequate to test the hypotheses, many good studies have shown quite clearly that punctuated equilibrium describes the evolution of many multicellular organisms. The few exceptions are in the gradual evolution of size (which was specifically exempted by Eldredge and Gould) and in uni544
Punctuated equilibrium vs. gradualism cellular organisms, which have both sexual and asexual modes of reproduction. Many of the classic studies of gradualism in oysters, heart urchins, horses, and even humans have even been shown to support a model of stasis punctuated by rapid change. The model is still controversial, however, and there are still many who dispute both the model and the data that support it. Implications One of the more surprising implications of the model is that long periods of stasis are not predicted by classical evolutionary theory. In neoDarwinian theory, species are highly flexible, capable of changing in response to environmental changes. Yet, the fossil record clearly shows that most species persist unchanged for millions of years, even when other evidence clearly shows climatic changes taking place. Instead of passively changing in response to the environment, most species stubbornly persist unchanged until they either go extinct, disappear locally, or change rapidly to some new species. They are not infinitely flexible, and no adequate mechanism has yet been proposed to explain the ability of species to maintain themselves in homeostasis in spite of environmental changes and apparent strong natural selection. Naturally, this idea intrigues paleontologists, since it suggests processes that can only be observed in the fossil record and were not predicted from studies of living organisms. Species Selection The punctuated equilibrium model has led to even more interesting ideas. If species are real, stable entities that form by speciation events and split into multiple lineages, then multiple species will be formed and compete with one another. Perhaps some species have properties (such as the ability to speciate rapidly, disperse widely, or survive extinction events) that give them advantages over other species. In this case, there might be competition and selection between species, which was called species selection by Steven Stanley in 1975. Some evolutionary biologists are convinced that species selection is a fundamentally different process from that of simple natural selection that operates on individuals. In species selection, the fundamental unit is the species; in natural selection, the fundamental unit is the individual. In species selection, new diversity is created by speciation and pruned by extinction; in natural selection, new diversity is created by mutation and eliminated by death of individuals. There are many other such parallels, but many evolutionary biologists believe that the processes are distinct. Indeed, since species are composed of populations of individuals, species selection operates on a higher level than natural selection. 545
Punctuated equilibrium vs. gradualism If species selection is a valid description of processes occurring in nature, then it may be one of the most important elements of evolution. Most evolutionary studies in the past have concentrated on small-scale, or microevolutionary, change, such as the gradual, minute changes in fruit flies or bacteria after generations of breeding. Many evolutionary biologists are convinced, however, that microevolutionary processes are insufficient to explain the large-scale, or macroevolutionary, processes in the evolution of entirely new body plans, such as birds evolving from dinosaurs. In other words, traditional neo-Darwinism says that all evolution is merely microevolution on a larger scale, whereas some evolutionary biologists consider some changes too large for microevolution. They require different kinds of processes for macroevolution to take place. If there is a difference between natural selection (a microevolutionary process) and species selection (a macroevolutionary process), then species selection might be a mechanism for the large-scale changes in the earth’s history, such as great adaptive radiations or mass extinctions. Naturally, such radical ideas are still controversial, but they are taken seriously by a growing number of paleontologists and evolutionary biologists. If they are supported by further research, then there may be some radical changes in evolutionary biology. Reinterpreting the Fossil Record Determining patterns of evolution requires a very careful, detailed study of the fossil record. To establish whether organisms evolve in a punctuated or gradual mode, many criteria must be met. The taxonomy of the fossils must be well understood, and there must be large enough samples at many successive stratigraphic levels. To estimate the time spanned by the study, there must be some form of dating that allows the numerical age of each sample to be estimated. It is also important to have multiple sequences of these fossils in a number of different areas to rule out the effects of migration of different animals across a given study area. Once the appropriate samples have been selected, then the investigator should measure as many different features as possible. Too many studies in the past have looked at only one feature and therefore established very little. In particular, changes in size alone are not sufficient to establish gradualism, since these phenomena can be explained by many other means. Finally, many studies in the past have failed because they picked one particular lineage or group and selectively ignored all the rest of the fossils in a given area. The question is no longer whether one or more cases of gradualism or punctuation occurs (they both do) but which is predominant among all the organisms in a given study area. Thus, the best studies look at the entire as546
Punctuated equilibrium vs. gradualism semblage of fossils in a given area over a long stratigraphic interval before they try to answer the question of which tempo and mode of evolution is prevalent. Since the 1940’s, evolutionary biology has been dominated by the neoDarwinian synthesis of genetics, systematics, and paleontology. In more recent years, many of the accepted neo-Darwinian mechanisms of evolution have been challenged from many sides. Punctuated equilibrium and species selection represent the challenge of the fossil record to neo-Darwinian gradualism and overemphasis on the power of natural selection. If fossils show rapid change and long-term stasis over millions of years, then there is no currently understood evolutionary mechanism for this sort of stability in the face of environmental selection. A more general theory of evolution may be called for, and, in more recent years, paleontologists, molecular biologists, and systematists have all been indicating that such a radical rethinking of evolutionary biology is on the way. Donald R. Prothero See also: Adaptations and their mechanisms; Adaptive radiation; Coevolution; Colonization of the land; Convergence and divergence; Dendrochronology; Development and ecological strategies; Evolution: definition and theories; Evolution: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Genetically modified foods; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Paleoecology; Population genetics; Speciation; Species loss. Sources for Further Study Bennett, K. D. Evolution and Ecology: The Pace of Life. New York: Cambridge University Press, 1997. Eldredge, Niles. Time Frames: The Rethinking of Darwinian Evolution and the Theory of Punctuated Equilibria. New York: Simon & Schuster, 1985. Eldredge, N., and S. J. Gould. “Punctuated Equilibria: An Alternative to Phyletic Gradualism.” In Models in Paleobiology, edited by T. J. M. Schopf. San Francisco: Freeman, Cooper, 1972. Freeman, S., and J. C. Herron. Evolutionary Analysis. 2d ed. Upper Saddle River, N.J.: Prentice Hall, 2001. Gerhart, John. Cells, Embryos, and Evolution: Toward a Cellular and Developmental Understanding of Phenotypic Variation and Evolutionary Adaptability. Malden, Mass.: Blackwell Science, 1997. Gould, Stephen J. “The Meaning of Punctuated Equilibria and Its Role in Validating a Hierarchical Approach to Macroevolution.” In Perspectives 547
Punctuated equilibrium vs. gradualism on Evolution, edited by Roger Milkman. Sunderland, Mass.: Sinauer Associates, 1982. Gould, Stephen J., and Niles Eldredge. “Punctuated Equilibrium: The Tempo and Mode of Evolution Reconsidered.” Paleobiology 3 (1977): 115-151. Hoffman, Antoni. Arguments on Evolution: A Paleontologist’s Perspective. New York: Oxford University Press, 1988. Levinton, Jeffrey S. Genetics, Paleontology, and Macroevolution. 2d ed. New York: Cambridge University Press, 2000. Mayr, Ernst. Animal Species and Evolution. Cambridge, Mass.: Harvard University Press, 1963. Moller, A. P. Asymmetry, Developmental Stability, and Evolution. New York: Oxford University Press, 1997.
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RAIN FORESTS Types of ecology: Biomes; Ecosystem ecology A forest growing in a region that receives over one hundred inches of rain annually is considered to be a rain forest. Rain forests can be found in both tropical and temperate climates and are noted for their remarkable biodiversity. Thousands of different animal and plant species can be found within only an acre or two of a rain forest.
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ain forests are forests found in regions of the world that receive large amounts of precipitation annually. Rain forests present an incredibly diverse range of habitats, as they exist both at low elevations and high in mountain ranges. Many unusual and seldom-seen creatures inhabit the world’s rain forests, including spiders so large they eat small birds, and colorful but highly poisonous tree frogs. The enigmatic sloth, an animal that spends its entire life hanging upside down from tree limbs and moving so slowly that moss grows on its fur, is found in the rain forests of South America. Although tropical rain forests, such as those in the Amazon River drainage system of South America, are perhaps the best known, rain forests do exist in temperate regions as well. Olympic National Park in the state of Washington preserves a temperate climate rain forest, while much of the coast of British Columbia and southeastern Alaska also receives well over one hundred inches of rain annually. The primary difference between temperate and tropical rain forests is that in a temperate rain forest, often one or two species of trees will become dominant. In the coniferous rain forest of the Pacific Northwest, for example, Douglas fir and western red cedar are the dominant species, while other trees are found in much smaller numbers. In a tropical rain forest, in contrast, several hundred species of trees may grow side by side within a very small geographic area. The majority of trees found in tropical rain forests tend to be broad-leaved, such as the rubber tree, while temperate rain forests are dominated by conifers. The leaves of many plants in rain forests often have a waxy texture or come to a point to help shed water more quickly and prevent the growth of fungi or mold. Characteristics of Rain Forests Although rain forests are remarkably diverse, they do share a few characteristics in common. The abundant moisture in a rain forest gives the 549
Rain forests woodland a lush, fertile appearance. This is particularly true in tropical regions. Even in the understory, close to ground level where light is limited, vegetation may be dense. This appearance of fertility is often deceptive. Dead plant matter decays rapidly in a tropical forest, but the nutrients are used quickly by the numerous competing plants. In addition, the trees in tropical forests are evergreen, which means the litter that does fall to the forest floor does so irregularly, unlike temperate broadleaf forests, where trees lose their leaves annually as the seasons change. Leaves will remain indefinitely on tropical species, such as fig and rubber trees, which is one reason small specimens of these trees are popular as houseplants. As a consequence of this lack of mulch, topsoil is often thin and the root systems of the trees are quite shallow. One reason tropical rain forests are evergreen is that in the tropics there is little seasonal variation in the hours of daylight. The closer to the equator a forest lies, the less change there is from season to season. In temperate climates, many plants have evolved to bloom, set seeds, or lose their leaves based on the number of hours of sunlight available each day. As the sea-
Although most think of rain forests as tropical ecosystems, many coastal or near-coastal forests in higher latitudes, such as those of the Pacific Northwest, fall into this category as well, with their high rates of precipitation and their various levels of growth. Here, understory and canopy are clearly visible. (PhotoDisc) 550
Rain forests sons change annually, plants bloom in the spring or early summer; fruit ripens in the fall, photosynthesis slows, and leaves change color and die. In the tropics, where the number of hours of sun light daily never varies, plants follow a different schedule. Many tropical plants bear new flowers and mature fruit simultaneously. The evergreen foliage and continuous supply of certain fruits has led to the adaptation of some animals to a very restricted diet: koalas, for example, which feed exclusively on eucalyptus leaves, or parakeets that eat only figs. Exceptions to this pattern are the forests where rain fall is seasonal, such as regions of the world like southeast Asia, where much of the rain comes in the form of annual monsoon storms. In those cases, flowering and setting fruit will coincide with the seasonal rains. Forest Zones A rain forest can be divided into four zones, each of which has its own distinct characteristics. The lowest level, the forest floor, is often dark and gloomy. Little sunlight penetrates to this level, and there is little air movement. Numerous insects, such as beetles, cockroaches, and termites, live in the decaying litter and provide food for larger animals and birds. Many of the insects, birds, reptiles, and amphibians that live in the lower levels of the rain forest are brightly colored. Scientists speculate that the animals have evolved in this fashion to more easily attract potential mates. Other scientists believe that colors warn potential predators to stay away. In either case, the vivid colors make the animals more easily seen in what is otherwise a dark environment. Just above the forest floor is the understory. Many of the plants in the understory have large, dark leaves to maximize their light-collecting ability. Because there is little natural air movement within the lower levels of a rain forest due to the canopy blocking any natural breezes, the flowering plants in the understory often have strongly scented or vividly colored flowers to help attract insects or birds to assist with pollination. Lizards, snakes, amphibians such as tree frogs and salamanders, small birds, and mammals as large as the jaguar all call the understory home. The plants found only in the understory seldom exceed fifteen to twenty feet in height. The coffee shrub is an example of a small, shade-tolerant, tropical tree. Until horticulturalists developed strains of coffee for use in plantations where the coffee bushes are the only plants grown, coffee grew naturally in the understory of tropical forests. The densest layer of plant life is the canopy. High above the rain forest floor, the branches of mature trees form a dense intertwined zone of vegetation extending up as much as 150 feet above the ground. Numerous 551
Rain forests plants sprout in the crotches of trees, where debris may collect. Tree limbs are festooned with vines and mosses, and bromeliads and orchids grow on the rough bark of tree trunks. Even other trees may start their life cycle a hundred feet above the ground: The strangler figs of Borneo are a relatively shade-intolerant species. A fig seed that lands and sprouts on the ground will probably not survive due to low light levels on the forest floor. Strangler figs have adapted so that their seedlings do best high in the canopy. The figs begin life in the crotches of other trees. The roots of a young fig will gradually creep down the trunk of the tree on which it sprouted. Over time, the strangler fig’s roots will completely encircle the host tree and penetrate the forest floor. The fig thrives, but the host tree dies, choked off by the strangler fig. Primates such as gibbons, orangutans, and lemurs spend much of their lives in the canopy, feeding on the fruit of trees such as the strangler fig, as do the sloth and other herbivorous mammals. The emergent layer of the rain forest consists of the tallest trees, some of which exceed two hundred feet in height. The tops of these trees provide a habitat for large, predatory birds, such as eagles, as well as being home to assorted snakes, monkeys, and other animals. Every layer of the rain forest teems with life, and often what can be found at ground level gives no hint of the diversity that exists two hundred feet above in the tree tops. Rain Forest Conservation Many of the trees found in rain forests are valued for their commercial use as lumber, while others have been exploited for their fruits or other products, causing much habitat loss. Tropical hardwoods, such as teak and mahogany, for example, have long been used in construction and in furniture. Teak resists rotting and as a result is often used for products that are going to be exposed to the weather, such as garden furniture. Because teak is desirable as lumber, timber companies are increasingly planting it in plantations for a sustainable yield rather than relying solely on natural forests as a source. Activists hoping to preserve the tropical rain forest have encouraged indigenous peoples to collect forest products, such as nuts or sap, as a way to create a viable economy while at the same time discouraging industrial clear-cutting of the forest. Native people tap rubber trees in Amazonia, for example, to collect latex. Rubber trees are native to the rain forests of South America, although they are also grown in plantations in other tropical regions of the world, such as Southeast Asia. The biggest threat to the world’s rain forests may not come from commercial logging, however. In many regions of the world, rain forests have fallen victim to population pressures. Forests continue to be clear-cut for 552
Rain forests agricultural use, even when the farmers and ranchers know the exposed soil’s fertility will be quickly exhausted. In some cases, the cleared land becomes an arid wasteland as the tropical sun bakes the soil too hard to absorb rain water. In others, the land is farmed for a year or two and then abandoned. Given enough time, the rain forest may regenerate, but the process will take hundreds of years. Nancy Farm Männikkö See also: Biomes: determinants; Biomes: types; Chaparral; Deserts; Forests; Grasslands and prairies; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes; Wetlands. Sources for Further Study Bowman, David M. J. S. Australian Rainforests: Islands of Green in a Land of Fire. New York: Cambridge University Press, 2000. Durbin, Kathie. Pulp Politics and the Fight for the Alaska Rain Forest. Corvallis: Oregon State University Press, 1999. Gamlin, Linda, and Anuschka de Rohan. Mysteries of the Rain Forest. Pleasantville, N.Y.: Reader’s Digest, 1998. Goldsmith, Frank Barrie. Tropical Rain Forest: A Wider Perspective. New York: Chapman & Hall, 1998. Holloway, M. “Sustaining the Amazon.” Scientific American 269 (July, 1993): 90-99. Killman, Wolf, and Lay Thong Hong. “Rubberwood: The Success of an Agricultural By-Product.” Unasylva 51 (2000): 66-72. Maser, Chris. Forest Primeval: The Natural History of an Ancient Forest. Reprint. Corvallis: Oregon State University Press, 2001. Tricart, Jean. The Landforms of the Humid Tropics, Forests, and Savannas. Translated by Conrad J. Kiewiet de Jonge. New York: St. Martin’s Press, 1972.
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RAIN FORESTS AND THE ATMOSPHERE Types of ecology: Biomes; Ecoenergetics; Ecosystem ecology; Global ecology Because photosynthesis releases large amounts of oxygen into the air, a curtailment of the process by rain-forest deforestation may have negative effects on the global atmosphere.
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ain forests are ecosystems noted for their high biodiversity and high rate of photosynthesis. The rapid deforestation of such areas is of great concern to environmentalists both because it may lead to the extinction of numerous species and because it may reduce the amount of photosynthesis occurring on the earth. All living things on the earth—plants, animals, and microorganisms— depend on the “sea” of air surrounding them. The atmosphere includes abundant, permanent gases such as nitrogen (78 percent) and oxygen (21 percent) as well as smaller, variable amounts of other gases such as water vapor and carbon dioxide. Organisms absorb and use this air as a source of raw materials and release into it by-products of their life activities. Cellular Respiration Cellular respiration is the most universal of the life processes. A series of chemical reactions beginning with glucose and occurring in cytoplasmic organelles called mitochondria, cellular respiration produces a chemical compound called adenosine triphosphate (ATP). This essential substance furnishes the energy cells need to move, to divide, and to synthesize chemical compounds—in essence, to perform all the activities necessary to sustain life. Cellular respiration occurs in plants as well as animals, and it occurs during both the day and the night. In order for the last of the series of chemical reactions in the process to be completed, oxygen from the surrounding air (or water, in the case of aquatic plants) must be absorbed. The carbon dioxide that forms is released into the air. For cellular respiration to occur, a supply of glucose (a simple carbohydrate compound) is required. Photosynthesis, an elaborate series of chemical reactions occurring in chloroplasts, produces glucose, an organic carbon compound with six carbon atoms. Energy present in light must be trapped by the chlorophyll within the chloroplasts to drive photosynthe554
Rain forests and the atmosphere sis. Therefore, photosynthesis occurs only in plants and related organisms such as algae, and only during the daytime. Carbon dioxide, required as a raw material, is absorbed from the air, while the resulting oxygen is released into the atmosphere. The exchange of gases typically involves tiny openings in leaves, called stomata. Oxygen Cycle Oxygen is required for the survival of the majority of microorganisms and all plants and animals. From the surrounding air, organisms obtain the oxygen used in cell respiration. Plants absorb oxygen through the epidermal coverings of their roots and stems and through the stomatal openings of their leaves. The huge amounts of oxygen removed from the air during respiration must be replaced in order to maintain a constant reservoir of oxygen in the atmosphere. There are two significant sources of oxygen. One involves water molecules of the atmosphere that undergo a process called photodissociation: Oxygen remains after the lighter hydrogen atoms are released from the molecule and escape into outer space.
An aerial view of the rain forest in Guyana. In such tropical forests, the many layers of forest vegetation result in energy from sunlight being efficiently used as it passes downward. The large amounts of oxygen released are available for use not only by the forests but also, because of global air movement, by other ecosystems throughout the world. (PhotoDisc) 555
Rain forests and the atmosphere The other source is photosynthesis. Chlorophyll-containing organisms release oxygen as they use light as the energy source to split water molecules in a process called photolysis. The hydrogen is transported to the terminal phase of photosynthesis called the Calvin cycle, where it is used as the hydrogen source necessary to produce and release molecules of the carbohydrate glucose. In the meantime, the oxygen from the split water is released into the surrounding air. Early in the history of the earth, before certain organisms evolved the cellular machinery necessary for photosynthesis, the amount of atmospheric oxygen was very low. As the number and sizes of photosynthetic organisms gradually increased, so did the levels of oxygen in the air. A plateau was reached several million years ago as the rate of oxygen release and absorption reached an equilibrium. Ozone Another form of oxygen is ozone. Unlike ordinary atmospheric oxygen, in which each molecule contains two atoms, ozone molecules have three oxygen atoms each. Most ozone is found in the stratosphere at elevations between 10 and 50 kilometers (6 and 31 miles). This layer of ozone helps to protect life on earth from the harmful effects of ultraviolet radiation. Scientists, especially ecologists, are concerned because the amount of ozone has been reduced drastically over the last few decades. Already, an increase in the incidence of skin cancer in humans and a decrease in the efficiency of photosynthesis has been documented. Another concern related to ozone is that of an increase in ozone levels nearer to the ground, where living things are harmed as a result. The formation of ozone from ordinary oxygen within the atmosphere is greatly accelerated by the presence of gaseous pollutants released from industrial processes. Carbon Cycle All forms of life are composed of organic (carbon-containing) molecules. Carbohydrates include glucose as well as lipids (fats, oils, steroids, and waxes), proteins, and nucleic acids. The ability of carbon to serve as the backbone of these molecules results from the ability of carbon atoms to form chemical bonds with other carbon atoms and also with oxygen, hydrogen, and nitrogen atoms. Like oxygen, carbon cycles in a predictable manner between living things and the atmosphere. In photosynthesis, carbon is “fixed” as carbon dioxide in the air (or dissolved in water) is absorbed and converted into carbohydrates. Carbon cycles to animals as they feed on plants and algae. As both green and nongreen organisms respire, some of their carbohy556
Rain forests and the atmosphere drates are oxidized, releasing carbon dioxide into the air. Each organism must eventually die, after which decay processes return the remainder of the carbon to the atmosphere. Greenhouse Effect Levels of atmospheric carbon dioxide have fluctuated gradually during past millennia, as revealed by the analysis of the gas trapped in air bubbles of ice from deep within the earth. In general, levels were lower during glacial periods and higher during warmer ones. After the nineteenth century, levels rose slowly until about 1950 and then much more rapidly afterward. The apparent cause has been the burning of increased amounts of fossil fuels associated with the Industrial Revolution and growing energy demands in its wake. The global warming that is now being experienced is believed by most scientists to be the cause of increased carbon dioxide levels. The greenhouse effect is the term given to the insulating effects of the atmosphere with increased amounts of carbon dioxide. The earth’s heat is lost to outer space less rapidly, thus increasing the earth’s average temperature. Forest Ecosystems The biotic (living) portions of all ecosystems include three ecological or functional categories: producers (plants and algae), consumers (animals), and decomposers (bacteria and fungi). The everyday activities of all organisms involve the constant exchange of oxygen and carbon dioxide between the organisms of all categories and the surrounding atmosphere. Because they release huge quantities of oxygen during the day, producers deserve special attention. In both fresh and salt water, algae are the principal producers. On land, this role is played by a variety of grasses, other small plants, and trees. Forest ecosystems, dominated by trees but also harboring many other plants, are major systems that produce a disproportionate amount of the oxygen released into the atmosphere by terrestrial ecosystems. Forests occupy all continents except for Antarctica. A common classification of forests recognizes these principal categories: coniferous (northern evergreen), temperate deciduous, and tropical evergreen, with many subcategories for each. The designation “rain forest” refers to the subcategories of these types that receive an amount of rainfall well above the average. Included are tropical rain forests (the more widespread type) and temperate rain forests. Because of the ample moisture they receive, both types contain lush vegetation that produces and releases oxygen into the atmosphere on a larger scale than do other forests. 557
Rain forests and the atmosphere Tropical Rain Forests Tropical rain forests exist at relatively low elevations in a band about the equator. The Amazon basin of South America contains the largest continuous tropical rain forest. Other large expanses are located in western and central Africa and the region from Southeast Asia to Australia. Smaller areas of tropical rain forests occur in Central America and on certain islands of the Caribbean Sea, the Pacific Ocean, and the Indian Ocean. Seasonal changes within tropical rain forests are minimal. Temperatures, with a mean near 25 degrees Celsius, seldom vary more than 4 degrees Celsius. Rainfall each year measures at least 400 centimeters. Tropical rain forests have the highest biodiversity of any terrestrial ecosystem. Included is a large number of species of flowering plants, insects, and animals. The plants are arranged into layers, or strata. In fact, all forests are stratified but not to the same degree as tropical rain forests. A mature tropical rain forest typically has five layers. Beginning with the uppermost, they are an emergent layer (the tallest trees that project above the next layer); a canopy of tall trees; understory trees; shrubs, tall herbs, and ferns; and low plants on the forest floor. Several special life-forms are characteristic of the plants of tropical rain forests. Epiphytes are plants such as orchids that are perched high in the branches of trees. Vines called lianas wrap themselves around trees. Most tall trees have trunks that are flared at their bases to form buttresses that help support them in the thin soil. This brief description of tropical rain forests helps to explain their role in world photosynthesis and the related release of oxygen into the atmosphere. As a result of the many layers of forest vegetation, the energy from sunlight as it passes downward is efficiently utilized. Furthermore, the huge amounts of oxygen released are available for use not only by the forests themselves but also, because of global air movement, by other ecosystems throughout the world. Because of this, tropical rain forests are often referred to as “the earth’s lungs.” Temperate Rain Forests Temperate rain forests are much less extensive than tropical rain forests; they occur primarily along the Pacific Coast in a narrow band from southern Alaska to central California. Growing in this region is a coniferous forest but one with warmer temperatures and a higher rainfall than those to the north and inland. This rainfall of 65 to 400 centimeters per year is much less than that of a tropical rain forest, but is supplemented in the summer by frequent heavy fogs. As a result, evaporation rates are greatly reduced. Because of generally favorable climatic conditions, temperate rain forests, 558
Rain forests and the atmosphere like tropical ones, support a lush vegetation. The rate of photosynthesis and release of oxygen are higher than in most other world ecosystems. Ecologists and conservationists are greatly concerned about the massive destruction of rain forests. Rain forests are being cut and burned at a rapid rate to plant crops, to graze animals, and to provide timber. The ultimate effect of deforestation of these special ecosystems is yet to be seen. Thomas E. Hemmerly See also: Biodiversity; Biomes: determinants; Biomes: types; Communities: ecosystem interactions; Deforestation; Ecosystems: definition and history; Ecosystems: studies; Forests; Geochemical cycles; Global warming; Greenhouse effect; Habitats and biomes; Hydrologic cycle; Nutrient cycles; Ozone depletion and ozone holes; Pollution effects; Rain forests; Savannas and deciduous tropical forests; Slash-and-burn agriculture; Trophic levels and ecological niches. Sources for Further Study Laurance, William F., and Richard O. Bierregaard, eds. Tropical Forest Remnants: Ecology, Management, and Conservation of Fragmented Communities. Chicago: University of Chicago Press, 1997. Shipp, Steve. Rainforest Organizations: A Worldwide Directory of Private and Governmental Entities. Jefferson, N.C.: McFarland, 1997. Townsend, Janet G. Women’s Voices from the Rainforest. New York: Routledge, 1995. Vandermeer, John. Breakfast of Biodiversity: The Truth About Rain Forest Destruction. Oakland, Calif.: Institute for Food and Development Policy, 1995.
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RANGELAND Types of ecology: Agricultural ecology; Biomes; Ecosystem ecology Open land of a wide variety of types, including grasslands, shrublands, marshes, and meadows as well as some desert and alpine land, is known as rangeland.
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angeland is a valuable and resilient ecosystem resource that supports considerable plant and animal life. Rangeland generally refers to a kind of land rather than a use of that land. The Society for Range Management defines rangelands as “land on which the native vegetation (climax or natural potential) is predominantly grasses, grass-like plants, forbs, or shrubs.” Rangeland “includes lands revegetated naturally or artificially” as well as “natural grasslands, savannas, shrublands, most deserts, tundra, alpine communities, coastal marshes and wet meadows.” Rangelands usually have some limitation for intensive agriculture, such as low and erratic precipitation, lack of soil fertility, shallow or rocky soil, or steep slopes. In addition to livestock grazing, rangelands serve multiple-use functions such as providing recreational opportunities, watersheds, mining locations, and habitat for many animal species. Renewable natural resources associated with rangelands are plants and animals (and, in some senses, water). Nonrenewable resources include minerals and other extractable materials. Location and Characteristics Rangelands are extensive and extremely variable. As defined by the Society for Range Management, they occupy more than 50 percent of the world’s total land surface and about 1 billion acres in the United States alone. Rangelands are home to nomadic herders on nearly every continent. They vary from high-elevation alpine tundra and high-latitude Arctic tundra to tropical grasslands. The tall-grass prairies in the United States (now mostly plowed for intensive agriculture) and the rich grasslands of eastern Africa are among the most productive. Rangelands grade into woodlands and forests as woody species and trees become more abundant. Some forests are grazed by wild and domestic animals, and the distinction between rangeland and forest is often not clear. The other difficult distinction is between rangeland and pastureland. Pastureland is generally improved by seeding, fertilization, or irrigation, whereas rangelands support native plants and have little intensive improvement. 560
Rangeland In the United States, rangeland improvements during the twenty years following World War II often included brush control, grazing management, and seeding, but rangelands were not irrigated. After the 1970’s, when fuel costs increased and environmental concerns about pesticide use increased, brush control practices were reduced considerably. Today environmental concerns include rangeland degradation from overgrazing, especially on riparian vegetation along streams, and concern for endangered animal and plant species. These issues have become controversial in the United States. Rangelands as Ecosystems Rangelands constitute natural ecosystems with nonliving environmental factors such as soil and climatic factors. Life-forms are primary producers (grasses, forbs, and shrubs), herbivores (livestock; big game animals such as deer and bison; and many rodents and insects), carnivores (such as coyotes, bears, and eagles), and decomposers (fungi and bacteria) that break down organic matter into elements that can be utilized by plants. Plants convert carbon dioxide and water into complex carbohydrates, fats, and proteins that nourish animals feeding on the plants.
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Rangeland Individual chemical elements are circulated throughout the various components. Many of these elements are present in the soil, including phosphorus, magnesium, potassium, and sulfur. Nitrogen, on the other hand, is present in large amounts in the atmosphere but must be converted (fixed) into forms that can be utilized by plants before it can be cycled. Energy is fixed through the process of photosynthesis and transformed to forms useful for the plants, then the animals that feed on plants. When chemicals are taken up by plant roots from the soil, they become available to a wide group of herbivores, from small microbes to large ungulates. Eventually nutrients are passed on to organisms at higher trophic levels (omnivores and carnivores). Both plant and animal litter is eventually broken down by decomposers—bacteria, fungi, and other soil organisms—and returned to the soil or, in the case of carbon or nitrogen, given off to the atmosphere. However, energy is degraded at each step along the way; energy is transferred but not cycled. Grazing animals on rangelands influence plants by removing living tissue, by trampling, and by altering competitive relations with other plants. Large grazing animals tend to compact the soil, reducing infiltration and increasing surface runoff. Rangeland Dynamics Rangelands vary considerably with time. Scientists are gaining a better understanding of some factors related to rangeland change. Pollen records and, in the southwestern United States, packrat middens have been used to reconstruct past climate and vegetational conditions. Some areas have become drier and others more mesic. The formation and retreat of glaciers influenced climatic patterns and soil development. A recent general trend in many rangelands is an increase in woody plants at the expense of grasses. Many factors are probably responsible for these shifts, but fire control, overgrazing, climatic shifts, introduction of exotic species, and influence of native animals are likely causal agents. Rangelands are being threatened by encroachment from crop agriculture as worldwide development increases. Nomadic herders traditionally met periodic drought conditions by having the flexibility to move to areas not impacted by drought. Now, with area lost to livestock grazing and other political restrictions, herders are often forced to maintain higher livestock numbers to support those directly dependent on livestock. Despite various kinds of disturbances and stresses on rangelands, these areas have supported many large grazing animals and people for centuries. Rex D. Pieper 562
Rangeland See also: Forest management; Grasslands and prairies; Grazing and overgrazing; Multiple-use approach. Sources for Further Study Heady, Harold F., and R. Dennis Child. Rangeland Ecology and Management. 2d ed. Boulder, Colo.: Westview, 2000. Holechek, Jerry L., Rex D. Pieper, and Carlton H. Herbel. Range Management: Principles and Practices. 4th ed. Upper Saddle River, N.J.: Prentice Hall, 2001. Jacobs, Lynn. Waste of the West: Public Lands Ranching. Tucson, Ariz.: L. Jacobs, 1991. Longworth, John W., and Gregory J. Williamson. China’s Pastoral Region: Sheep and Wool, Minority Nationalities, Rangeland Degradation, and Sustainable Development. Wallingford, England: CAB International, 1993. Owen, Oliver S., Daniel D. Chiras, and John P. Reganold. Natural Resource Conservation. 7th ed. Upper Saddle River, N.J.: Prentice Hall, 1998. Sayre, Nathan F. The New Ranch Handbook: A Guide to Restoring Western Rangelands. Santa Fe, N.Mex.: Quivera Coalition, 2001.
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REEFS Types of ecology: Aquatic and marine ecology; Biomes; Ecosystem ecology Reefs are among the oldest known communities, existing at least 2 billion years ago. They exert considerable control on the surrounding physical environment, influencing turbulence levels and patterns of sedimentation. Ancient reefs are often important hydrocarbon reservoirs. “True” Reefs vs. Reeflike Structures Reefs or reeflike structures are among the oldest known communities, extending back more than 2 billion years into the earth’s history. These earliest reefs were vastly different in their biotic composition and physical structure from modern reefs, which are among the most diverse of biotic communities and display amazingly high rates of biotic productivity (carbon fixation) and calcium carbonate deposition, despite their existence in a virtual nutrient “desert.” Reefs are among the few communities to rival the power of humankind as a shaper of the planet. The Great Barrier Reef of Australia, for example, forms a structure some 2,000 kilometers in length and up to 150 kilometers in width. It is necessary to distinguish between “true,” or structural, reefs and reeflike structures or banks. Reefs are carbonate structures that possess an internal framework. The framework traps sediment and provides resistance to wave action; thus, reefs can exist in very shallow water and may grow to the surface of the oceans. Banks are also biogenically produced but lack an internal framework. Thus, banks are often restricted to low-energy, deep-water settings. “Bioherm” refers to moundlike carbonate buildups, either reefs or banks, and “biostrome” to low, lens-shaped buildups. Reef Classification Modern reefs are classified into several geomorphic types: atoll, barrier, fringing, and patch. Many of these may be further subdivided into reef crest or flat, back-reef or lagoon, and fore-reef zones. Atoll reefs are circular structures with a central lagoon, thought to form on subsiding volcanic islands. Barrier reefs are elongate structures that parallel coastlines and possess a significant lagoon between the exposed reef crest and shore. These often occur on the edges of shelves that are uplifted by faulting. Fringing reefs are elongate structures paralleling and extending seaward from the coastline that lack a lagoon between shore and exposed reef crest. Patch 564
Reefs reefs are typically small, moundlike structures, occurring isolated on shelves or in lagoons. The majority of fossil reefs would be classified as patch reefs, although many examples of extensive, linear, shelf-edge trends are also known from the geologic record. Reefs form one of the most distinctive and easily recognized sedimentary facies (or environments). In addition to possessing a characteristic fauna consisting of corals, various algae, and stromatoporoids, they are distinguished by a massive (nonlayered) core that has abrupt contacts with adjacent facies. Associated facies include flat-lying lagoon and steeply inclined fore-reef talus, the latter often consisting of large angular blocks derived from the core. The reef core is typically a thick unit relative to adjacent deposits. The core also consists of relatively pure calcium carbonate with little contained terrigenous material. Reef Environments Modern reefs are restricted to certain environments. They occur abundantly only between 23 degrees north and south latitudes and tend to be restricted to the western side of ocean basins, which lack upwelling of cold bottom waters. This restriction is based on temperature, as reefs do not flourish where temperatures frequently reach below 18 degrees Celsius. Reef growth is largely restricted to depths greater than 60 meters, as there is insufficient penetration of sunlight below this depth for symbiontbearing corals to flourish. Reefs also require clear waters lacking suspended terrigenous materials, as these interfere with the feeding activity of many reef organisms and also reduce the penetration of sunlight. Finally, most reef organisms require salinities that are in the normal oceanic range. It appears that many fossil reefs were similarly limited in their environmental requirements. Some of the most striking features of modern reefs include their pronounced zonation, great diversity, and high productivity and growth rates. Reefs demonstrate a strong bathymetric (depth-related) zonation. This zonation is largely mediated through depth-related changes in turbulence intensity and in the quantity and spectral characteristics (reds are absorbed first, blues last) of available light. Shallow (1- to 5-meter) fore-reef environments are characterized by strong turbulence and high light intensity and possess low-diversity assemblages of wave-resistant corals, such as the elk-horn coral, Acropora palmata, and crustose red algae. With increasing depth (10-20 meters), turbulence levels decrease and coral species diversity increases, with mound and delicate branching colonies occurring. At greater depths (30-60 meters), corals assume a flattened, platelike form in an attempt to maximize surface area for exposure to am565
Reefs bient light. Sponges and many green algae are also very important over this range. Finally, corals possessing zooxanthellae, which live in the coral tissues and provide food for the coral host, are rare or absent below 60 meters because of insufficient light. Surprisingly, green and red calcareous algae extend to much greater depths (100-200 meters), despite the very low light intensity (much less than 1 percent of surface irradiance). Sponges are also important members of these deep reef communities. Diveristy of Life-Forms Coral reefs are among the most diverse of the earth’s communities; however, there is no consensus on the mechanism(s) behind the maintenance of this great diversity. At one time, it was believed that reefs existed in a lowdisturbance, highly stable environment, which allowed very fine subdivision of food and habitat resources and thus permitted the coexistence of a great number of different species. Upon closer inspection, however, many reef organisms appear to overlap greatly in food and habitat requirements. Also, it has become increasingly apparent that disturbance, in the form of disease, extreme temperatures, and hurricanes, is no stranger to reef communities. Coral reefs exhibit very high rates of productivity (carbon fixation), which is a result of extremely tight recycling of existing nutrients. This is necessary, as coral reefs exist in virtual nutrient “deserts.” Modern corals exhibit high skeletal growth rates, up to 10 centimeters per year for some branching species. Such high rates of skeletal production are intimately related to the symbiosis existing between the hermatypic or reef-building scleractinian corals (also gorgonians and many sponges) and unicellular algae or zooxanthellae. Corals that, for some reason, have lost their zooxanthellae or that are kept in dark rooms exhibit greatly reduced rates of skeleton production. In addition to high individual growth rates for component taxa, the carbonate mass of the reefs may grow at a rate of some 2 meters per 1,000 years, a rate that is much higher than that of most other sedimentary deposits. This reflects the high productivity or growth rates of the component organisms and the efficient trapping of derived sediment by the reef frame. Although the framework organisms, most notably corals, are perhaps the most striking components of the reef system, the framework represents only 10-20 percent of most fossil reef masses. The remainder of the reef mass consists of sedimentary fill derived from the reef community through a combination of biosynthesis (secretion) and bioerosion (breaking down) of calcium carbonate. An example of the relative contributions of reef organisms to sediment can be found in Jamaica, where shallow-water, back566
Reefs
This underwater close-up of a portion of Australia’s Great Barrier Reef displays the diversity of species supported by this marine ecosystem. The Great Barrier Reef forms a structure some 2,000 kilometers in length and up to 150 kilometers in width. (Corbis)
reef sediment consists of 41 percent coral, 24 percent green calcareous algae, 13 percent red calcareous algae, 6 percent foraminifera, 4 percent mollusks, and 12 percent other grains. The most important bioeroders are boring sponges, bivalves, and various “worms,” which excavate living spaces within reef rock or skeletons, and parrot fish and sea urchins, which remove calcium carbonate as they feed upon surface films of algae. Types of Reef Communities A diversity of organisms has produced reef and reeflike structures throughout the earth’s history. Several distinct reef community types have been noted, as well as four major “collapses” of reef communities. The oldest reefs or reeflike structures existed more than 2 billion years ago during the Precambrian eon. These consisted of low-diversity communities dominated by soft, blue-green algae, which trapped sediment to produce layered, often columnar structures known as stromatolites. During the Early Cambrian period, blue-green algae were joined by calcareous, conical, spongelike organisms known as archaeocyathids, which persisted until the end of the Middle Cambrian. Following the extinction of the archaeocyathids, reefs again consisted only of blue-green algae until the advent of more modern reef communities in the Middle Ordovician period. These reefs consisted of corals (predominantly tabulate and, to a much lesser extent, rugose corals), red calcareous algae, bryozoans (moss 567
Reefs animals), and the spongelike stromatoporoids. This community type persisted through the Devonian period, at which time a global collapse of reef communities occurred. The succeeding Carboniferous period largely lacked reefs, although algal and crinoidal (sea lily) mounds were common. Reefs again occurred in the Permian period, consisting mainly of red and green calcareous algae, stromatolites, bryozoans, and chambered calcareous sponges known as sphinctozoans, which resembled strings of beads. These reefs were very different from those of the earlier Paleozoic era; in particular, the tabulates and stromatoporoids no longer played an important role. The famous El Capitan reef complex of West Texas formed during this interval. The Paleozoic era ended with a sweeping extinction event that involved not only reef inhabitants but also other marine organisms. After the Paleozoic extinctions, reefs were largely absent during the early part of the Mesozoic era. The advent of modern reefs consisting of scleractinian corals and red and green algae occurred in the Late Triassic period. Stromatoporoids once again occurred abundantly on reefs during this interval; however, the role of the previously ubiquitous blue-green algal stromatolites in reefs declined. Late Cretaceous reefs were often dominated by conical, rudistid bivalves that developed the ability to form frameworks and may have possessed symbiotic relationships with algae, as do many modern corals. Rudists, however, became extinct during the sweeping extinctions that occurred at the end of the Cretaceous period. The reefs that were reestablished in the Cenozoic era lacked stromatoporoids and rudists and consisted of scleractinian corals and red and green calcareous algae. This reef type has persisted, with fluctuations, until the present. Study of Modern Reefs Modern reefs are typically studied while scuba (self-contained underwater breathing apparatus) diving, which enables observation and sampling to a depth of approximately 50 meters. Deeper environments have been made accessible through the availability of manned submersibles and unmanned, remotely operated vehicles that carry mechanical samplers and still and video cameras. The biological compositions of reef communities are determined by census (counting) methods commonly employed by plant ecologists. Studies of symbioses, such as that between corals and their zooxanthellae, employ radioactive tracers to determine the transfer of products between symbiont and host. Growth rates are measured by staining the calcareous skeletons of living organisms with a dye, such as Alizarin red, and then later collecting and sectioning the specimen and 568
Reefs measuring the amount of skeleton added since the time of staining. Another method for determining growth is to X-ray a thin slice of skeleton and then measure and count the yearly growth bands that are revealed on the X-radiograph. Variations in growth banding reflect, among other factors, fluctuations in ocean temperature. Reef sediments, which will potentially be transformed into reef limestones, are examined through sieving, X-ray diffraction, and epoxy impregnation and thin-sectioning. Sieving enables the determination of sediment texture, the relationships of grain sizes and abundance (which will reflect environmental energy and the production), and erosion of grains through biotic processes. X-ray diffraction produces a pattern that is determined by the internal crystalline structure of the sediment grains. As each mineral possesses a unique structure, the mineralogical identity of the sediment may be determined. Thin sections of embedded sediment or lithified rock are examined with petrographic microscopes, which reveal the characteristic microstructures of the individual grains. Thus, even highly abraded fragments of coral or algae may be identified and their contributions to the reef sediment determined. Because of their typically massive nature, fossil reefs are usually studied by thin-sectioning of lithified rock samples collected either from surface exposures or well cores. Reef limestones that have not undergone extensive alteration may be dated through carbon 14 dating, if relatively young, or through uranium-series radiometric dating methods. Reefs as Ecological Laboratories Modern reefs serve as natural laboratories, enabling the scientists to witness and study phenomena, such as carbonate sediment production, bioerosion, and early cementation, that have been responsible for forming major carbonate rock bodies in the past. The study of cores extracted from centuries-old coral colonies shows promise for deciphering past climates and perhaps predicting future trends. This is made possible by the fact that the coral skeleton records variations in growth that are related to ocean temperature fluctuations. The highly diverse modern reefs also serve as ecological laboratories for testing models on the control of community structure. For example, the relative importance of stability versus disturbance and recruitment versus predation in determining community structure is being studied within the reef setting. Modern reefs are economically significant resources, particularly for many developing nations in the tropics. Reefs and the associated lagoonal sea-grass beds serve as important nurseries and habitats for many fish and invertebrates. The standing crop of fish immediately over reefs is much 569
Reefs higher than that of adjacent open shelf areas. Reef organisms may one day provide an important source of pharmaceutical compounds, such as prostaglandins, which may be extracted from gorgonians (octocorals). In addition, research has focused upon the antifouling properties exhibited by certain reef encrusters. Reefs also provide recreational opportunities for snorkelers and for scuba divers, a fact that many developing countries are utilizing to promote their tourist industries. Finally, reefs serve to protect shorelines from wave erosion. Because of the highly restricted environmental tolerances of reef organisms, the occurrence of reefs in ancient strata enables fairly confident estimation of paleolatitude, temperature, depth, salinity, and water clarity. In addition, depth- or turbulence-related variation in growth form (mounds in very shallow water, branches at intermediate depths, and plates at greater depths) enables even more precise estimation of paleobathymetry or turbulence levels. Finally, buried ancient reefs are often important reservoir rocks for hydrocarbons and thus are important economic resources. W. David Liddell See also: Defense mechanisms; Marine biomes; Ocean pollution and oil spills; Phytoplankton. Sources for Further Study Birkeland, Charles, ed. Life and Death of Coral Reefs. New York: Chapman and Hall, 1997. Cousteau, Jacques-Yves, and Philippe Diolé. Life and Death in a Coral Sea. Translated by J. F. Bernard. Garden City, N.Y.: Doubleday, 1971. Darwin, Charles. The Structure and Distribution of Coral Reefs. 1851. Reprint. Berkeley: University of California Press, 1962. Davidson, Osha Gray. The Enchanted Braid: Coming to Terms with Nature on the Coral Reef. New York: Wiley, 1998. Frost, S. H., M. P. Weiss, and J. B. Sanders, eds. Reefs and Related Carbonates: Ecology and Sedimentology. Tulsa, Okla.: American Association of Petroleum Geologists, 1977. Goreau, Thomas F., et al. “Corals and Coral Reefs.” Scientific American 241 (August, 1979): 16. Jones, O. A., and R. Endean, eds. Biology and Geology of Coral Reefs. 4 vols. New York: Academic Press, 1973-1977. Kaplan, Eugene H. A Field Guide to Coral Reefs of the Caribbean and Florida, Including Bermuda and the Bahamas. Boston: Houghton Mifflin, 1988. Keating, Barbara H., et al., eds. Seamounts, Islands, and Atolls. Washington, D.C.: American Geophysical Union, 1987. 570
Reefs Köhler, Annemarie, and Danja Köhler. The Underwater Explorer: Secrets of a Blue Universe. New York: Lyons Press, 1997. National Geographic Society. Jewels of the Caribbean Sea: A National Geographic Special. Video. Washington, D.C.: Author, 1994. Newell, Norman D. “The Evolution of Reefs.” Scientific American 226 (June, 1972): 12, 54-65. Wood, Rachel. Reef Evolution. New York: Oxford University Press, 1999.
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REFORESTATION Type of ecology: Restoration and conservation ecology Reforestation is the growth of new trees in an area that has been cleared for human activities. It can occur naturally or be initiated by people.
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any areas of the eastern United States, such as the New England region, reforested naturally in the nineteenth and early twentieth centuries after farmland that had been abandoned was allowed to lie fallow for decades. After an area has been logged, environmentalists, as well as the commercial logging industry, advocate planting trees rather than waiting for natural regrowth because the process of natural regeneration can be both slow and unpredictable. In natural regeneration, the mixture of trees in an area may differ significantly from the forest that preceded it. For example, when nineteenth century loggers clear-cut the white pine forests of the Great Lakes region, many logged-over tracts grew back primarily in mixed hardwoods. Land that has been damaged by industrial pollution or inefficient agricultural practices sometimes loses the ability to reforest naturally. In some regions of Africa, soils exposed by slash-and-burn agriculture contain high levels of iron or aluminum oxide. Without a protective cover of vegetation, even under cultivation, soil may undergo a process known as laterization. Laterite is a residual product of rock decay that makes soil rock-hard. Such abandoned farmland is likely to remain barren of plant life for many years. In polluted areas such as former mining districts, native trees may not be able to tolerate the toxins in the soil; in these cases, more tolerant species must be introduced. Safeguarding Timber Resources Reforestation differs from tree farming in that the goal of reforestation is not always to provide woodlands for future harvest. Although tree farming is a type of reforestation (trees are planted to replace those that have been removed), generally only one species of tree is planted, with explicit plans for its future harvest. The trees are seen first as a crop and only incidentally as wildlife habitat or a means of erosion control. As foresters have become knowledgeable about the complex interactions within forest ecosystems, however, tree farming methods have begun to change. Rather than monocropping (planting only one variety of tree), the commercial forest industry has begun planting mixed stands. Trees 572
Reforestation that possessed no commercial value, once considered undesirable weed trees, are now recognized as nitrogen fixers necessary for the healthy growth of other species. In addition to providing woodlands for possible use in commercial forestry, goals of reforestation include wildlife habitat restoration and the reversal of environmental degradation. Early Efforts Reforestation to replace trees removed for commercial purposes has been practiced in Western Europe since the late Middle Ages. English monarchs, including Queen Elizabeth I, realized that forests were a vanishing resource and established plantations of oaks and other hardwoods to ensure a supply of ship timbers. Similarly, Sweden created a corps of royal foresters to plant trees and watch over existing woodlands. These early efforts at reforestation were inspired by the reduction of a valuable natural resource. By the mid-nineteenth century it was widely understood that the removal of forest cover contributes to soil erosion, water pollution, and the disappearance of many species of wildlife.
Clear-cutting removes all the trees on a tract of land, leaving none standing. At one time a standard practice in logging, it has become one of the most controversial harvesting techniques used in modern logging. With its windrows of slash and debris, a clear-cut tract of land may appear as though a catastrophic event has devastated the landscape. (PhotoDisc) 573
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The laborious process of planting new trees, combined with the time required for those trees to grow, highlights the need to eliminate clear-cutting as a means of harvesting timber. Reforestation also requires careful reconstruction of the forest community in all its variety, in order to provide habitat for many forms of wildlife. Simple “tree farming,” by contrast, is aimed at growing stands of a single species of tree for later harvesting. (PhotoDisc)
Ecological and Environmental Aspects Water falling on hillsides made barren by clear-cutting timber washes away topsoil and causes rivers to choke with sediment, killing aquatic life. Without trees to slow the flow of water, rain can also run off slopes too quickly, causing rivers to flood. For many years, soil conservationists advocated reforestation as a way to counteract the ecological damage caused by erosion. In the mid-twentieth century, scientists established the vital role that trees, particularly those in tropical rain forests, play in removing carbon dioxide from the earth’s atmosphere through the process of photosynthesis. Carbon dioxide is a greenhouse gas: It helps trap heat in the atmosphere. As forests disappear, the risk of global warming—caused in part by an increase in the amount of carbon dioxide in the atmosphere—becomes greater. Since the 1980’s, scientists and environmental activists concerned about global warming have joined foresters and soil conservationists in urging that for every tree removed anywhere, whether to clear land for development or to harvest timber, replacement trees be planted. As the area covered by tropical rain forests shrinks in size, the threat of irreversible damage to the global environment becomes greater. 574
Reforestation Reforestation Programs In 1988 American Forests, an industry group, established the Global ReLeaf program to encourage reforestation efforts in an attempt to combat global warming. In addition to supporting reforestation efforts by government agencies, corporations, and environmental organizations, Global ReLeaf and similar programs encourage people to practice reforestation in their own neighborhoods. Trees serve as a natural climate control, helping to moderate extremes in temperature and wind. Trees in a well-landscaped yard can reduce a homeowner’s energy costs by providing shade in the summer and serving as a windbreak during the winter. Global ReLeaf is one of many programs that support reforestation efforts. Arbor Day, an annual day devoted to planting trees for the beautification of towns or the forestation of empty tracts of land, was established in the United States in 1872. The holiday originated in Nebraska, a prairie state that seemed unnaturally barren to homesteaders used to eastern woodlands. Initially emphasizing planting trees where none had existed before, Arbor Day is observed in U.S. public schools to educate young people about the importance of forest preservation. Organizations such as the National Arbor Day Foundation provide saplings (young trees) to schools and other organizations for planting in their own neighborhoods. Nancy Farm Männikkö See also: Biodiversity; Biomass related to energy; Conservation biology; Deforestation; Endangered plant species; Erosion and erosion control; Forest fires; Forest management; Forests; Grazing and overgrazing; Integrated pest management; Multiple-use approach; Old-growth forests; Rain forests; Restoration ecology; Species loss; Sustainable development; Urban and suburban wildlife; Wildlife management. Sources for Further Study Cherrington, Mark. Degradation of the Land. New York: Chelsea House, 1992. TreePeople, with Andy Lipkis and Katie Lipkis. The Simple Act of Planting a Tree: A Citizen Forester’s Guide to Healing Your Neighborhood, Your City, and Your World. Los Angeles: St. Martin’s Press, 1990. Weiner, Michael. Plant a Tree: Choosing, Planting, and Maintaining This Precious Resource. New York: Wiley, 1992.
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REPRODUCTIVE STRATEGIES Types of ecology: Behavioral ecology; Population ecology Reproductive strategies are a set of attributes involved in an organism’s maximizing its reproductive success. Theoretical and experimental studies of reproductive strategies reveal why various reproductive patterns have evolved.
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he concept of reproductive strategies is closely related to that of natural selection. Natural selection results in the individuals within a population, under a given set of environmental circumstances, being more likely to pass on their genes to future generations. By this process, the gene pool (genetic makeup) of the population is altered over time. An organism’s fitness can be assessed by evaluating two key characteristics: survival and reproductive success. The organism’s reproductive strategy, then, is the blend of traits enabling it to have the highest overall reproductive success. Application of the term “reproductive strategy” has also been extended to describe patterns beyond individual organisms: populations, species, and even entire groups of similar species, such as carnivorous mammals. Examination of reproductive strategies is part of the larger study of lifehistory evolution, which attempts to understand why a given set of basic traits has evolved. These traits include not only those pertaining to reproduction but also those such as body size and longevity. To consider a reproductive strategy appropriately, one must view it within the context of the organism’s overall life history, precisely because these traits (particularly body size) often affect reproductive traits. One should also evaluate the role that the organism’s ancestry plays in these processes. A species’ evolutionary history can have a profound effect on its current attributes. Reproductive Traits and Behaviors A reproductive strategy consists of a collection of basic reproductive traits, including litter, or “clutch,” size (the number of offspring produced per birth), the number of litters per year, the number of litters in a lifetime, and the time between litters, gestation, or pregnancy length. The age of the mother’s first pregnancy is also a consideration. Another trait is the degree of development of the young at birth. In different species, mothers put varying levels of time and energy into the production of either relatively immature, or altricial, offspring or offspring that are well developed, or precocial. Reproductive strategies also consist of behavioral elements, such as the 576
Reproductive strategies mating system and the amount of parental care. Mating systems include monogamy (in which one male is mated to one female) and polygamy (in which an individual of one sex is mated to more than one from the other). The type of polygamy when one male mates with several females is called polygyny; the reverse is known as polyandry. Finally, physiological events such as those involved in ovulation (what happens when the egg or eggs are shed from the ovary) may also be used to characterize a reproductive strategy. Some mammals are spontaneous ovulators. Females shed their eggs during the reproductive cycle without any physical stimulation. Other mammalian species are induced ovulators—a female ovulates only after being physically stimulated by a male during copulation. These patterns, induced and spontaneous ovulation, may be regarded as alternate reproductive strategies, each enabling a type of species to reproduce successfully under certain conditions. The overall effectiveness of a reproductive strategy is important to consider with respect to the relative success of the offspring (even those in future generations) in leaving their own descendants. A sound reproductive strategy results in increased fitness. An organism’s fitness as it affects the population’s gene pool may not be adequately assessed until several generations have passed. The r and K Selection Model The model of r and K selection is the most widely cited description of how certain reproductive traits are most effective under certain environmental conditions. To appreciate this model, an understanding of elementary population dynamics is needed. At the early stages of a population’s growth, the rate of addition of new individuals (designated r) tends to be slow. After a sufficient number of individuals is reached, the growth rate can increase sharply, resulting in a boom phase. In most environments, however, unrestrained growth cannot continue indefinitely. Critical resources— food, water, and protective cover—become more scarce as the environment’s carrying capacity (K) is approached. Carrying capacity is the maximal population size an area can support. When the population approaches this level, growth rate slows as individuals now have fewer resources to convert into the production of new offspring. This pattern is defined as density-dependent population growth—the density or number of individuals per area that influences its growth. This description of population dynamics is also referred to as logistic growth and was conceived by the Belgian mathematician Pierre-François Verhulst in the early nineteenth century. It has successfully described population growth in many species. 577
Reproductive strategies The r and K selection model was presented by Robert H. MacArthur and Edward O. Wilson in their influential book, The Theory of Island Biogeography (1967). They argued that in the early phase of a population’s growth, individuals should evolve traits associated with high reproductive output. This enables them to take advantage of the relatively plentiful supply of food. The evolution of such traits is called r selection, after the high population growth rates occurring during this phase. They also suggested that, as the carrying capacity was approached, individuals would be selected that could adjust their lives to the now reduced circumstances. This process is called K selection. Such individuals should be more efficient in the conversion of food into offspring, producing fewer young than those living in the population’s early phase. In a sense, a shift from productive to efficient individuals occurs as the population grows. Other biologists, most notably Eric Pianka, have extended this concept of r and K selection to entire species rather than only to individuals at different stages of a population’s growth. Highly variable or unpredictable climates commonly create situations in which population size is first diminished but then grows rapidly. Species commonly occurring in such environments are referred to as r strategists. Those living in more constant,
Male seals can successfully defend areas containing from eighty to a hundred females from other males. Very dense clusters of females, however, attract too many males for one male to monopolize. When this happens, the largest male typically dominates the rest and maintains disproportionate access to females. (PhotoDisc) 578
Reproductive strategies relatively predictable climates are less likely to go through such an explosive growth phase. These species are considered to be K strategists. According to this scheme, an r strategist is characterized by small body size, rapid development, high rate of population increase, early age of first reproduction, a single or few reproductive events, and many small offspring. The K strategist has the opposite qualities—large size, slower development, delayed age of first reproduction, repeated reproduction, and fewer, larger offspring. Various combinations of r and K traits may occur in a species, and few are entirely r- or K-selected. Populations of the same species commonly occupy different habitats during their lives or across their geographic ranges. An organism might thus shift strategies in response to environmental changes—they may, however, be constrained by their phylogeny or ancestry in the degree to which their strategies are flexible. Criticism of the Model Because the r and K model of reproductive strategies seems to explain patterns observed in nature, it has become widely accepted. It has also met with considerable criticism. Charges against it include arguments that the logistic population-growth model (on which the r and K strategies model is based) is too simplistic. Another is that cases of r and K selection have not been adequately tested. Ecologist Mark Boyce has persuasively argued that for the r and K model to be most useful it must be viewed as a model of how population density affects life-history traits. Within this framework, also called density-dependent natural selection, the concept of r and K selection remains true to the one that MacArthur and Wilson originally proposed. Boyce suggests that the ability of r and K selection to explain reproductive strategies will have the best chance of being realized when approached in this fashion. In addition to the r and K model, there are many other ways of describing reproductive strategies. For example, some species, such as the Chinook salmon, are semelparous: They reproduce only once before dying. The alternate is to be iteroparous—in which an organism experiences two or more reproductive events over its life span. If juvenile death rates are high, an individual might be better off reproducing on several occasions rather than only once. (This reproductive strategy is referred to as “bet-hedging.”) Finally, it has also been useful to evaluate reproductive strategies based on the proportion of energy that goes into reproduction relative to that devoted to all other body functions. This mode of analysis addresses such considerations as reproductive effort and resource allocation. 579
Reproductive strategies Studying Reproductive Strategies Initially, one who studies the reproductive strategy of an organism should attempt to characterize its reproduction fully. The sample examined must be representative of the population under consideration—it should account for the variability of the traits being measured. Studies can involve any of several approaches. Short-term laboratory studies can uncover some hard-to-observe features, but there is no substitute for long-term field research. By studying an organism’s reproduction in nature, a biologist has the best chance of determining how its reproduction is shaped by an environment. If the research is performed over several seasons or years, patterns of variability can be better understood. This is important in determining how the physical environment influences reproductive traits. After data have been systematically collected, it might then be possible to characterize a reproductive strategy. Imagine that a mouse population becomes established in a previously uninhabited area and that the population has a high reproductive rate (it produces large litters). The young develop quickly and produce many young themselves. Because of this combination of circumstances, one might consider the reproductive strategy to be r-selected since the population has a high reproductive output in an unexploited area. Though the concept of r and K strategies is problematic, it still is common to typify a strategy as r- or K-selected based upon this approach. Because a reproductive strategy needs to be seen as part of an organism’s overall life history, however, other things should be measured to understand it fully. These may include the life span and population attributes such as survival patterns. Values should be taken for different age groups to characterize the population’s strategy. Correlational analysis is a statistical procedure that is used to evaluate reproductive strategies. Through such a methodology, one assesses the degree of association between two variables or factors. This may involve relationships between two reproductive variables or between a reproductive and an environmental variable—for example, to determine if there is a significant correlation between litter size and decreasing body size in mammals. If one were found to occur, the conclusion that smaller species typically have larger litters might be drawn, which is, in fact, true. Such an analysis enables the characterization of a change in reproductive strategy based on body size. Simply establishing a correlation does not prove that causation has occurred—it does not automatically mean that one factor is responsible for the expression of the other. Multivariate statistical procedures are also used to analyze reproductive strategies. These allow the determination of how groups of reproduc580
Reproductive strategies tive traits are associated and of how they can be explained by several factors. One might determine that a certain bird species produces its greatest number of young, and that the young grow most rapidly, at northern locations having high snow levels. Such an approach is often needed in dealing with reproductive strategies—a combination of traits typically requires explanation. Reproduction and Survivial The characterization of an organism’s reproductive strategy involves more than an understanding of reproductive traits. There is a successful process by which offspring are produced, and reproductive success is one of the two principal measures of fitness—the other is survival. Because a successful reproductive strategy ultimately results in high fitness, any discussion of these strategies bears directly on issues of natural selection and evolution. An organism’s reproductive strategy represents perhaps the most significant way the organism is adapted to its environment. A successful reproductive strategy represents a successful mode of passing genes on to the next generation, so traits associated with a reproductive strategy are under intense natural selection pressure. If environmental conditions change, the original strategy may no longer be as successful. To the extent that an organism can shift its reproductive strategy as circumstances change, its genes will persist. The study of reproductive strategies has helped scientists understand why certain modes of reproduction occur, based upon observations of a species itself and of its environment. An understanding of reproductive strategies may also be of some practical use. An organism’s reproduction directly influences its population dynamics. If an animal has small litters and is at an early age at first reproduction, its population should grow at a concomitantly high rate. These and other components of reproduction may strongly affect a species’ population growth. A knowledge of how reproduction influences population dynamics can be important in wildlife management activities, which can range from strict preservation efforts to overseeing trophy hunting. Samuel I. Zeveloff See also: Adaptive radiation; Biodiversity; Biogeography; Clines, hybrid zones, and introgression; Convergence and divergence; Demographics; Displays; Ethology; Extinctions and evolutionary explosions; Gene flow; Genetic diversity; Genetic drift; Human population growth; Insect societies; Natural selection; Nonrandom mating, genetic drift, and mutation; 581
Reproductive strategies Population analysis; Population fluctuations; Population genetics; Population growth; Punctuated equilibrium vs. gradualism; Speciation; Territoriality and aggression. Sources for Further Study Austin, C. R., and R. V. Short, eds. The Evolution of Reproduction. New York: Cambridge University Press, 1976. Boyce, Mark S. “Restitution of r- and K-Selection as a Model of DensityDependent Natural Selection.” Annual Review of Ecology and Systematics 15 (1984): 427-447. Clutton-Brock, T. H., F. E. Guiness, and S. D. Albon. Red Deer: Behavior and Ecology of Two Sexes. Chicago: University of Chicago Press, 1982. Ferraris, Joan D., and Stephen R. Palumbi, eds. Molecular Zoology: Advances, Strategies, and Protocols. New York: Wiley-Liss, 1996. MacArthur, Robert H., and Edward O. Wilson. The Theory of Island Biogeography. Princeton, N.J.: Princeton University Press, 1967. Pianka, Eric R. Evolutionary Ecology. 6th ed. New York: Harper & Row, 2000. Wrangham, Richard W., W. C. McGrew, Frans B. M. De Waal, and Paul G. Heltne, eds. Chimpanzee Cultures. Cambridge, Mass.: Harvard University Press, 1996.
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RESTORATION ECOLOGY Type of ecology: Restoration and conservation ecology Restoration ecology is concerned with converting ecosystems that have been modified or degraded by human activity to a state approximating their original condition.
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ederal laws often dictate ecological restoration following strip mining, construction, and other activities that alter the landscape. As a part of the management of natural areas that have been disturbed to some degree, several options are available. One is to do nothing but protect the property, allowing nature to take its course. In the absence of further disturbances, one would expect the area to undergo the process of ecological succession. Theoretically, an ecosystem similar to that typical of the region, and including an array of organisms, would be expected to return. One might, therefore, ask why ecological restoration is mandated. For one thing, succession is often a process requiring long periods of time. As an example, the return of a forest following the destruction of the trees and the removal of the soil would require more than one century. Also, ecosystems resulting from succession may be lacking in species typical of the region. This is true when succession is initiated in an area where many exotic (alien) species are present or where certain native species have been eliminated. Succession can produce a new ecosystem with a biodiversity comparable to the original one only if there is a local source of colonizing animals and seeds of native plants. Also, satisfactory recovery by succession is unlikely if the soil has been heavily polluted by heavy metals or other substances caused by industrial land use. The Restoration Process Once it has been decided that a given ecosystem is to be restored, success requires that a plan be designed and followed. Although the specifics may vary greatly, all restoration projects should follow five basic steps: Envision the end result, consult relevant literature and solicit the advice of specialists, remove or mitigate any current disturbances to the site, rehabilitate the physical habitat, and restore indigenous plants and animals. Much can be learned from restoration projects that have been conducted in various parts of the world involving a wide variety of ecosystems. A classic ecological restoration of a prairie was conducted in Wisconsin beginning in the 1930’s. Because most North American prairies have 583
Restoration ecology
Restoration ecology enlists human intervention to return habitats and ecosystems to their former state, particularly when natural processes such as ecological succession would take far longer than the original destruction of the community. Such destruction is often the result of human activity such as clear-cutting, strip-mining, large-scale agriculture, or other development. (PhotoDisc)
been converted to agricultural uses, many opportunities exist for prairie restoration. In such projects it is often necessary to eliminate exotic plants by mechanical means or by application of herbicides. Native prairie grasses and forbs can be established by transplantation or from seed. It may also be necessary to introduce native fauna from nearby areas. Periodic prescribed burning is often necessary to simulate natural fires common in prairies. After decades of loss of wetlands in the United States, governmental policy is now “no net loss.” Thus, when a wetland is destroyed by development, it is required that a new wetland be created as compensation. Before introducing native biota, it is necessary to alter the hydrology of the new site. Thomas E. Hemmerly See also: Biological invasions; Conservation biology; Deforestation; Endangered animal species; Endangered plant species; Erosion and erosion control; Forest management; Grazing and overgrazing; Integrated pest management; Invasive plants; Landscape ecology; Multiple-use approach; 584
Restoration ecology Old-growth forests; Reforestation; Succession; Sustainable development; Urban and suburban wildlife; Waste management; Wildlife management; Zoos. Sources for Further Study Harper, David. Eutrophication of Freshwaters: Principles, Problems, and Restoration. London: Chapman & Hall, 1992. Hey, Donald L., and Nancy S. Philippi. A Case for Wetland Restoration. New York: Wiley, 1999.
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SAVANNAS AND DECIDUOUS TROPICAL FORESTS Types of ecology: Biomes; Ecosystem ecology Savannas are areas of continuous grass or sedge cover beneath trees that range from scattered, twisted, and gnarled individuals to open woodlands. Deciduous tropical forests have continuous to open forest cover and undergo a leafless period during a seasonally lengthy dry season.
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here the annual rainfall in tropical regions is less than 2,000 millimeters and three to six months out of the year are dry, savannas and deciduous forests are common. Deciduous tropical forests often occur where the annual rainfall is less than that of savannas. Together, the two biomes are referred to here as the dry tropical biome. A pronounced pattern of seasonally wet and dry periods is the most important factor affecting the distribution of these types of plant cover. Higher soil fertility favors forest over grasses and savanna such as in the cerrado of Brazil, which occurs only on certain geological formations and low-nutrient soils. Fire has been a dominant feature of these biomes, and human influences—fires, agriculture, and grazing of animals—have interacted with climate to produce a varied landscape. The dry tropical biome is most geographically widespread on the continents of Africa, South America, and Australia, with smaller enclaves in Asia. The world’s largest expanses of dry forest—the Brachystegia woodland across Central Africa, the cerrado (savanna) and caatinga (dry forest) of the Amazon basin, and much of interior Australia—are notable examples. “Elephant grass savanna,” with tall grasses up to 4 meters tall and scattered trees, occurs exclusively in Africa. In the West Indies, dry forest occurs in rain-shadow zones on the leeward sides of islands affected by the tradewinds. Plant Adaptations and Diversity of Life-Forms As the rainfall decreases below 2,000 millimeters, and especially below 1,000 millimeters, the height of the forest decreases and the proportion of trees that are deciduous increases. In the dry tropics, leaf fall occurs in response to drought, and therefore the lengthy dry season becomes a selective pressure to which plants have adapted. Tree leaves tend to be compound, with small leaflets that help plants exchange heat with their surroundings better than large, simple leaves; rates of leaf respiration and 586
Savannas and deciduous tropical forests transpiration are thereby reduced. Sclerophyllous leaves are common, aiding in moisture retention, and the drier, more open woodlands may have cacti or other succulents. The dry forest is far less species-rich than the rain forest, but the diversity of life-forms and the proportion of endemics are greater. For example, dry forests may contain xerophytic (dry-adapted) evergreens, either obligatively or facultatively deciduous trees, trees with photosynthetic bark, plants that use the Crassulacean acid metabolism (CAM) photosynthesis as well as C3 and C4 dicots, grasses, bromeliads, lianas, epiphytes, and hemiparasites. Trees from Fabaceae (the legume family) are the most well-represented family among trees. Dry forests contain a higher proportion of wind-dispersed species than wetter forests, and many trees will have their flowering and fruiting controlled by the duration and intensity of the dry season. Synchronous flowering within and among species is common, and many produce seed during the dry season. Flowers are often conspicuous and visited by specialized pollinators such as hawkmoths, bats, and bees. It is incorrect to generalize about savannas and dry tropical forests because, although they both occur in the drier tropics, the two vegetation
Savannas are landscapes of dense grass and scattered trees, such as these yellow fever trees growing in Nakura National Park in Kenya. Common on the continent of Africa, savannas are also found in India, Australia, and the northern part of South America. (Corbis) 587
Savannas and deciduous tropical forests types occur in different habitats and are adapted differently to their respective environments. Trees of the cerrado in northeast Brazil are deeply rooted, tap groundwater, and have high rates of transpiration. Drought here is atmospheric, as water is always available below two meters of soil depth. The deciduous caatinga of central Brazil, however, receives only 500 millimeters of rain yearly, and transpiration of trees is low. Here, trees suffer significant water deficits during the long, dry season, are truly xerophytic, and exhibit classic adaptations to drought. Trees of the cerrado have a number of adaptations that confer resistance to fire. These include a thick, corky bark, the ability to form adventitious roots from buds on roots following the burning of the stem, and the cryptophyte or hemicryptophyte life-form (cryptophytes produce buds underground). Many herbaceous species are induced to flower by fire. Human Impacts and Conservation Fires have occurred in the Brazilian cerrado for thousands of years, based on carbon 14 dating of charcoal fragments. Fire is thus an environmental factor to which the vegetation has become adapted. Yet, the human influence has been to increase the incidence of fire. The cerrado has changed as a result to a more open form of plant cover with fewer trees and shrubs. In addition, timber extraction, charcoal production, and ranching have altered the savanna landscape. The ability of belowground organs to survive such types of disturbance has increased the ability of the cerrado to persist. Yet it is estimated that 50 percent of the cerrado has been destroyed, much of this the result of clearing for agriculture since the 1960’s. Because of better soils and fewer pests, humans in tropical areas of Central America have mostly chosen the dry and moist life zones as places to live rather than the wetter rain-forest zones. As a result, dry forest ecosystems have been subject to massive disturbance. Today, only a small fraction of the original dry forest remains. Fire has been used as a means of clearing the forest for farming, but, unlike the savanna, the dry forest is not adapted to fire. At Guanacaste, Costa Rica, a well-known tropical conservation project, restoration of dry forest is dependent on controlling annual fires set by farmers and ranchers and supporting the return of forest vegetation to dry areas. In Africa, large areas of dry forest are burned annually by farmers, and areas of dense, dry forest have been converted to more open forest or even savanna. Sustainable land-use systems are urgently needed for dry tropical regions. Allan P. Drew 588
Savannas and deciduous tropical forests See also: Biomes: determinants; Biomes: types; Forests; Grasslands and prairies; Habitats and biomes; Rangeland; Reforestation. Sources for Further Study Allen, W. Green Phoenix: Restoring the Tropical Forests of Guanacaste, Costa Rica. New York: Oxford University Press, 2001. Bullock, S. H., H. A. Mooney, and E. Medina. Seasonally Dry Tropical Forests. New York: Cambridge University Press, 1995. Rizzini, C. T., A. F. C. Filho, and A. Houaiss. Brazilian Ecosystems. Rio de Janeiro: ENGE-RIO, Index Editora, 1988. Silver, Donald M. African Savanna. New York: McGraw-Hill, 1997.
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SLASH-AND-BURN AGRICULTURE Types of ecology: Agricultural ecology; Ecotoxicology Slash-and-burn agriculture, also called swidden agriculture, is a practice in which forestland is cleared and burned for use in crop and livestock production. While yields are high during the first few years, they rapidly decline in subsequent years, leading to further clearing of nearby forestland.
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lash-and-burn agriculture has been practiced for many centuries among people living in tropical rain forests. Initially, this farming system involved small populations. Therefore, land could be allowed to lie fallow (unplanted) for many years, leading to the full regeneration of the secondary forests and hence a restoration of the ecosystems. During the second half of the twentieth century, however, several factors led to drastically reduced fallow periods. In some places such fallow systems are no longer in existence, resulting in the transformation of forests into shrub and grasslands, negative effects on agricultural productivity for small farmers, and disastrous consequences to the environment. Among the factors that have been responsible for reduced or nonexistent fallow periods are increased population in the tropics, increased demand for wood-based energy, and, perhaps most important, the increased worldwide demand for tropical commodities during the 1980’s and 1990’s, especially for products such as palm oil and natural rubber. These last two factors have helped industrialize slash-and-burn agriculture, which was practiced for centuries mainly by small farmers. Ordinarily, small farmers are able to control their fires so that they are similar to a small forest fire triggered by lightning in the northwestern or southeastern United States. However, the continued reduction in fallow periods, coupled with increased burning by subsistence farmers and large agribusiness, especially in Asia and Latin America, is resulting in increased environmental concern. While slash-and-burn agriculture seldom takes place in temperate regions, some agricultural burning occurs in the Pacific Northwest of the United States, where it is estimated that three thousand to five thousand agricultural fires are set each year in Washington State alone. These fires also create problems for human health and the environment. Habitat Fragmentation One of the most easily recognized results of slash-and-burn agriculture is habitat fragmentation, which leads to a significant loss of the vegetation 590
Slash-and-burn agriculture needed for the maintenance of effective gaseous exchange in tropical regions and throughout the world. For every acre of land lost to slash-andburn agriculture, 10 to 15 acres (4 to 6 hectares) of land are fragmented, resulting in the loss of habitat for wildlife, plant species, and innumerable macro- and microorganisms yet to be identified. This also creates problems for management and wildlife conservation efforts in parts of the world with little or no resources to feed their large populations. Fragmentation has also led to intensive discussions on global warming. While slash-andburn agriculture by itself is not completely responsible for global warming, the industrialization of the process could make it a significant component of the problem, as more and more vegetation is fragmented. Human Health The impact of slash-and-burn agriculture on human health and the environment is best exemplified by the 1997 Asian fires that resulted from such practices. Monsoon rains normally extinguish the fires set by farmers, but a strong El Niño weather phenomenon delayed the expected rains, and the fires burned out of control for months. Thick smoke caused severe health problems. It is estimated that more than 20 million people in Indonesia alone were treated for asthma, bronchitis, emphysema, and eye, skin, and cardiovascular problems as a result of the fires. Similar problems have been reported for smaller agricultural fires. Three major problems are associated with air pollution: particulate matter, pollutant gases, and volatile organic compounds. Particulate compounds of 10 microns or smaller that are inhaled become attached to the alveoli and other blood cells, resulting in severe illness. Studies by the U.S. Environmental Protection Agency (EPA) and the University of Washington indicate that death rates associated with respiratory illnesses increase when fine particulate air pollution increases. Meanwhile, pollutant gases such as carbon monoxide, nitric oxide, nitrogen dioxide, and sulfur dioxide become respiratory irritants when they combine with vapor to form acid rain or fog. Until the Asian fires, air pollutants stemming from the small fires of slash-and-burn agriculture that occur every planting season often went unnoticed. Thus, millions of people in the tropics experience environmental health problems because of slash-and-burn agriculture that are never reported. Soil and Water Quality The loss of vegetation that follows slash-and-burn agriculture causes an increased level of soil erosion. The soils of the humid tropics create a hard pan underneath a thick layer of organic matter. Therefore, upon the re591
Slash-and-burn agriculture
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moval of vegetation cover, huge areas of land become exposed to the torrential rainfalls that occur in these regions. The result is severe soil erosion. As evidenced by the impact of Hurricane Mitch on Honduras during 1998, these exposed lands can give rise to large mudslides that can lead to significant loss of life. While slash-and-burn agriculture may not be the ultimate cause for sudden mud slides, it does predispose these lands to erosional problems. Associated with erosion is the impact of slash-and-burn agriculture on water quality. As erosion continues, sedimentation of streams increases. This sedimentation affects stream flow and freshwater discharge for catchment-area populations. Mixed with the sediment are minerals such as phosphorus and nitrogen-related compounds that enhance algal growth in streams and estuaries, which depletes the supply of oxygen that aquatic organisms require to survive. Although fertility is initially increased on noneroded soils, nutrient deposition and migration into drinking water supplies continues to increase. Controlling Slash-and-Burn Agriculture Given the fact that slash-and-burn agriculture has significant effects on the environment not only in regions where it is the mainstay of the agricultural 592
Slash-and-burn agriculture systems but also in other regions of the world, it has become necessary to explore different approaches to controlling this form of agriculture. However, slash-and-burn agriculture has evolved into a sociocultural livelihood; therefore, recommendations must be consistent with the way of life of a people who have minimal resources for extensive agricultural systems. Among the alternatives are new agroecosystems such as agroforestry systems and sustainable agricultural systems that do not rely so much on the slashing and burning of forestlands. These systems allow for the cultivation of agronomic crops and livestock within forest ecosystems. This protects soils from being eroded. Another possibility is the education of small rural farmers, absentee landlords, and big agribusiness concerns in developing countries to understand the environmental impact of slashand-burn agriculture. While small rural farmers may not have the resources for renovating utilized forestlands, big business can organize ecosystems restoration, as has been done in many developed nations of the world. Oghenekome U. Onokpise See also: Biopesticides; Deforestation; Erosion and erosion control; Forest management; Forests; Global warming; Grazing and overgrazing; Multipleuse approach; Pesticides; Rangeland; Savannas and deciduous tropical forests; Sustainable development. Sources for Further Study Jordan, C. F. An Amazonian Rain Forest: The Structure and Function of a Nutrient Stressed Ecosystem and the Impact of Slash and Burn Agriculture. Boca Raton, Fla.: CRC Press, 1990. Simons, L. M., and M. Yamashita. “Indonesia’s Plague of Fire.” National Geographic 194 (August, 1998): 100-120. Terborgh, J. Diversity and the Tropical Rain Forest. New York: Scientific American Library, 1992. Youth, Howard. “Green Awakening in a Poor Country.” World Watch 11, no. 5 (September/October, 1998): 28-37.
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SOIL Types of ecology: Agricultural ecology; Ecosystem ecology; Soil ecology Soils are complex chemical factories. Regardless of the type of soil—and twelve types of soil are identified by the U.S. Department of Agriculture—chemical processes such as plant growth, organic decay, mineral weathering, and water purification, as well as living organisms, constitute the ecosystem commonly referred to as soil.
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oil chemistry has been studied as long as there has been sustainable agriculture. Although they did not recognize it as such, those first successful farmers who plowed under plant stalks, cover crops, or animal wastes were actively managing the soil chemistry of their fields. These early farmers knew that to have productive farms in one location season after season, they had to return something to the soil. It is now understood that soil chemistry is a complex of chemical and biochemical reactions. The most obvious result of this complex of reactions is that some soils are very fertile whereas other soils are not. Soil itself is a unique environment because all the “spheres”—the atmosphere, hydrosphere, geosphere, and biosphere—are intimately mixed there. For this reason, soil and soil chemistry are extremely important. Rock Weathering Soil chemistry begins with rock weathering. The minerals composing a rock exposed at the earth’s surface are continually bathed in a shower of acid rain—not necessarily polluted rainwater but naturally occurring acid rain. Each rain droplet forming in the atmosphere absorbs a small amount of carbon dioxide gas. Some of the dissolved carbon dioxide reacts with the water to form a dilute solution of carbonic acid. A more concentrated solution of carbonic acid is found in any bottle of sparkling water. Most of the common rock-forming minerals, such as feldspar, will react slowly with rainwater. Some of the chemical elements of the mineral, such as sodium, potassium, calcium, and magnesium, are very soluble in rainwater and are carried away with the water as it moves over the rock surface. Other chemical elements of the mineral, such as aluminum, silicon, and iron, are much less soluble. Some of these elements are dissolved in the water and carried away; most, however, remain near the original weathering, where they recombine into new, more resistant minerals. Many of the new minerals are of a type called clays. 594
Soil Clay minerals tend to be very small crystals composed of layers of aluminum and silicon. Between the layers of aluminum and silicon atoms are positively charged ions (cations) of sodium, potassium, calcium, and magnesium. The cations hold the layers of some clays together by electrostatic attraction. In most cases, the interlayer cations are not held very tightly. They can migrate out of the clay and into the water surrounding the clay mineral, to be replaced by another cation from the soil solution. This phenomenon is called cation exchange. The weathering reactions between rainwater and rock minerals produce a thin mantle of clay mineral soil. The depth to fresh, unweathered rock is not great at first, but rainwater continues to fall, percolating through the thin soil and reacting with fresh rock minerals. In this way, the weather-
Soil Horizons
O = organic debris A = topsoil (minerals) B = subsoil (clay, iron oxide, carbonate calcium)
C = regolith (soil base)
Bedrock
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Soil ing front (the line between weathered minerals and fresh rock) penetrates farther into the rock, and the overlying soil gets thicker. Biological Processes Throughout the weathering process, biological processes contribute to the pace of soil formation. In the very early stages, lichens and fungi are attached to what appear to be bare rock surfaces. In reality, they are using their own acids to “digest” the rock minerals. They absorb the elements of the mineral they need, and the remainder is left to form soil minerals. As the soil gets thicker, larger plants and animals begin to colonize. Large plants send roots down into the soil looking for water and nutrients. Some of the necessary nutrients, such as potassium, are available as exchangeable cations on soil clays or in the form of deeper, unweathered minerals. In either case, the plant obtains the nutrients by using its own weathering reaction carried on through its roots. The nutrient elements are removed from minerals and become part of the growing plant’s tissue. Without a way to replenish the nutrients in the soil, the uptake of nutrients by plants will eventually deplete the fertility of the soil. Nutrients are returned to the soil through the death and decay of plants. Microorganisms in the soil, such as bacteria and fungi, speed up the decay. Since the bulk of the decaying plant material is found at the surface (the dead plant’s roots also decay), most of the nutrients are released to the surface layer of the soil. Some of the nutrients are carried down to roots deep in the soil by infiltrating rainwater. Most of the nutrients, however, are removed from the water by the shallow root systems of smaller plants. The deeper roots of typically large plants can mine the untapped nutrients at the deep, relatively unweathered soil-rock boundary. The soil and its soil chemistry are now well established, with plants growing on the surface and their roots reaching toward mineral nutrients at depth. Water is flowing through the soil, carrying dissolved nutrients and the soluble by-products of weathering reactions. Soil as an Ecosystem Not to be forgotten in this mix are the microbes, insects, nematodes, worms, and other organisms that, along with fungi and plants, occupy the soil ecosystem. There are at least twelve different classifications of soil recognized by the U.S. Department of Agriculture, and these reflect the many communities that occupy various soil ecosystems. In fact, when ecologists discuss soil as an ecosystem, they are referring not only to the biotic and abiotic components of soil itself but also to the living organisms, from all kingdoms, that occupy, partially occupy, or travel through soil. Disruption 596
Soil to soil by herbicides, polluted water, solid waste, mechanical erosion, and other factors therefore has a reverberating impact not only on the minerals and chemical compounds that form soil but also on all members of the soil ecosystem. Soil Chemistry Soil ecologists and soil chemists are concerned not only with the composition of soil and soil water but also with how that composition changes as the water interacts with the atmosphere, minerals, plants, fungi, animals, and mechanical forces at work on it. Soil and its chemistry can be studied in its natural environment, or samples can be brought into the laboratory for testing. Some tests have been standardized and are best conducted in the laboratory so that they can be compared with the results of other researchers. Most of the standardized tests, such as measures of the soil’s acidity and cation-exchange capacity, are related to measures of the soil’s fertility and its overall suitability for plant growth. These tests measure average values for a soil sample because large original samples are dried and thoroughly mixed before smaller samples are taken for the specific test. Increasingly, soil chemists are looking for ways to study the fine details of soil chemical processes. They know, for example, that soil water chemistry changes as the water percolates through succeeding layers of the soil. The water flowing through the soil during a rainstorm has a different chemical composition from that of water clinging to soil particles, at the same depth, several days later. Finally, during a rainstorm, the water flowing through large cracks in the soil has a chemical composition different from that of the same rainwater flowing through the tiny spaces between soil particles. Sampling Techniques Soil chemists use several sampling techniques to collect the different types of soil water. During a rainstorm, water flows under the influence of gravity. After digging a trench in the area of interest, researchers push several sheets of metal or plastic, called pan lysimeters, into the wall of the trench at specified depths below the surface. The pans have a very shallow V shape. Soil water flowing through the soil collects in the pan, flows toward the bottom of the V, and flows out of the pan into a collection bottle. Comparing the chemical compositions of rainwater that has passed through different thicknesses of soils (marked by the depth of each pan) allows the soil chemist to identify specific soil reactions with specific depths. After the soil water stops flowing, water is still trapped in the soil. The soil water clings to soil particles and is said to be held by tension. Tension water can spend a long time in the soil between rainstorms. During that 597
The Twelve Soil Orders in the U.S. Classification System Soil Order
Features
Alfisols
Soils in humid and subhumid climates with precipitation from 500 to 1,300 millimeters (20 to 50 inches), frequently under forest vegetation. Clay accumulation in the B horizon and available water most of the growing season. Slightly to moderately acid soils.
Andisols
Soils with greater than 60 percent volcanic ash, cinders, pumice, and basalt. They have a dark A horizon as well as high absoption and immobilization of phosphorus and very high cation exchange capacity.
Aridisols
Aridisols exist in dry climates. Some have horizons of lime or gypsum accumulations, salty layers, and A and slight B horizon development.
Entisols
Soils with no profile development except a shallow A horizon. Many recent river floodplains, volcanic ash deposits, severely eroded areas, and sand are entisols.
Gelisols
Soils that commonly have a dark organic surface layer and mineral layers underlain by permafrost, which forms a barrier to downward movement of soil solution. Common in tundra regions of Alaska. Alternate thawing and freezing of ice layers results in special features in the soil; slow decomposition of the organic matter due to cold temperatures results in a peat layer at the surface in many gelisols.
Histosols
Organic soils of variable depths of accumulated plant remains in bogs, marshes, and swamps.
Inceptisols
Soils found in humid climates that have weak to moderate horizon development. Horizon development may have been delayed because of cold climate or waterlogging.
Mollisols
Mostly grassland soils, but with some broadleaf forest-covered soils with relatively deep, dark A horizons, a possible B horizon, and lime accumulation.
Oxisols
Excessively weathered soils. Oxisols are over 3 meters (10 feet) deep, have low fertility, have dominantly iron and aluminum oxide clays, and are acid. Oxisols are found in tropical and subtropical climates.
Spodosols
Sandy leached soils of the cool coniferous forests, usually with an organic or O horizon and a strongly acidic profile. The distinguishing feature of spodosols is a B horizon with accumulated organic matter plus iron and aluminum oxides.
Ultisols
Strongly acid and severely weathered soils of tropical and subtropical climates. They have clay accumulation in the B horizon.
Vertisols
Soils with a high clay content that swell when wet and crack when dry. Vertisols exist in temperate and tropical climates with distinct dry and wet seasons. Usually vertisols have only a deep self-mixing A horizon. When the topsoil is dry, it falls into the cracks, mixing the soil to the depth of the cracks.
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Soil time, it reacts with soil mineral grains and soil microorganisms. Tension water is sampled by placing another type of lysimeter, a tension lysimeter, into the soil at a known depth. A tension lysimeter is like the nozzle of a vaccum cleaner with a filter over the opening. Soil chemists actually vacuum the tension water out of the soil and to the surface for analysis. Determining Isotopic Composition Nonradioactive, stable isotopes of common elements are being used more often by soil chemists to trace both the movement of water through the soil and the chemical reactions that change the composition of the water. Trace stable isotopes behave chemically just the way their more common counterparts do. For example, deuterium, an isotope of hydrogen, substitutes for hydrogen in the water molecule and allows the soil chemist to follow the water’s movements. Similarly, carbon 13 and nitrogen 15 are relatively rare isotopes of common elements that happen to be biologically important. Using these isotopes, soil chemists can study the influences of soil organisms on the composition of soil water. Depending on what the soil chemist is studying, the isotope may be added, or spiked, to the soil in the laboratory or in the field. Alternatively, naturally occurring concentrations of the isotope in rain or snowmelt may be used. Regardless, soil water samples are collected by one or more of the lysimeter methods, and their isotopic composition is determined. The Soil Chemical Factory The wonderful interactions of complex chemical and biochemical reactions that are soil chemistry are one indication of the uniqueness of planet Earth. Without the interaction of liquid water and the gases in the atmosphere, many of the nutrients necessary for life would remain locked up in rock minerals. Thanks to weathering reaction, the soil chemical factory started to produce nutrients, which resulted in the exploitation of the soil environment by millions of organisms. The processes involved in soil chemistry—from weathering reactions that turn rock into new soil to the recycling of plant nutrients through microbial decay—are vital to every human being. Without fertile soil, plants will not grow. Without plants as a source of oxygen and food, there would be no animal life. Because of the complex chemical interrelationships that have developed in the soil environment, it may seem that nothing can disrupt the “factory” operation. As more is understood about soil chemistry and the ways in which humans stress the soil chemistry through their activities, it is apparent that the factory is fragile. Not only do humans rely on soil fertility for their very existence, but they also are taking advantage of soil 599
Soil chemical processes to help them survive their own past mistakes. Soil has been and continues to be used as a garbage filter. Garbage, whether solid or liquid, has been dumped on or buried in soil for ages. Natural chemical processes broke down the garbage into simpler forms and recycled the nutrients. When garbage began to contain toxic chemicals, those chemicals, when in small quantities, were either destroyed by soil bacteria or firmly attached to soil particles. The result is that water—percolating through garbage, on its way to the local groundwater, stream, or lake—does not carry with it as much contamination as one might expect. Soil chemistry has, so far, kept contaminated garbage from ruining drinking water. There are well-known cases, however, where the volume and composition of waste buried or spilled were such that the local soil chemistry was overwhelmed. In cases of large industrial spills, or when artificial chemicals are spilled or buried, the soil needs help to recover. The recovery efforts are usually very expensive but, faced with the possible permanent loss of large parts of the soil chemical factory, humankind cannot afford to neglect this aspect of the environment. Richard W. Arnseth See also: Acid deposition; Deforestation; Endangered plant species; Erosion and erosion control; Grasslands and prairies; Grazing and overgrazing; Multiple-use approach; Nutrient cycles; Pesticides; Rangeland; Reforestation; Slash-and-burn agriculture; Soil contamination. Sources for Further Study Berner, Elizabeth K., and Robert A. Berner. The Global Water Cycle: Geochemistry and Environment. Englewood Cliffs, N.J.: Prentice-Hall, 1987. Bohn, Heinrich, B. L. McNeal, and G. A. O’Connor. Soil Chemistry. 2d ed. New York: Wiley, 1985. Brill, Winston. “Agricultural Microbiology.” Scientific American 245 (September, 1981): 198. Evangelou, V. P. Environmental Soil and Water Chemistry: Principles and Applications. New York: Wiley, 1998. Lloyd, G. B. Don’t Call It Dirt. Ontario, Calif.: Bookworm Publishing, 1976. McBride, Murray B. Environmental Chemistry of Soils. New York: Oxford University Press, 1994. Millot, Georges. “Clay.” Scientific American 240 (April, 1979): 108. Sparks, Donald S., ed. Soil Physical Chemistry. 2d ed. Boca Raton, Fla.: CRC Press, 1999. Tan, Kim Howard. Principles of Soil Chemistry. 3d ed. New York: M. Dekker, 1998. 600
SOIL CONTAMINATION Types of ecology: Ecotoxicology; Restoration and conservation ecology; Soil ecology Soils contaminated with high concentrations of hazardous substances pose potential risks to human health and the earth’s thin layer of productive soil.
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roductive soil depends on bacteria, fungi, and other soil microbes to break down wastes and release and cycle nutrients that are essential to plants. Healthy soil is essential for growing enough food for the world’s increasing population. Soil also serves as both a filter and a buffer between human activities and natural water resources, which ultimately serve as the primary source of drinking water. Soil that is contaminated may serve as a source of water pollution through leaching of contaminants into groundwater and through runoff into surface waters such as lakes, rivers, and streams. Types of Contamination Soils can become contaminated by many human activities, including fertilizer or pesticide application, direct discharge of pollutants at the soil surface, leaking of underground storage tanks or pipes, leaching from landfills, and atmospheric deposition. Additionally, soil contamination may be of natural origin. For example, soils with high concentrations of heavy metals can occur naturally because of their close proximity to metal ore deposits. Common contaminants include inorganic compounds such as nitrate and heavy metals (for example, lead, mercury, cadmium, arsenic, and chromium); volatile hydrocarbons found in fuels, such as benzene, toluene, ethylene, and xylene BTEX compounds; and chlorinated organic compounds such as polychlorinated biphenyls (PCBs) and pentachlorophenol (PCP). Contaminants may also include substances that occur naturally but whose concentrations are elevated above normal levels. For example, nitrogen- and phosphorus-containing compounds are often added to agricultural lands as fertilizers. Since nitrogen and phosphorus are typically the limiting nutrients for plant and microbial growth, accumulation in the soil is usually not a concern. The real concern is the leaching and runoff of the nutrients into nearby water sources, which may lead to oxygen depletion of lakes as a result of the eutrophication encouraged by those nutrients. Furthermore, nitrate is a concern in drinking water because it poses a direct risk to human infants; it is associated with blue-baby syndrome. 601
Soil contamination Environmental Interactions Contaminants may reside in the solid, liquid, and gaseous phases of the soil. Most will occupy all three phases but will favor one phase over the others. The physical and chemical properties of the contaminant and the soil will determine which phase the contaminant favors. The substance may preferentially adsorb to the solid phase, either the inorganic minerals or the organic matter. The attraction to the solid phase may be weak or strong. The contaminant may also volatize into the gaseous phase of the soil. If the contaminant is soluble in water, it will dwell mainly in the liquidfilled pores of the soil. Contaminants may remain in the soil for years or make their way into the atmosphere or nearby water sources. Additionally, the compounds may be broken down or taken up by the biological component of the soil. This may include plants, bacteria, fungi, and other soil-dwelling microbes. The volatile compounds may slowly move from the gaseous phase of the soil into the atmosphere. The contaminants that are bound to the solid phase may remain intact or be carried off in runoff attached to soil particles and flow into surface waters. Compounds that favor the liquid phase, such as nitrate, will either move into surface waters or leach down into the groundwater. Metals display a range of behaviors. Some bind strongly to the solid phase of the soil, while others easily dissolve and wind up in surface or groundwater. PCBs and similar compounds bind strongly to the solid surface and remain in the soil for years. These compounds can still pose a threat to waterways because, over long periods of time, they slowly dissolve from the solid phase into the water at trace quantities. Fuel components favor the gaseous phase but will bind to the solid phase and dissolve at trace quantities into the water. However, even trace quantities of some compounds can pose a serious ecological or health risk. When a contaminant causes a harmful effect, it is classified as a pollutant. Treatments There are two general approaches to cleaning up a contaminated soil site: treatment of the soil in place (in situ) or removal of the contaminated soil followed by treatment (non-in situ). In situ methods, which have the advantage of minimizing exposure pathways, include biodegradation, volatilization, leaching, vitrification (glassification), and isolation or containment. Non-in situ methods generate additional concerns about exposure during the process of transporting contaminated soil. Non-in situ options include thermal treatment (incineration), land treatment, chemical extraction, solidification or stabilization, excavation, and asphalt incorporation. 602
Soil contamination The choice of methodology will depend on the quantity and type of contaminants and on the nature of the soil. Some of these treatment technologies are still in the experimental phase. John P. DiVincenzo See also: Acid deposition; Biomagnification; Biopesticides; Erosion and erosion control; Food chains and webs; Geochemical cycles; Hydrologic cycle; Integrated pest management; Pesticides; Pollution effects; Soil; Waste management. Sources for Further Study Pierzynski, Gary M., J. Thomas Sims, and George F. Vance. Soils and Environmental Quality. Boca Raton, Fla.: Lewis, 1994. Sparks, Donald L. “Soil Decontamination.” In Handbook of Hazardous Materials, edited by Morton Corn. San Diego, Calif.: Academic Press, 1993. Testa, Stephen M. The Reuse and Recycling of Contaminated Soil. Boca Raton, Fla.: Lewis, 1997.
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SPECIATION Types of ecology: Community ecology; Evolutionary ecology; Speciation Processes whereby new species arise is referred to as speciation. The term is used most often to refer to the multiplication of species.
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any types of speciation have been proposed, but most can be grouped into three main modes. Geographic (allopatric) speciation depends upon geographic isolation of populations. Semigeographic (parapatric) speciation involves divergence between populations in continuous geographic contact. Nongeographic (sympatric) speciation involves speciation at a restricted locality, without geographic separation. Allopatric Speciation Geographic, or allopatric, speciation is widely accepted as the most important mode of speciation for sexual species. According to this model, a new species develops when a population becomes geographically isolated from the remainder of the species and gradually evolves independently to the extent that it becomes reproductively isolated. If the two populations reestablish contact subsequent to the development of reproductive isolation, no interbreeding will take place. Geographic speciation is a slow process not amenable to experimental testing, but abundant indirect evidence is furnished by patterns of geographic variation, the development of reproductive isolation between geographically remote elements of the same species, varying degrees of divergence between isolates, and correlation of speciation with periods of isolation produced by past climatic or geological events. An unproven variant of the allopatric model is the foundereffect model, in which an isolated population established by a few founders goes through a drastic genetic reorganization because of the limited genetic variability introduced by the founders and chance fluctuations in gene frequencies (genetic drift). Such a reorganization supposedly could accelerate the speciation process. Parapatric Speciation The possibility of parapatric (semigeographic) speciation is suggested by the occurrence of hybrid zones or belts along which two races interbreed freely. Many hybrid belts are undoubtedly the result of secondary contact between previously isolated populations, but others may have been formed in place. The origin of hybrid zones, interactions at hybrid zones, 604
Speciation and processes, if any, whereby discontinuities can proceed to reproductive isolation are subjects of continuing investigation. Most chromosomal models are also essentially parapatric. Such models usually involve fixation in a local population of chromosomal rearrangements that severely reduce fertility in heterozygotes. Small, semi-isolated populations or mating systems that promote inbreeding are usually required. The subject is controversial. Sympatric Speciation The origin of an asexual form from a sexual one always takes place in a nongeographic (sympatric) mode. There are many variants of asexual reproduction, including egg or seed development without fertilization (parthenogenesis and agamospermy, respectively), vegetative reproduction, and simple fission. Obligatory self-fertilization in hermaphrodites accomplishes the same end. Considerable attention has been given to the adaptive significance of uniparental reproduction and factors influencing its origin. The only unquestioned mode of sympatric speciation for sexual forms is through polyploidy, with doubling of the entire complement of chromosomes, a phenomenon often associated with hybridization. Tetraploids (4N), for example, produced by a doubling of the diploid (2N) chromosome number, are often fertile, but are reproductively isolated from the parental forms because backcrossing produces sterile triploids (3N). Sexual polyploids are known from many animal groups but are generally rare. Polyploids are common among plants, however, and polyploidy has been an important speciation mechanism in plants. Many other models for sympatric speciation have been proposed, and most are controversial. Many of these models involve disruptive selection, a type of selection in which two or more phenotypes have high fitness, while intermediates between them have low fitness. If an organism, for example, exploits two subniches in the same locality, and there is some impediment to free gene exchange, disruptive selection could produce two different genotypes, each adapted to one of the subniches; heterozygotes would be adapted to neither. This type of speciation has received some support from studies on herbivorous insects and insects with parasitic larvae; conditioning may favor egg deposition by the insect on the plant or host where it developed. This would inhibit free gene exchange and allow adaptation to different plants or hosts. Ecological and Evolutionary Implications The species is the most fundamental unit of classification and is the basic unit of reference with respect to living things. It is an important unit of in605
Speciation teraction in natural communities. It is implicit that a species is genetically distinct from other species, with its own morphological and physiological attributes; as such it is an essential reference in all fields of biology and in the applied life sciences as well. The origin of a new species signifies the appearance of a distinct evolutionary unit with its own potential and that is isolated by intrinsic barriers from other species. The evolutionary implications for sexual and asexual forms, however, are quite different. Sexual forms have an immeasurably greater potential for evolutionary change because of the reservoir of genetic variability of the population, which is shared and reshuffled through sexual reproduction. Asexual forms have a limited capacity for change, rarely give rise to anything new, and tend to exploit short-term opportunities. The majority of described species other than microorganisms are sexual, although many exploit both modes of reproduction. The speciation process itself does not necessarily produce adaptive change, although changes in adaptation are usually involved in speciation. Species, however, once formed, interact with other species through competition, and selective forces promote specialization and adaptation to subniches. This process leads not only to more diverse and complex ecological communities but also to more pronounced morphological and physiological differences between species. This phenomenon is well illustrated by various adaptive radiations that have taken place on initially depauperate islands or in species-poor lakes following colonization by one or a few species. Speciation in this light can be seen to be a critical step that opens the way to, and indirectly promotes, evolutionary change. The origin of higher taxonomic categories has also been linked to speciation. The fossil record indicates that higher categories originate when there is movement into a major and/or distinctive and previously unexploited adaptive zone, followed by further morphological change and diversification within the zone. If a multiplicity of species are adapted to different subniches, chances are greatly enhanced for the “discovery” of a new adaptive zone by at least one species. Once movement into the zone is accomplished, diversification through speciation would take place, and interactions between species would promote further change. John S. Mecham See also: Adaptations and their mechanisms; Adaptive radiation; Clines, hybrid zones, and introgression; Convergence and divergence; Development and ecological strategies; Evolution: definition and theories; Evolu606
Speciation tion: history; Evolution of plants and climates; Extinctions and evolutionary explosions; Gene flow; Genetic drift; Isolating mechanisms; Natural selection; Nonrandom mating, genetic drift, and mutation; Population genetics; Punctuated equilibrium vs. gradualism; Species loss; Succession. Sources for Further Study Claridge, Michael F., H. A. Dawah, and M. R. Wilson, eds. Species: The Units of Biodiversity. New York: Chapman and Hall, 1997. Lambert, David M., and Hamish G. Spencer, eds. Speciation and the Recognition Concept: Theory and Application. Baltimore: Johns Hopkins University Press, 1995. Mayr, Ernst. Populations, Species, and Evolution. Cambridge, Mass.: Belknap Press, 1970. Otte, Daniel, and John Endler, eds. Speciation and Its Consequences. Sunderland, Mass.: Sinauer Associates, 1989. Paterson, H. E. H. Evolution and the Recognition Concept of Species: Collected Writings. Baltimore: Johns Hopkins University Press, 1993. Townsend, Colin R., et al. Essentials of Ecology. 2d ed. Malden, Mass.: Blackwell Science, 2003. White, Michael. Modes of Speciation. San Francisco: W. H. Freeman, 1978.
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SPECIES LOSS Types of ecology: Evolutionary ecology; Restoration and conservation ecology Species loss, particularly the extinction of species that is caused by human activities, has increasingly concerned scientists in a number of fields, threatening biodiversity both locally and globally.
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ublic and scientific concern about species loss stems from several factors and encompasses a variety of viewpoints. Ethically, many people believe that species have value in and of themselves and that humankind does not have the right to cause the extinction of any species. A species may also have an unknown potential to enrich human life and health. The latter argument is important in that many synthetic medicines and commercial products were first produced by plants and animals. The loss of species could potentially mean the loss of beneficial new products for human society. Species that exist today are the result of millions of years of evolutionary success, and to lose species is to lose that evolutionary history. From a resource management point of view, ecologists and land managers alike are concerned about the effects that species loss may have on the function and stability of biotic communities. Ecological Concerns Relationships such as predation, competition, and parasitism link species into complex community relationships. One way species are linked is by trophic levels within the community food chain, which is more accurately described as a food web. Starting with plants at the base of the web, trophic levels begin with producers, followed by several successive levels of consumers: herbivore, first-level carnivore, second-level carnivore, and so on, up to top carnivore. Omnivores feed both as herbivores and as carnivores and thus feed at more than one trophic level. Finally decomposers feed on dead organisms and their waste products from all trophic levels. Therefore, although the ramifications of loss of a species are not easily predicted, such a loss will have significant impact on ecosystems—often beyond merely the obvious one of increasing a population of its prey or decreasing a population of predators. Such a loss will disturb the entire food chain—or, more properly, food web—involving the complex relationships among all species in a community. Such community disturbance inevitably expands beyond the community’s borders to affect the larger ecosystem. 608
Species loss Some examples of these complex relationships have been revealed by controlled studies. Species-Removal Studies Species-removal studies provide some indication of what may occur when a species becomes extinct. In more than 90 percent of predator-removal studies, population densities of prey species in the trophic level immediately below the predator have shown a significant increase or decrease. In many cases, the change in density was twofold. Rarely has the removal of predator species had no effect on the population density of its prey. However, not all studies have shown the expected increase in prey density; many have shown an unexpected decrease. For species that possibly compete with one another, more than 90 percent of competitor-removal studies have shown an increase in the “remaining competitor” population density. Several factors may influence the strength of community response in species-removal experiments. For example, a predator may prey more heavily on a large, aggressive prey species and thus allow the coexistence of a less aggressive, competitor prey species. If the predator is removed, the aggressive prey may increase in density while the less aggressive one may actually decrease. Studies in aquatic communities indicate that the higher the trophic level in which species removal occurs, the greater the effect on population densities at lower trophic levels. The ramifications of species loss can only partially be predicted with knowledge of community food webs. The size and direction of population density change within a community may or may not be as expected. It is safe to predict, however, that species loss will cause changes in most instances. Wildlife Protection and Endangered-Species Legislation Concern about species loss in North America can be traced back at least as far as 1872, when legislation offering limited protection to the American bison (buffalo) was passed by the United States Congress. This legislation was passed at the height of buffalo exploitation by market hunters and during the United States Army’s policy of fighting Native American tribes by cutting off their food supply. However, President Ulysses S. Grant vetoed the legislation, and the buffalo was almost lost. Only a few hundred remained by 1900. The first National Wildlife Refuge was set aside by President Theodore Roosevelt in 1902 to protect egrets from extinction by feather hunters. Three years later, the Wichita Mountain National Wildlife Refuge was set aside to protect one of the small remnant herds of buffalo. 609
Species loss Several North American species and subspecies are now extinct because of similar exploitations: The passenger pigeon, Carolina parakeet, heath hen, Merriam’s elk, and Badlands bighorn sheep are some of the best known examples. During the 1960’s increasing concern about an accelerated species extinction rate attributable to human exploitation and disturbance of the environment culminated in the first federal protective legislation for endangered species, the Endangered Species Preservation Act of 1966. This act was limited to listing endangered birds and mammals and funding research on their population ecology and habitat acquisition. This legislation was expanded in 1969 to include all vertebrate animal species and some invertebrates. The definitive protection legislation is the 1973 Endangered Species Act. This act set procedures for listing threatened and endangered species, called for designation of critical habitat for each threatened or endangered species, and mandated the development of recovery plans for these species. The act prohibits the use of federal funds for projects that would harm threatened or endangered species. The coverage of the 1973 act was also expanded to include plants and invertebrate animals (except pest insects), subspecies, and distinct vertebrate populations. Since 1966 the U.S. Fish and Wildlife Service (USFWS) has had the legal responsibility of compiling and maintaining an official threatened and endangered species list. There are formal petitioning processes for placing additional species on the list and for removing them from the list. Petitions may be initiated by the USFWS or by private organizations. Petitions are reviewed by scientific panels using all available information on the species. If sufficient information is available to support the petition, a proposed addition to the list is published in the Federal Register and other appropriate places to solicit public comment. Final decisions about listing, “down-listing” (for example, changing a species designation from “endangered” to “threatened”), or “de-listing” are made by the USFWS. The ultimate goal of the listing process and the implementation of a recovery plan is to increase the abundance and distribution of a species to the point of being able to remove it from the threatened and endangered species list. James F. Fowler See also: Biodiversity; Conservation biology; Deforestation; Endangered animal species; Endangered plant species; Extinctions and evolutionary explosions; Habitats and biomes; Old-growth forests; Reforestation; Restoration ecology; Speciation; Wildlife management; Zoos. 610
Species loss Sources for Further Study Sherry, Clifford J. Endangered Species: A Reference Handbook. Santa Barbara, Calif.: ABC-Clio, 1998. Stanley, Steven M. Extinction. New York: Scientific American Library, 1987. Stearns, Beverly Petersen, and Stephen C. Stearns. Watching, from the Edge of Extinction. New Haven, Conn.: Yale University Press, 1999. Ward, Peter D., and Don Brownlee. Rare Earth: Why Complex Life Is Uncommon in the Universe. New York: Copernicus, 2000. Wilson, Edward O. The Diversity of Life. New York: W. W. Norton, 1993. _______. The Future of Life. New York: Alfred A. Knopf, 2001.
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SUCCESSION Type of ecology: Community ecology Succession is the progressive and orderly replacement of one biological community by another until a relatively stable, self-maintaining “climax community” is achieved.
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uccession is an important ecological phenomenon because it allows the maximum variety and number of species to occupy a given area through time and leads to the establishment of an ecologically stable climax community that represents the most complex and diverse biological system possible, given existing environmental conditions and available energy input. As succession proceeds, significant changes occur in species composition, nutrient cycling, energy flow, productivity, and stratification. Changes also occur within the climax community; however, these changes act to maintain the climax, not alter it. Immature communities tend to have high populations of a few species that are relatively small and simple. Biomass (weight of living material) is low, and nutrient conservation and retention are poor. Food chains are short, and available energy is shared by few species. Community structure is simple and easily disrupted by external forces. As communities mature, larger and more complex organisms appear, and there is a higher species diversity (number of different species). Biomass increases, and nutrients are retained and cycled within the community. The greater number of species results in more species interactions and the development of complex food webs. Community productivity (conversion of solar energy to chemical energy), initially high in immature communities, becomes balanced by community respiration as more energy is expended in maintenance activities. Stages of Succession The entire sequence of communities is called a sere, and each step or community in the sequence is a seral stage. The climax community is in balance, or equilibrium, with the environment and displays greater stability, more efficient nutrient and energy recycling, a greater number of species, and a more complex community structure than that of each preceding seral stage. Each seral stage is characterized by its own distinctive forms of plant and animal life, which are adapted to a unique set of chemical, physical, 612
Succession and biological conditions. Excepting the climax community, change is the one constant shared by all seral stages. Changes can be induced by abiotic factors, such as erosion or deposition, and by biotic factors, modification of the environment caused by the activities of living organisms within the community. These self-induced factors bring about environmental changes detrimental to the existing community but conducive to invasion and replacement by more suitably adapted species. For example, lichens are one of the first colonizers of barren rock outcrops. Their presence acts to trap and hold windblown and water-carried debris, thereby building up a thin soil. As soil depth increases, soil moisture and nutrient content become optimal for supporting mosses, herbs, and grasses, which replace the lichens. These species continue the process of soil-building and create an environment suitable for woody shrubs and trees. In time, the trees overtop the shrubs and establish a young forest. These first trees are usually shade-intolerant species. Beneath them, the seeds of the shade-tolerant trees germinate and grow up, eventually replacing the shade-tolerant species. Finally, a climax forest community develops on what once was bare rock, and succession ends. Primary and Secondary Succession The sere just described—from barren rock to climax forest—is an example of primary succession. In primary succession, the initial seral stage, or pioneer community, begins on a substrate devoid of life or unaltered by living organisms. Succession that starts in areas where an established community has been disturbed or destroyed by natural forces or by human activities (such as floods, windstorms, fire, logging, and farming) is called secondary succession. An example of secondary succession occurs on abandoned cropland. This is referred to as old-field succession and begins with the invasion of the abandoned field by annual herbs such as ragweed and crabgrass. These are replaced after one or two years by a mixture of biennial and perennial herbs, and by the third year the perennials dominate. Woody shrubs and trees normally replace the perennials within ten years. After another ten or twenty years have passed, a forest is established, and ultimately, after one or two additional seral stages in which one tree community replaces another, a climax forest emerges. Both primary and secondary succession begin on sites typically low in nutrients and exposed to extremes in moisture, light intensity, temperature, and other environmental factors. Plants colonizing such sites are tolerant of harsh conditions, are characteristically low-growing and relatively 613
Succession small, and have short life cycles. By moderating the environmental conditions, these species make the area less favorable for themselves and more favorable for plants that are better adapted to the new environment. Such plants are normally long-lived and relatively large. Secondary succession usually proceeds at a faster rate than primary succession, because a welldeveloped soil and some life are already present. Aquatic Environments Succession can also take place in aquatic environments, such as a newly formed pond. The pioneer community consists of microscopic organisms that live in the open water. Upon death, their remains settle on the bottom and join with sediment and organic matter washed into the pond. An accumulation of sediment provides anchorage and nutrients for rooted, submerged aquatic plants such as pondweeds and waterweeds. These add to the buildup of sediment, and as water depth decreases, rooted, floatingleaved species such as water lilies prevent light from reaching the submerged aquatics and eliminate them. At the water’s edge, emergent plants rooted in the bottom and extending their stems and leaves above water (cattails, rushes, and sedges) trap
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Succession sediment, add organic matter, and continue the filling-in process. The shallow margins fill first, and eventually the open water disappears and a marsh or bog forms. A soil rich in partially decomposed organic matter and saturated with water accumulates. As drainage improves and the soil becomes raised above the water level, trees and shrubs tolerant of wet soils invade the marsh. These act to lower the water table and improve soil aeration. Trees suited to drier conditions move in, and once again a climax community characteristic of the surrounding area develops. Theories of Succession The American ecologist Frederic E. Clements (1874-1945) believed that the characteristics of a climax community were determined solely by regional climate. According to Clements, all communities within a given climatic region, despite initial differences, eventually develop into the same climax community. Some seral stages might be abbreviated or skipped entirely, while others could be lengthened or otherwise modified; however, the end result would always be a single climax community suited to the regional climate. This phenomenon is called convergence, and Clements’s singleclimax concept is known as the monoclimax theory. Some ecologists have found the monoclimax theory to be simplistic and have offered other theories. One of these, the polyclimax theory, holds that, within a given climatic region, there could be many climaxes. It was noted that in any single climatic region, there were often many indefinitely maintained communities that could be considered separate and distinct climaxes. These developed as a result of differences caused by soil type, soil moisture, nutrients, slope, fire, animal activity (grazing and browsing), and other factors. Clements countered that these would eventually reach true climax status if given enough time and proposed terms such as subclimax (a long-lasting seral stage preceding the climax) and disclimax (a nonclimax maintained by continual disturbance) to describe such situations. A third theory, the climax pattern concept, views the climax as a single large community composed of a mosaic or pattern of climax vegetation instead of many separate climaxes or subclimaxes. Numerous habitat and environmental differences account for the patterns of populations within the climax; no single factor such as climate is responsible. While there is little doubt about the reality of succession, it is apparently not a universal phenomenon. For example, disturbed areas within tropical rain forests do not undergo a series of seral stages leading to reestablishment of the climax community. Instead, the climax is established directly by the existing species. Nevertheless, in most regions succession is the 615
Succession mechanism by which highly organized, self-maintained, and ecologically efficient communities are established. Basis for Biodiversity Succession is an important ecological phenomenon because it allows the maximum variety and number of species to occupy a given area through time and leads to the establishment of an ecologically stable climax community that represents the most complex and diverse biological system possible, given existing environmental conditions and available energy input. As succession proceeds, significant changes occur in species composition, nutrient cycling, energy flow, productivity, and stratification. Changes also occur within the climax community; however, these changes act to maintain the climax, not alter it. Immature communities tend to have high populations of a few species that are relatively small and simple. Biomass (weight of living material) is low, and nutrient conservation and retention are poor. Food chains are short, and available energy is shared by few species. Community structure is simple and easily disrupted by external forces. As communities mature, larger and more complex organisms appear, and there is a higher species diversity (number of different species). Biomass increases, and nutrients are retained and cycled within the community. The greater number of species results in more species interactions and the development of complex food webs. Community productivity (energy storage), initially high in immature communities, becomes balanced by community respiration as more energy is expended in maintenance activities. Community structure increases in complexity and stability as equilibrium with the prevailing physical environment is achieved. Human beings, throughout their history, have been interacting with natural communities and the process of succession—sometimes with disastrous results. Much of what was once climax forest or grassland has been put to the plow, timbered, strip-mined, or otherwise altered. In such cases, humans retard or reverse succession by destroying or disrupting the existing climax and replacing it with an ecologically simpler and less stable seral stage. In a cornfield, for example, the existing climax has been replaced, in effect, by a simple pioneer community whose dominant species is an annual. Invading weeds and shrubs must be constantly controlled or eliminated. Nutrients, in the form of fertilizer, must be applied to maintain high yields. Windstorms, drought, insect attacks, and other natural calamities can easily destroy the entire community. A cornfield is neither selfrepairing nor self-maintaining, and humans must constantly intercede to keep succession in check. 616
Succession Although such human intervention is easily justified by its benefits, human exploitation of the natural environment is too often destabilizing and destructive. The Dust Bowl of the 1930’s is an excellent example. The shortgrass climax community that existed in parts of the southwestern Great Plains was converted to wheat production and ranchland without regard for the consequences. Drought, overgrazing, and poor farming practices combined to convert the once-fertile prairie into a barren wasteland. Failure to understand the physical and climatic conditions that resulted in shortgrass prairie, coupled with unwise land usage, was the underlying cause of this environmental disaster. Steven D. Carey See also: Biodiversity; Biogeography; Biomes: determinants; Biomes: types; Coevolution; Communities: ecosystem interactions; Communities: structure; Competition; Ecology: definition; Food chains and webs; Gene flow; Genetic diversity; Speciation; Symbiosis; Trophic levels and ecological niches. Sources for Further Study Bazzaz, F. A. Plants in Changing Environments: Linking Physiological, Population, and Community Ecology. New York: Cambridge University Press, 1996. Brewer, Richard. The Science of Ecology. Fort Worth, Tex.: Saunders College Publishers, 1994. Perry, David A. Forest Ecosystems. Baltimore: Johns Hopkins University Press, 1994. Smith, Robert L. Ecology and Field Biology. 6th ed. San Francisco: Benjamin Cummings, 2001.
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SUSTAINABLE DEVELOPMENT Types of ecology: Restoration and conservation ecology; Theoretical ecology Sustainable development meets the consumption needs of the current generation without compromising the ability of future generations to increase their economic production to meet future needs. Environmental benefits arise as a consequence of changes in human attitude and behavior, technology, and resource utilization.
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n 1987, the United Nations World Commission on Environment and Development, also known as the Brundtland Commission, issued a report in which it noted that humanity has the ability to make development “sustainable”—to ensure that it meets the needs of the present without compromising the ability of future generations to meet their own needs. Sustainable development is a process of change in which the exploitation of resources, the direction of investments, the orientation of technological development, and institutional change are all in harmony and enhance both current and future potential to meet human needs and aspirations. The commission envisioned the possibility of continued economic growth, population stabilization, improvements in global economic equity between rich and poor nations, and environmental improvement, all occurring simultaneously and in harmony. Since publication of the Brundtland Commission’s report, sustainable development has become the dominant global position on the environment, ecology, and economic development. A Value System Sustainable development is a normative philosophy, or value system, concerned with equal distribution of the earth’s natural capital among current and future generations of humans. Sustainable development promotes three core values. First, current and future generations should each have equal access to the planet’s life-support systems—including Earth’s gaseous atmosphere, biodiversity, stocks of exhaustible resources, and stocks of renewable resources—and should maintain the earth’s atmosphere, land, and biodiversity for future generations. Exhaustible resources, such as minerals and fossil fuels, are used sparingly and conserved for use by future generations. Renewable resources, such as forests and soil fertility, are renewed as they are used to ensure that stocks are maintained at or above current levels and are never exhausted. Second, all future generations should have an equal opportunity to en618
Sustainable development joy a material standard of living equivalent to that of the current generation. In addition, the descendants of the current generation in underdeveloped regions are permitted to increase their economic development to match that available to descendants of the current generation in the industrialized regions. Future development and growth in both developed and underdeveloped regions must be sustainable. Finally, future development must no longer follow the growth path taken by the currently industrialized countries but should utilize appropriate technology. Development should also limit use of renewable resources to each resource’s maximum sustained yield, the rate of harvest of natural resources such as fisheries and timber that can be maintained indefinitely through active human management of those resources. Weak sustainability requires that depletions in natural capital be compensated for by increases in human-made capital of equal value. For example, the requirements for weak sustainability are met when a tree (natural capital) is cut for the construction of a frame house (human-made capital). However, if the tree is cut and cast aside in a land-clearing project, the requirements for weak sustainability are not met. Strong sustainability requires that depletions of one sort of natural capital be compensated for by increases in the same or similar natural capital. For example, the requirements for strong sustainability are met when a tree is cut and a new tree is planted to replace it, or when loss of acreage in equatorial rain forests in Brazil is compensated for by an increase in the acreage of temperate rain forests on the Pacific coast of North America. Promoting the Philosophy Sustainable development is promoted through a combination of public policies. First, to the extent possible, elements in the earth’s support system are assigned monetary values in order to make the economic and financial calculations that are necessary to ensure that the requirements of weak sustainability are met. Second, economic development in the underdeveloped world is shifted away from high-resource-using, high-polluting patterns of Western development and toward more sustainable or “appropriate” patterns. Suggested appropriate technologies include solar energy, resource recycling, cottage industry, and microenterprises (factories built on a small scale). Third, objective and measurable air, water, and resource quality standards are established and enforced to ensure that a continuing minimum quality and quantity of natural capital is maintained and that certain stocks of natural capital are protected through the establishment of wilderness areas, oil and gas reserves, and other reserves. 619
Sustainable development Finally, each individual human adopts a personal commitment to a sustainable lifestyle, thus making a minimal personal impact on the earth’s natural capital. Environmental improvement results from the changes in resource utilization. For example, reductions in use and waste of natural capital reduces the environmental impact of resource extraction industries such as strip mines, and waste disposal industries such as incinerators. Environmental quality standards and maintenance of biodiversity leads to implementation of antipollution and ecosystem restoration efforts. Gordon Neal Diem See also: Biodiversity; Conservation biology; Deforestation; Endangered animal species; Endangered plant species; Erosion and erosion control; Forest management; Grazing and overgrazing; Integrated pest management; Multiple-use approach; Old-growth forests; Reforestation; Restoration ecology; Species loss; Urban and suburban wildlife; Waste management; Wildlife management; Zoos. Sources for Further Study Bowers, John. Sustainability and Environmental Economics: An Alternative Text. Harlow, England: Longman, 1997. Dryzek, John, ed. Debating the Earth: The Environmental Politics Reader. New York: Oxford University Press, 1998. Lee, Kai N. Compass and Gyroscope: Integrating Science and Politics for the Environment. Washington, D.C.: Island Press, 1993. Sitarz, Daniel. Sustainable America: America’s Environment, Economy, and Society in the Twenty-first Century. Foreword by Al Gore. Carbondale, Ill.: EarthPress, 1998. United Nations Earth Summit. Agenda 21. New York: Author, 1992. World Bank. Monitoring Environmental Progress. Washington, D.C.: Environmentally Sustainable Development, World Bank, 1995. _______. The World Bank and the Global Environment: A Progress Report. Washington, D.C.: Author, 2000.
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SYMBIOSIS Type of ecology: Community ecology All animals live in close association, or symbiosis, with other species. Most symbioses are based on nutritional interrelationships involving competition or cooperation. Some animals cannot survive without their symbiotic partners, while others are harmed or killed by them.
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nderstanding the ways in which different species of animals interact in nature is one of the fundamental goals of ecology. Predator-prey relationships, competition between species for limited resources, and symbiosis are the major forms of species interactions, and these have profoundly influenced the diversity and ecology of all forms of life. Significant advances have been made in understanding how organisms interact, but in studies of symbiosis (which literally means “living together”), one finds the most complex, interesting, and important examples of both cooperation and exploitation known in the living world. Defining Symbiosis Symbiosis involves many types of dependent or interdependent associations between species. In contrast to predator-prey interactions, however, symbioses are seldom rapidly fatal to either of the associating species (symbionts) and are often of long duration. With the exception of grazing animals that do not often entirely consume or destroy their plant “prey,” most predators quickly kill and consume their prey. While a predator may share its prey with other individuals of the same species (clearly an example of “living together”), such intraspecific behavior is not considered to be a type of symbiosis. Fleas, some ticks, mites, mosquitoes, and other bloodsucking flies are viewed as micropredators rather than parasites. All organisms are involved in some form of competition. The abundance and availability of environmental resources are finite, and competition for resources occurs both between members of the same species and between individuals and populations of different species. When the number of individuals in a population increases, the intensity of competition for limited food, water, shelter, space, and other resources necessary for survival and reproduction also increases. Thus, competition plays a major role in populations of free-living animals (those not inhabiting the body of other organisms) and in populations living on or in other animals. For example, both tapeworms and whales must compete for resources, and both 621
Symbiosis have evolved habitat-specific adaptations to accomplish this goal. Whales compete with whales, fish, and other predators for food; tapeworms compete with tapeworms and other symbionts (such as roundworms) for food and space; and tapeworms and whales compete with each other for food in the whale’s gut. “Symbiosis” is a term used to describe nonaccidental, nonpredatory associations between species. When used by itself, the term “symbiosis” does not provide information on how or why species live together, or the biological consequences of their interactions. Recognizably different forms of symbioses all have one or more characteristics in common. All involve “living together”; most involve food sharing; many involve shelter; and some involve damage to one or both symbionts. Hosts and Symbionts Host species may be thought of as landlords. Hosts provide their symbionts (also called symbiotes) with transportation, shelter, protection, space, some form of nutrition, or some combination of these. Host species are generally larger and structurally more complex than their symbionts, and different parts of a host’s body (skin, gills, and gut, for example) may provide habitats for several different kinds of symbionts at the same time. The three primary categories of symbiosis most commonly referred to in popular and scientific works are commensalism, mutualism, and parasitism. Symbionts that share a common food source are known as commensals (literally, “mess-mates”). In the usual definition of commensalism, one species (usually referred to as the commensal, although both species are commensals) is said to benefit from the relationship, while the other (usually referred to as the host) neither benefits nor is harmed by the other. Adult tapeworms which live in the intestinal tracts of vertebrate hosts provide a classic example of commensals. Adult tapeworms share the host’s food, usually with little or no effect on otherwise healthy hosts. As in all species, however, too large a tapeworm population may result in excessive competition, lower fitness, or disease in both the host and the tapeworms. For example, the broad fish tapeworm, which includes humans among its hosts, Diphyllobothrium latum, may cause a vitamin B-12 deficiency and anemia in humans when the worm burden is high. In addition to tapeworms, many human symbionts called “parasites” are, in fact, commensals. External commensals (those living on the skin, fur, scales, or feathers of their hosts) are called epizoites. A good example of an epizoite is the fish louse (a distant relative of the copepod), which feeds on mucus of the skin and scales of fish. Another type of commensalism is called phoresis 622
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Remoras attach themselves to larger fish for transport. This form of symbiosis is called phoresis, the passive transportation of the commensal (here, the remora) by its host. (Digital Stock)
(phoresy), which involves passive transportation of the commensal (phoront) by its host. Examples of phoreses include barnacles carried by whales and sea turtles, and remoras (sharksuckers), which, in the absence of sharks, may temporarily attach themselves to human swimmers. In inquilinism, the transported commensal (inquiline) shares, or more accurately, steals, food from the host, or may even eat parts of the host. Perhaps the best-known inquilines are the glass- or pearlfish, which take refuge in the cloacae of sea cucumbers and often eat part of the host’s respiratory system. A unique type of commensalism, known as symphilism, is found in certain ants and some other insects (hosts) which “farm” aphids (symphiles) and induce them to secrete a sugary substance which the ants eat. Mutualism The most diverse type of commensalism is mutualism. In some works, particularly those dealing with animal behavior, mutualism is used as a synonym of symbiosis; hence, the reader must use caution in order to determine an author’s usage of these terms. As used here, mutualism is a special case of commensalism, a category of symbiosis. The relationship between mutuals may be obligatory on the part of one or both species, but it is always reciprocally beneficial, as the following examples illustrate. 623
Symbiosis Some species of hermit crab place sea anemones on their shells or claws (sea anemones are carnivores which possess stinging cells in their tentacles). Hermit crabs without anemones on their shells or claws may be more vulnerable to predators than those with an anemone partner. Hermit crabs, which shred their food in processing it, lose some of the scraps to the water, which the anemones intercept, and eat. Thus, the crab provides food to the anemone, which in turn protects its provider. Such relationships, which are species-specific, are probably the result of a long period of coevolution. A different type of mutualism, but one having the same outcome as the crab-anemone example, is found in associations between certain clown fish and sea anemones. Clown fish appear to be fearless and vigorously attack intruders of any size (including scuba divers) that venture too close to “their” anemone. When threatened or attacked by predators, these small fish dive into an anemone’s stinging tentacles, where they find relative safety. Anemones apparently share in food captured by clown fish, which have been observed to drop food on their host anemone’s tentacles. Cleaning symbiosis is another unique type of mutualism found in the marine environment. In this type of association, marine fish and shrimp of several species “advertise” their presence by bright and distinctive color patterns or by conspicuous movements. Locations where this behavior occurs are called “cleaning stations.” Instead of being consumed by predatory fish, these carnivores approach the cleaner fish or shrimp, stop swimming, and sometimes assume unusual postures. Barracudas, groupers, and other predators often open their mouths and gill covers to permit the cleaners easy entrance and access to the teeth and gills. Cleaners feed on epizoites, ectoparasites, and necrotic (dead) tissue that they find on host fish, to the benefit of both species. Some studies have shown that removal of cleaning symbionts from a coral reef results in a significant decrease in the health of resident fish. Parasitism Parasitism is a category of symbiosis involving species associations that are very intimate and in which competitive interactions for resources may be both acute and costly. The extreme intimacy (rather than damage) between host and parasite is the chief difference between parasitism and other forms of symbiosis. Parasites often, but not always, live within the cells and tissues of their hosts, using them as a source of food. Some types of commensals also consume host tissue, but in such cases (pearl fish and sea cucumbers, for example) significant damage to the host rarely occurs. Commensalism is associated with nutritional theft. 624
Symbiosis Some, but not all, parasites harm their hosts, by tissue destruction (consumption or mechanical damage) or toxic metabolic by-products (ammonia, for example). Commonly, however, damage to the host is primarily the result of the host’s own immune response to the presence of the parasite in its body, cells, or tissues. In extreme cases, parasites may directly or indirectly cause the host’s death. When the host dies, its parasites usually die as well. It follows that the vast majority of host-parasite relationships are sublethal. A number of parasites are actually beneficial or crucial to the survival of their hosts. The modern, and biologically reasonable, definition of parasitism as an intimate type of symbiosis, rather than an exclusively pathogenic association between species, promotes an ecological-evolutionary understanding of interspecies associations. Most nonmedical ecologists and symbiotologists agree that two distinct forms of intimate associations, or parasitisms (with many intermediate types) occur in nature. The most familiar are those involving decreased fitness in humans and in their domestic animals and crops. Among animal parasites, malarial parasites, hookworms, trypanosomes, and schistosomes (blood flukes) cause death and disease in millions of people each year. The degree to which these parasites are pathogenic, however, is partly the result of preexisting conditions of ill health, malnutrition, other diseases, unsanitary living conditions, overcrowding, or lack of education and prevention. Parasites which frequently kill or prevent reproduction of their hosts do not survive in an evolutionary sense, because both the parasites and their hosts perish. Both members of intimate symbiotic relationships constantly adapt to their environments, and to each other. Over time, evolutionary selection pressures result in coadaptation (lessening of pathogenicity) or destruction or change in form of the symbiosis. Nonpathogenic or beneficial host-parasite associations are among the most highly evolved of reciprocal interactions between species. The extreme degree of intimacy of the symbionts (not lack of pathogenicity) distinguishes this type of parasitism from mutualism. Parasitic dinoflagellates (relatives of the algae that cause “red tides”) are found in the tissues of all reef-building corals. These photosynthetic organisms use carbon dioxide and other waste products produced by corals. In turn, the dinoflagellates (Symbiodinium microadriaticum) provide their hosts with oxygen and nutrients that the corals cannot obtain or produce by themselves. Without parasitic dinoflagellates, reef-building corals starve to death. Similar host-parasite relationships occur in termites, which, without cellulose-digesting parasitic protozoans in their gut, would starve to death. 625
Symbiosis Research on Commensals and Parasites The life cycles of many commensals and parasites are extremely complex and often involve two or more intermediate hosts living in different environments, as well as free-living developmental stages. Knowledge of life cycles remains as one of the most important areas of research in parasitology and is usually the phase of research following the description of a new species. Scientists have long recognized that “chemical warfare” (antibiotics, antihelminthics, insecticides) against microbial and animal parasites, and their insect and other vectors, provides only short-term solutions to the control or eradication of symbionts of medical importance. Research attempts are being made to find ways of interrupting life cycles, sometimes with the use of other parasites. This research requires sophisticated ecological and biochemical knowledge of both the host-parasite relationship and the parasite-mix. Studies of the parasite-mix are ecological (parasiteparasite and host-parasite competition), immunological (host defense mechanisms and parasite avoidance strategies), and ethological (host and symbiont behavioral interactions) in nature. Investigators involved in this kind of research must be well trained in many of the biological disciplines, including epidemiology (the distribution and demographics of disease). Immunology is the most promising modern research area in parasitology. Not only have specific diagnostic tests for the presence of cryptic (hidden or hard to find) parasites been developed, but also vaccines may be discovered that can protect people from such destructive protozoan diseases as malaria. Malaria has killed more humans than any other disease in history, and it currently causes the death of more than one million people, and lowers the quality of life for millions of others, each year. All species are involved in complex interrelationships with other species that live in or on their bodies, or with which they intimately interact behaviorally or ecologically. Such interactions may play a minor role in the life and well-being of one or both of the associates, or they may be necessary for the mutual survival of both. In relatively few symbiotic relationships, one or both species may suffer damage or death. Pathogenic associations are relatively rare, because disease or death of one symbiont generally results in corresponding disease or death of the other. Such relationships, which cannot persist over evolutionarily long periods of time, may nevertheless cause catastrophic loss of life in nonadapted host populations. Ecological Implications All species are involved in complex interrelationships with other species that live in or on their bodies, or with which they intimately interact 626
Symbiosis behaviorally or ecologically. Such interactions may play a minor role in the life and well-being of one or both of the associates, or they may be necessary for the mutual survival of both. In relatively few symbiotic relationships, one or both species may suffer damage or death. Pathogenic associations are relatively rare, because disease or death of one symbiont generally results in corresponding disease or death of the other. Such relationships, which cannot persist over evolutionarily long periods of time, may nevertheless cause catastrophic loss of life in nonadapted host populations. Domestic animals cannot live in some parts of the world, such as the central portion of Africa, because they have little or no resistance to parasites of wild species, which are the normal hosts and are not harmed. Native species have coadapted with the parasites. This situation presents a moral dilemma to humans. In the face of human needs for space and other resources, should native animals be displaced or killed? Or should human populations proactively slow their reproductive rates? History shows that humanity has often chosen to take the former course. The common view that animals which live in other animals are degenerate creatures that take advantage of more deserving forms of life is understandable but inaccurate. Symbionts are highly specialized animals that do not live cost-free, or always to the detriment of their hosts. Symbiotic relationships between species have vastly increased the diversity, complexity, and beauty of the living world. Sneed B. Collard See also: Animal-plant interactions; Biological invasions; Coevolution; Communities: ecosystem interactions; Communities: structure; Competition; Ecology: definition; Food chains and webs; Lichens; Mycorrhizae; Pollination; Predation; Trophic levels and ecological niches. Sources for Further Study Boothroyd, John C., and Richard Komuniecki, eds. Molecular Approaches to Parasitology. New York: Wiley-Liss, 1995. Caullery, Maurice. Parasitism and Symbiosis. London: Sidgwick and Jackson, 1952. Limbaugh, Conrad. “Cleaning Symbiosis.” Scientific American 205 (August, 1961): 42-49. Margulis, Lynn. “Symbiosis and Evolution.” Scientific American 225 (August, 1971): 48-57. Margulis, Lynn, and Dorion Sagan. Slanted Truths: Essays On Gaia, Symbiosis, and Evolution. New York: Copernicus, 1997. 627
Symbiosis Noble, Elmer, Glenn Noble, Gerhard Schad, and Austin MacGinnes. Parasitology: The Biology of Animal Parasites. 6th ed. Philadelphia: Lea & Febiger, 1989. Toft, Catherine Ann, Andre Aeschlimann, and Liana Bolis, eds. ParasiteHost Associations: Coexistence or Conflict? New York: Oxford University Press, 1991. Whitefield, Philip. The Biology of Parasitism: An Introduction to the Study of Associating Organisms. Baltimore: University Park Press, 1979. Zann, Leon P. Living Together in the Sea. Neptune City, N.J.: T. F. H., 1980. Zinsser, Hans. Rats, Lice, and History. Reprint. New York: Bantam Books, 2000.
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TAIGA Types of ecology: Biomes; Ecosystem ecology “Taiga” derives from a Russian word for the forests of cone-bearing, needle-leaved, generally evergreen trees of northern Eurasia and North America. “Coniferous forest” and “boreal forest” are other names given to this biome. Some botanists include the temperate rain forests along the Pacific Coast of North America and the coniferous forests in the western mountains in the taiga.
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hile the term “coniferous forest” can be applied to temperate rain forest and coniferous forest biomes in the western mountains, the terms “taiga” and “boreal forest” should be restricted to the northern forests. “Taiga” is also sometimes used in a more restricted way, to mean a subdivision of the boreal forest. Components The dominant plants in the taiga are cone-bearing, needle-leaved, evergreen trees, such as pines, spruces, and firs. North American taiga is dominated by two species of spruce: black spruce (Picea mariana) and white spruce (Picea glauca). Jack pine (Pinus banksiana), balsam fir (Abies balsamea), and eastern larch (Larix laricina, a deciduous conifer) are also important in parts of the taiga. A few deciduous flowering trees are also important components. Quaking aspen (Populus tremuloides, the most widespread tree species in North America) and paper birch (Betula papyrifera) are two examples. Eurasian taiga is dominated by related species of spruce and pine and has the same character. Determinants and Adaptations Taiga occurs in a broad band across Canada, Alaska, Siberia, and Europe; essentially, this band is interrupted only by oceans. This pattern suggests that climate plays a major role in determining the distribution of the taiga. Average temperatures are cool, and precipitation is intermediate, but evaporation is low because of the cool temperatures. Hence, moisture is generally available to plants during the growing season. The growing season is short, and winters are long. Permafrost is present in the northern part of the taiga, and wetlands are common because drainage is often deficient. These physical conditions are primarily determined by the high latitude at which taiga occurs, but why taiga develops under these conditions is not entirely clear. 629
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Taiga, or boreal forest, is characterized by its location in the northern latitudes and its domination by conebearing, evergreen trees, notably spruces and pines. A few deciduous, flowering trees are also important components, such as aspens, the most widespread tree species in the North American taiga. (PhotoDisc)
The length of the growing season may help explain why the dominant taiga trees are evergreen. Because they retain their leaves through the winter, these trees can carry out some photosynthesis on mild winter days. More important, they avoid the energetic expense of replacing all their leaves at one time. Deciduous trees put tremendous amounts of energy into leaf replacement each spring and must replace those energy stores as well as produce energy for growth during the growing season. Deciduous forests generally occur south of the taiga, where the growing season is longer. However, some deciduous trees are successful in the taiga, so other adaptations must also be important. Asexual reproduction probably contributes to the success of taiga trees, especially in severe environments. Black and white spruce reproduce by layering, the growth of a new tree from a lower branch which makes contact with the ground. Most deciduous trees of the taiga can sprout from the roots or other underground parts if the aboveground part of the tree is damaged or killed. Both strategies allow new trees to develop using the resources of the parent tree. In contrast, some plants growing from seed do not have sufficient resources to survive. 630
Taiga Fire is an important environmental factor in the taiga. Many of the conifers produce at least some cones which open and release their seeds only after they have been heated intensely, as in a forest fire. Jack pine responds to fire this way, as does black spruce to a lesser extent. Most deciduous trees send up new stems from undamaged underground parts after a taiga fire. White spruce does not employ either of these strategies but does have efficient seed dispersal and so can move into a burned area fairly quickly. Similar adaptations make Eurasian taiga species fit for life in northern environments. Apparently, no single suite of adaptations suits a tree species for taiga life; instead various combinations of characteristics are employed by the different species. Adjacent Zones The taiga is bordered by tundra to the north, and the meeting place between the two biomes is a broad transition zone often called the “taigatundra,” or forest-tundra. This ecotone is composed of a mixture of forest and tundra plants, with trees becoming fewer and smaller from south to north until conditions become so harsh that trees can no longer grow. The southern boundary of the taiga is often adjacent to deciduous forest, grassland, or parkland. These are also broad, transitional ecotones. In eastern North America, the northern hardwood forest region is such a transition zone and is composed primarily of a mixture of trees from the deciduous forests and the taiga. The aspen parklands in the west are also transitional. Quaking aspen from the taiga and grasses from western grasslands mix in this zone between the taiga and grassland biomes. Environmental Concerns Human activities may have less impact on the taiga than on many other biomes, primarily because the taiga occurs in a harsh environment less accessible to humans than many other biomes. Still, there are serious concerns. Acid rain became a problem for the taiga in eastern Canada in the late twentieth century. These forests are northeast of the industrial centers in the United States, and the prevailing southwesterly winds move nitrogen and sulfur oxides into eastern Canada, where they precipitate on plants and soil. Both oxides interact with water to produce acids, thus acidifying the soil and plant leaves. Many ecologists believe that acid precipitation has seriously damaged the taiga of both North America and Eurasia. Global warming is a second and perhaps more insidious threat to the taiga. The taiga will almost certainly be negatively impacted by changes in temperature, the length of the growing season, fire frequency and intensity, and precipitation patterns. Taiga itself may play a role in carbon stor631
Taiga age and mitigation of the greenhouse effect. This possibility, its role as a source of timber, and the inherent value of the biome and its component species make it imperative that the taiga be conserved. Carl W. Hoagstrom See also: Biomes: determinants; Biomes: types; Chaparral; Deserts; Forests; Grasslands and prairies; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Tundra and high-altitude biomes; Wetlands. Sources for Further Study Barbour, Michael G., and William Dwight Billings, eds. North American Terrestrial Vegetation. 2d ed. New York: Cambridge University Press, 2000. Larsen, James A. The Boreal Ecosystem. New York: Academic Press, 1980. Vankat, John L. The Natural Vegetation of North America: An Introduction. Malabar, Fla.: Krieger, 1992.
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TERRITORIALITY AND AGGRESSION Type of ecology: Behavioral ecology Aggressive behavior and territoriality are common features of animals. Territories may differ in function across species, but general trends occur. Territoriality is best viewed as a means by which individuals maximize their own reproductive success rather than as a mechanism of population regulation.
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ny field or forest inhabited by animals contains countless invisible lines that demarcate territories of individuals of many different species. Humans are oblivious to these boundaries yet have quick perception of human property lines; other animals are equally oblivious to human demarcations. Most organisms, in fact, appear to attend only to the territorial claims made by members of their own species. If separate maps of individual territories could be obtained for each species in the same habitat and superimposed on one another, the resulting hodgepodge of boundaries would show little consensus on the value of particular areas. Yet basic similarities exist in why and how different species are territorial. Causes of Territoriality The existence of aggression and territorial behavior in nature hardly comes as a surprise. Even casual observations at a backyard bird feeder reveal that species that are commonly perceived as friendly can be highly aggressive. The observation of birds at feeders can lead to interesting questions concerning territorial behavior. For example, bird feeders usually contain much more food than any one bird could eat: Why, then, are aggressive interactions so common? Moreover, individuals attack conspecifics more often than birds of other species, even when all are eating the same type of seeds. Aggressive defense of superabundant resources is not expected to occur in nature; however, bird feeders are not a natural phenomenon. Perhaps the aggressive encounters that can be observed are merely artifacts of birds trying to forage in a crowded, novel situation, or perhaps bird feeders intensify aggressive interactions that occur less frequently and less conspicuously in nature. While the degree to which aggression observed at feeders mirrors reality is open to question, the observation of a greater intensity of interactions between conspecifics definitely reflects a natural phenome633
Territoriality and aggression non. Members of the same species are usually more serious competitors than are members of different species because they exploit exactly the same resources; members of different species might only share a few types of resources. Despite the ecological novelty of artificial feeders, noting which individuals win and lose in such an encounter can provide valuable information on the resource-holding potential of individuals that differ in various physical attributes such as body size, bill size, or even sex. For organisms that live in dense or remote habitats, this type of information can often be obtained only by observations at artificial feeding stations. Territorial defense can be accomplished by visual and vocal displays, chemical signals, or physical encounters. The sequence of behaviors that an individual uses is usually predictable. The first line of defense may involve vocal advertisement of territory ownership. One function of birdsong is to inform potential rivals that certain areas in the habitat are taken. If song threats do not deter competitors, visual displays may be employed. If visual displays are also ineffective, then residents may chase intruders and, if necessary, attack them. This sequence of behaviors is common in territorial interactions because vocal and visual displays are energetically cheaper than fighting and involve less risk of injury to the territory owner. It may be less obvious why fighting is a necessary component in territorial interactions for both territory owners and intruders. Without the threat of bodily injury, there is no cost to intruders that steal the resources of an-
Two elephants exhibit territorial aggression. (Digital Stock) 634
Territoriality and aggression other individual. This would severely hamper an owner’s ability to control an area. On the other hand, if intruders never physically challenge territory owners, then it would pay for all territory owners to exaggerate their ability to defend a resource. Thus, physical aggression may be essential. Animals do not frequently kill their opponents, however, so there must be something that limits violence. Various species of animals possess formidable weapons, such as large canine teeth or antlers, that are quite capable of inflicting mortal wounds. Furthermore, a dead opponent will never challenge again. Yet fights to the death are rare in nature. When they do occur, some novel circumstance is usually involved, such as a barrier that prohibits escape of the losing individual. Restraint in normal use of weapons, however, probably does not indicate compassion among combatants. Fights to the death may simply be too costly, because they would increase the chance that a victor would suffer some injury from a loser’s last desperate attempts to survive. Functions of Territory Territories can serve various functions, depending on the species. For some, the area defended is only a site where males display for mates; for others, it is a place where parents build a nest and raise their offspring; for others, it may be an all-purpose area where an owner can have exclusive access to food, nesting sites, shelter from the elements, and refuge from predators. These different territorial functions affect the area’s size and the length of time an area is defended. Territories used as display sites may be only a few meters across, even for large mammal species. Territorial nest sites may be smaller still, such as the densely packed nest sites guarded by parents of many colonial seabirds. All-purpose territories are typically large relative to the body size of the organism. For example, some passerine birds defend areas that may be several hundred meters across. Although all three types of territories may be as ephemeral as the breeding season, it is not uncommon for all-purpose territories to be defended year around. The abundance and spatial distribution of needed resources determine the economic feasibility of territoriality. On one extreme, if all required resources are present in excess throughout the habitat, territory holders should not have a reproductive advantage over nonterritory holders. At the other extreme, if critical resources are so rare that enormous areas would have to be defended, territory holders might again have no reproductive advantage over nonterritory holders. If needed resources, however, are neither superabundant nor extremely rare and are somewhat clumped in the habitat, territoriality might pay off. That is, territorial individuals might produce more offspring than nonterritorial individuals. 635
Territoriality and aggression Studies of territoriality raise more questions than biologists can answer. Researchers investigate how large an area an individual defends and whether both sexes are equally territorial. They seek to determine whether the territories of different individuals vary according to quality. The density of conspecifics may influence territoriality; on the other hand, territoriality itself may serve to regulate population size, although evidence suggests that this is an incidental effect. All-purpose territories vary considerably in size, depending on the resource requirements of the individuals involved and the pattern of temporal variation in resource abundance. In some organisms, individuals only defend enough area to supply their “minimum daily requirements.” In others, individuals defend a somewhat larger area—one that could still support them even when resource levels drop. In others, individuals defend territories that vary in size depending on current resource levels. For example, pied wagtails (European songbirds) defend linear territories along riverbanks that are about six hundred meters long during the winter. The emerging aquatic insects they consume are a renewable resource, but renewal rates vary considerably during the season. Rather than adjusting territory size to match the current levels of prey abundance in the habitat, wagtails maintain constant territory boundaries. This inflexibility persists even though territories that extend for only three hundred meters could adequately support an individual for about onethird of the season. In contrast, the territory size of an Australian honey eater varies widely during the winter. Nectar productivity of the flowers visited by honey eaters varies considerably during the season. By adjusting territory size to match changing resource levels, individual birds obtain a relatively constant amount of energy each day (about eighteen kilocalories). Sex Roles In some species, only males are territorial. In other species, both sexes defend territories, but males defend larger territories than females do. In some mammals in which both sexes are territorial, males are aggressive only to other males, and females are only aggressive to other females. In these species, male territories are sufficiently large to encompass the territories of several females. Presumably, these males have increased sexual access to the females within their territories. Perhaps the most curious example of sex-specific territorial behavior is observed in a number of coral reef fish, in which all individuals in the population are initially female and not territorial. As the individuals grow older and larger, some develop into males. Once male, they engage in territorial behavior. 636
Territoriality and aggression Within a species, significant variation in territory quality exists among individuals. Studies on numerous species have demonstrated a relationship between territory quality and an individual’s resource-holding potential. For example, larger individuals tend to control prime locations more often than smaller individuals. In addition, possession of higher-quality territories often results in increased reproductive success. For some species, this occurs because individuals with better territories obtain mates sooner or obtain more mates than individuals with poorer territories. In other species, possession of superior territories increases the survival chances of the owner. As the density of conspecifics increases, the ability of individuals to control territories decreases. In some species, the territorial system may break down completely, with all individuals scrambling for their share of needed resources in a chaotic fashion. In other species, the territorial system is replaced by a dominance hierarchy. All competitors may remain in the area, but their access to resources is determined by their rank in the hierarchy. For example, dominant male elephant seals can successfully defend from other males areas containing between eighty and one hundred females. Very dense clusters of females, however (two hundred or more), attract too many males for one male to monopolize. When this happens, one male—usually the largest male—dominates the rest and maintains disproportionate access to females. Territoriality undeniably has an adaptive function: to increase the survival and reproductive success of individuals. Territoriality can also have several possible incidental effects, one of which was once considered to be an adaptive function: serving as a means of population regulation. The reasoning behind this hypothesis is simple. The number of territories in a habitat would limit the number of reproducing individuals in a population and would thereby prevent overpopulation that could cause a population crash. Support for this hypothesis would include demonstration that a significant number of nonbreeding adults exist in a population. Indeed, for several species, experimental removal of territory owners has revealed that “surplus” individuals quickly fill the artificially created vacancies. In most of the species studied, however, these surplus individuals are primarily males. Population growth can be curbed only by limiting the number of breeding females, not the number of breeding males. Furthermore, the population regulation argument assumes that some individuals abstain from reproduction for the good of the population. If such a population did exist, a mutant individual that never abstained from reproducing would quickly spread, and its descendants would predominate in future generations. 637
Territoriality and aggression Territoriality in the Field Territoriality is typically investigated in the field using an observational approach. Initial information collected includes assessing the amount of area used by each individual, how much of that area is defended from conspecifics, and exactly what is being defended. It is relatively easy to discern the spatial utilization of animals. For many species, all that is required is capturing each individual, marking it for field identification, and watching its movements. For species that range long distances, such as hawks or large mammals, and species that are nocturnal, radio telemetry is frequently used. This methodology requires putting radio transmitters on the individuals to be followed and using hand-held antennas, or antennas attached to cars or airplanes, to monitor movements. For fossorial species (animals that are adapted for digging), animal movements are often determined by repeated trapping. This method involves placing numerous baited live traps above the ground in a predetermined grid. Knowing the spatial utilization of an animal does not document territoriality. Many types of animals repeatedly use the same regions in the habitat but do not defend these areas from conspecifics. Such “home ranges” may or may not contain areas that are defended (that is, territories). Territorial defense can be readily documented for some animals by simply observing individual interactions. These data often need to be supplemented by experiments. Behavioral interactions might occur only in part of the organism’s living space because neighbors do not surround it. For these individuals, researchers play tape-recorded territorial vocalizations or place taxidermy mounts of conspecifics in different locations and note the response of the territory holder. For other species, such as fossorial rodents, direct estimates of territory size cannot be obtained because aggressive interactions cannot be observed; as a result, territory boundaries must be inferred from trapping information. Regions in which only the same individual is repeatedly trapped are likely to be areas that the individual defends. This is an indirect method, however, and can be likened to watching the shadow of an organism and guessing what it is doing. It is often difficult to determine exactly what an animal is defending in an all-purpose territory where organisms use many different types of resources. Which resource, that is, constitutes the “reason” for territorial defense? On the other hand, several resources may contribute in some complex way. For many species these things simply are not known. This uncertainty also complicates estimates of territory quality. For example, red-winged blackbirds in North America have been particularly well studied for several decades by different investigators in various parts of the 638
Territoriality and aggression species range. Males defend areas in marshes (or sometimes fields), and some males obtain significantly more mates than others. Biologists think that males defend resources that are crucial for female reproduction. Some males may be more successful at mating than others because of variation in territory quality. Yet the large number of studies done on this species has not yielded a consensus on what the important resources are, whether food, nest sites, or something else. Theoretical investigations of territorial behavior often employ optimality theory and game theory approaches. Optimality theory considers the benefits and costs of territorial defense for an individual. Benefits and costs might be measured simply as the number of calories gained and lost, respectively. Alternatively, benefits might be measured as the number of young produced during any one season; costs might be measured as the reduction in number of future young attributable to current energy expenditures and risks of injury. For territorial behavior to evolve by means of natural selection, the benefits of territorial behavior to the individual must exceed its costs. Game theory analyses compare the relative success of individuals using alternative behaviors (or “strategies”). For example, two opposing strategies might be “defend resources from intruders” and “steal resources as they are encountered.” In the simplest case, if some individuals only defend and other individuals only steal resources, the question would be which type of individual would leave the most offspring. Yet defenders interact with other defenders as well as with thieves, and the converse holds for thieves. By considering the results of interactions within and between these two types of individuals, a game theory analysis can predict the conditions under which one strategy would “win” or “lose” and how the success of each type of individual would vary as the frequency of the other increases in the population. A complete understanding of territoriality involves not only empirical approaches in the field but also the development of testable theoretical models. Considerable advances have been made recently merging these two methodologies. Future investigations will no doubt include experimental control over resource levels that will allow definitive tests of predictions of alternative theoretical models. Evolution of Terrioriality Among animals in general, some species are highly aggressive in defending their living space, and others ignore or tolerate conspecifics in a nearly utopian manner. Some animals are territorial during only part of the annual cycle, and some only in specific areas that they inhabit; others remain aggressive at any time and in any place. Thus, a main goal for researchers is 639
Territoriality and aggression to unravel the ecological and evolutionary conditions that favor aggressive behavior and territoriality. Aggression and territorial behavior appear to have evolved in various organisms because, in the past, aggressive and territorial individuals outreproduced nonaggressive and nonterritorial ones. An implicit assumption of behavioral biologists is that animals other than humans do not interact aggressively because of conscious reasoning, nor are they consciously aware of the long-term consequences of aggressive acts. Should these consequences be detrimental, natural selection will eliminate the individuals involved, even if this means total extinction of the species. Humans are different. They are consciously aware of their actions and of the consequences of such actions. They need only use conscious reasoning and biological knowledge of aggressive behavior to create conditions that can reduce conflict between individuals and groups. Richard D. Howard See also: Altruism; Communication; Defense mechanisms; Displays; Ethology; Habituation and sensitization; Hierarchies; Insect societies; Mammalian social systems; Mimicry; Pheromones; Predation; Reproductive strategies. Sources for Further Study Alcock, John. Animal Behavior. 7th ed. Sunderland, Mass.: Sinauer Associates, 2001. Allen, Colin, and Marc Bekoff. Species of Mind: The Philosophy and Biology of Cognitive Ethology. Cambridge, Mass.: MIT Press, 1997. Davies, Nicholas B., and John R. Krebs. An Introduction to Behavioral Ecology. 4th ed. Boston, Mass.: Blackwell Scientific Publications, 1997. Dennen, J. van der, and V. S. E. Falger, eds. Sociobiology and Conflict: Evolutionary Perspectives on Competition, Cooperation, Violence, and Warfare. New York: Chapman and Hall, 1990. Howard, Eliot. Territory in Bird Life. New York: Atheneum, 1962. Ratcliffe, Derek A. The Peregrine Falcon. 2d ed. San Diego, Calif.: Academic Press, 1993. Wilson, Edward O. Sociobiology. Cambridge, Mass.: The Belknap Press of Harvard University Press, 1975.
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TROPHIC LEVELS AND ECOLOGICAL NICHES Types of ecology: Community ecology; Ecoenergetics; Ecosystem ecology A trophic level is a position in the food pyramid occupied by an organism based on its food relationships with other organisms: what it eats, and what eats it. An ecological niche is the physical space in which an animal lives and all the interactions with the other living organisms and components of its environment.
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he idea of the niche probably had its first roots in ecology in 1910. At that time, Roswell Johnson wrote that different species utilize different niches in the environment. He theorized that individuals of a particular species are only in certain places because of food supply and environmental factors that limit their distribution in an area. Later, in 1924, Joseph Grinnel developed his concept of niche that centered on an organism’s distribution having limits set on it by climatic and physical barriers. At the same time, Charles Elton was defining his own idea of niche. His description of niche involved the way an organism makes its living—in particular, how it gathers food. The Food Pyramid For many years, ecologists focused on Elton’s definition and referred to niche in terms of an organism’s place in the food pyramid. The food pyramid is a simplified scheme in which organisms interact with one another while obtaining food. The food pyramid is represented as a triangle, often with four horizontal divisions, each division being a different trophic level. The base of the food pyramid is the first trophic level and contains the primary producers: photosynthetic plants. At the second trophic level are the primary consumers. These are the herbivores, such as deer and rabbits, which feed directly on the primary producers. Secondary consumers are found at the third trophic level. This third trophic level contains carnivores, such as the mountain lion. The members of the uppermost trophic level are the scavengers and decomposers, including hyenas, buzzards, fungi, and bacteria. The organisms in this trophic level break down all the nutrients (such as carbon and nitrogen) in the bodies of plants and animals and return them to the soil to be absorbed and used by plants. 641
Trophic levels and ecological niches It should be noted that no ecosystem actually has a simple and welldefined food pyramid. Many organisms interact with more than only the organisms at the adjacent trophic levels. For example, a coyote could be considered to belong to the third trophic level with the carnivores, but the coyote also feeds on occasional fruits and other primary producers. Basically, all living things are dependent on the first trophic level, because it alone has the capability to convert solar energy to energy found in, for example, glucose and starch. The food pyramid takes the geometric form of a triangle to show the flow of energy through a system. Photosynthetic plants lose 10 percent of the energy they absorb from the sun as they convert solar energy into glucose and starch. In turn, the herbivores can convert and use only 90 percent of the energy they obtain by eating plants. Hence, less energy is found at each higher trophic level. Because of this reduced energy, fewer organisms can be supported by each higher trophic level. Consequently, the sections of the pyramid get smaller at each higher trophic level, representing the decreasing levels of energy and number of members. Types of Niches Through the years, two concepts of niche have evolved in ecology. The first is the place niche, the physical space in which an organism lives. The second is the ecological niche, and it encompasses the particular location occupied by an organism and its functional role in the community. The functional role of a species is not limited to its placement along a food pyramid; it also includes the interactions of a species with other organisms while obtaining food. For example, the methods used to tolerate the physical factors of its environment, such as climate, water, nutrients, soils, and parasites, are all part of its functional role. In other words, the ecological niche of an organism is its natural history: all the interactions and interrelationships of the species with other organisms and the environment. The study of the interrelationships among organisms has been the focus of ecological studies since the 1960’s. Before this time, researchers had focused on the food pyramid and its effect on population changes of merely a single species. One example, the classic population study of the lynx and the snowshoe hare of Canada, originally focused on the interactions of the species in the food pyramid. It was discovered that the lynx had a ten-year population cycle closely following the population cycle of its prey, the snowshoe hare. The lynx population appeared to rise, causing a decline in the population of the snowshoe hare. In the investigations that followed, however, studies diverted the focus from the food pyramid to other ele642
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The Food Pyramid: Trophic Levels
Decomposers, Scavengers: Bacteria, Fungi, Buzzards, Hyenas
Seconday Consumers: Carnivores
Primary Consumers: Herbivores
Primary Producers: Photosynthetic Plants
More Energy .................................................................. Less Energy
ments of the niche of the two species. For example, the reproductive nature of the hare provided a contradiction to the simple predator-prey explanation. The hare has a faster rate of reproduction than the lynx. It seemed impossible that the significantly lower population of lynx could effectively place sufficient predator pressure on the hare to cause its drastic decline in numbers. Therefore, it appeared that the population dynamics of the hare and lynx were regulated by more than simply a predator-prey relationship. Later studies of the lynx and hare suggested that the peaks and dives in the two populations may also be a factor of parasites of the hare that are 643
Trophic levels and ecological niches carried by the lynx. A rise in the lynx population increases the carriers of parasites of the hare. Therefore, it is thought that, although the hare has a much greater reproduction rate than the lynx, the population of hares will still decline because of the combination of predation by the lynx and the increased frequency of parasites of the hare. This study involved looking at more than one dimension of the ecological niche of a species and broke away from concentrating on only the interactions between organisms in the food pyramid. Niche Overlap: Interspecific The goal of understanding how species interact with one another can also be better accomplished by defining the degree of niche overlap, the degree of the sharing of resources between two species. When two species use one or more of the same elements of an ecological niche, they exhibit interspecific competition. It was once believed that interspecific competition would always lead to survival of only the better competitor of the two species. That was the original concept of the principle of the competition exclusion law of ecology: No two species can utilize the same ecological niche. It was conjectured that the weaker competitor would either migrate, begin using another resource not used by the stronger competitor, or become extinct. It is now believed that the end result of two species sharing elements of ecological niches may not always be exclusion. Ecologists theorize that similar species do, in fact, coexist, despite the sharing of elements of their ecological niches, because of character displacement, which leads to a decrease in niche overlap. Character displacement involves a change in the morphological, behavioral, or physiological state of a species without geographical isolation. Character displacement occurs as a result of natural selection arising from competition between one or more ecologically similar species. Examples might be changes in mouth sizes so that they begin to feed on different sizes of the same food type, thereby decreasing competition. Specialists and Generalists The more specialized a species, the more rigid it will be in terms of its ecological niche. A species that is general in terms of its ecological niche needs will be better able to find and use an alternative for the common element of the niche. Since a highly specialized species cannot substitute whatever is being used, it cannot compete as well as the other species. Therefore, a specialized species is more likely to become extinct. For example, a panda is a very specialized feeder, eating mainly bamboo. If a pest is introduced into the environment that destroys bamboo, the 644
Trophic levels and ecological niches panda will probably starve, being unable to switch to another food source. On the other hand, the coyote is a generalized feeder. A broad variety of food types make up its diet. If humans initiate a pest-control program, killing the population of rabbits, the coyote will not fall victim to starvation, because it can switch to feeding predominantly on rodents, insects, fruits, and domesticated animals (including cats, dogs, and chickens). Hence, species with specialized ecological niche demands (specialists) are more in danger of extinction than those with generalized needs (generalists). Although this fundamental difference in survival can be seen between specialists and generalists, it must be noted again that exclusion is not an inevitable result of competition. There are many cases of ecologically similar species that coexist. Niche Overlap: Intraspecific When individuals of the same species compete for the same elements of the ecological niche, it is referred to as intraspecific competition. Intraspecific competition has the opposite effect of interspecific competition: niche generalizations. In increasing populations, the first inhabitants will have access to optimal resources. The opportunity for optimal resources decreases as the population increases; hence, intraspecific competition increases. Deviant individuals using marginal resources may slowly begin to use less optimal resources that are in less demand. That can lead to an increase in the diversity of ecological niches used by the species as a whole. In other words, the species may become more generalized and exploit wider varieties of niche elements. Representing a situation on the opposite end of the spectrum from that of two organisms competing for the same dimension of an ecological niche is the vacant niche theory. This ecological principle states that when an organism is removed from its ecological niche, space, or any other dimension of the niche, another organism of the same or similar species will reinvade. Field Research Theoretical studies of ecological niches are abstract, since humans are limited to three-dimensional diagrams, and there are more dimensions than three to an ecological niche. This multidimensionality is referred to as the n-dimensional niche. This abstract n-dimensional niche can be studied mathematically and statistically, but the study of ecological niches is mainly a field science. Therefore, its techniques are mainly those used for field research. Research that attempts to describe all the elements of the n-dimensional ecological niche would require extensive observations. Yet, ecological 645
Trophic levels and ecological niches niches are difficult to measure not only because of the plethora of data that would have to be collected but also because of the element of change in nature. The internal and external environment of an organism is always dynamic. Nothing in life is static, even if equilibrium is established. These constant fluctuations create daily and seasonal changes in space and ecological niches. Therefore, because of the constant fluctuations, merely descriptive field observations would not be reliable depictions of an organism’s ecological niche. Ecologists must also resort to quantitative data of measurable features of an organism’s ecological niche. For example, the temperature, pH, light intensity, algae makeup, predators, and activity level of the organism are measurable features of an ecological niche in a pond community. The difficulty is in the collection of each of the necessary measurements making up an ecological niche. The ecologist would have to limit the data to a manageable number of specific dimensions of the niche based on conjecture and basic intuition. Such limitations often lead to incomplete and disconnected measurements that can at best only partially describe a few of the dimensions of the ecological niche. Ecologists realize that complete observations and measurements of all the dimensions of an organism’s ecological niche are unattainable. The focus in understanding how a species interacts with its community centers on determining the degree of niche overlap between any two species. In other words, the level of competition for space niche and resources. Studies of this niche overlap are typically limited to dimensions that can be quantitatively measured. Yet, there is still the problem of deciding which of the dimensions are involved in the competition between the two species. Again, the ecologist must usually rely on inherent knowledge about the two species in question. Often, researchers investigating niche competition measure no more than four ecological niche dimensions to determine the niche overlap in an attempt to understand how two individuals competing for the same space, resources, or other ecological niche features can coexist. Field methods for observations and quantitative measurements of elements of ecological niches, niche overlap, and niche competition are probably endless. To name a few, describing an organism’s niche may involve fecal samples to determine its diet, fecal samples of possible predators to identify its primary predator, animal and plant species checklists of its space niche along with soil components, climatic trends, and the like. Niche competition and overlap often can be studied first in the laboratory under controlled situations. One method might involve recording the population dynamics of the species as different elements in the ecological 646
Trophic levels and ecological niches niche are manipulated to determine which is the better competitor and what is the resource that is most responsible for limiting the population size. Niche and Community The shift in meaning and study from merely space and trophic level placement in the food pyramid to ecological niche of n dimensions has been beneficial for the field of ecology. This focus on community ecology is obviously much more productive for the goal of ecology, the understanding of how all living organisms interact with one another and with nonliving elements in the environment. Perhaps more important is the attempt to describe niches in terms of community ecology, which can be essential for some of humankind’s confrontations with nature. For example, it has become increasingly apparent that synthetic chemicals are often too costly and too hazardous to continue using for control of crop pests and carriers of diseases. The goal is to control pests effectively with biological controls. Biological controls can involve the introduction of natural predators of the undesirable pest or the introduction of a virus or bacteria that eliminates the pest and is harmless to humans and wildlife. The success of a biological control is directly proportional to the knowledge of the pest’s n-dimensional ecological niche and the other organisms with which it comes in contact. A classic example of the havoc that can result from manipulations of nature without adequate ecological information is when Hawaii attempted to use biological controls to eradicate a population of snakes, which humans had accidentally introduced. The biological control used was the snake’s natural predator, the mongoose. One very important dimension of the ecological niche of both species was ignored. One species was active only at night, while the other was active only during the day. Needless to say, this particular venture with a biological control was not a success. Another relevant function of community-oriented studies of ecological niches involves endangered species. In addition to having aesthetic and potential medicinal values, an endangered organism may be a keystone species, a species on which the entire community depends. A keystone species is so integral to keeping a community healthy and functioning that if obliterated the community no longer operates properly and is not productive. Habitat destruction has become the most common cause of drastic population declines of endangered species. To enhance the habitat of the endangered species, it is undeniably beneficial to know what attracts a spe647
Trophic levels and ecological niches cies to its particular preferred habitat. This knowledge involves the details of many of the dimensions of its ecological niche integral to its population distribution. Another common means of endangering the survival of a species is to introduce an organism or exotic species that competes for the same resources and displaces the native species. Solving such competition between native and introduced species would first involve determining niche overlap. It is often stated that an ounce of prevention is worth a pound of cure. Thus, the researching and understanding of all the dimensions of ecological niches are key to preventing environmental manipulations by humankind that might lead to species extinction. Many science authorities have agreed that future research in ecology and related fields should focus on solving three main problems: species endangerment, soil erosion, and solid waste management. This focus on research in ecology often means that studies of pristine communities, those undisturbed, will be the most helpful for future restoration projects. Although quantitative and qualitative descriptions of pristine areas seem to be unscientific at the time they are made, because there is no control or experimental group, they are often the most helpful for later investigations. For example, after a species has shown a drastic decline in its population, the information from the observations of the once-pristine area may help to uncover what niche dimension was altered, causing the significant population decrease. Jessica O. Ellison See also: Animal-plant interactions; Balance of nature; Biodiversity; Biogeography; Biological invasions; Coevolution; Communities: ecosystem interactions; Communities: structure; Competition; Food chains and webs; Herbivores; Omnivores; Phytoplankton; Predation; Symbiosis. Sources for Further Study Bronmark, Christopher, and Lars-Anders Hansson. The Biology of Lakes and Ponds. New York: Oxford University Press, 1998. Ehrlich, Paul R. “Who Lives Together, and How.” In The Machinery of Nature. New York: Simon & Schuster, 1986. Giller, Paul S. Community Structure and the Niche. New York: Chapman and Hall, 1984. Odling-Smee, F. John, Kevin N. Laland, and Marcus W. Feldman. “Niche Construction.” American Naturalist 147, no. 4 (April, 1996): 641-649. Rayner, Alan D. M. Degrees of Freedom: Living in Dynamic Boundaries. River Edge, N.J.: World Scientific Publications, 1997. 648
Trophic levels and ecological niches Ricklefs, Robert E. Ecology. 4th ed. New York: Chiron Press, 1999. Shugart, Herman H. Terrestrial Ecosystems in Changing Environments. New York: Cambridge University Press, 1998. Smith, Robert L. Ecology and Field Biology. 6th ed. San Francisco: Benjamin/ Cummings, 2001. Stone, Richard. “Taking a New Look at Life Through a Functional Lens.” Science 269, no. 5222 (July, 1995): 316-318.
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TROPISMS Type of ecology: Physiological ecology Tropisms represent a variety of adaptations of plants that have allowed them to grow toward or away from environmental stimuli such as light, gravity, objects to climb, moisture in soil, or the position of the sun. These rapid responses, which make use of separate systems for detecting and responding to stimuli, help a plant to survive in its particular habitat.
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lthough plants appear not to move, they have evolved adaptations to allow movement in response to various environmental stimuli; such mechanisms are called tropisms. There are several kinds of tropism, each of which is named for the stimulus that causes the response. For example, gravitropism is a growth response to gravity, and phototropism is a growth response to unidirectional light. Tropisms are caused by differential growth meaning that one side of the responding organ grows faster than the other side of the organ. This differential growth curves the organ toward or away from the stimulus. Growth of an organ toward an environmental stimulus is called a positive tropism; for example, stems growing toward light are positively phototropic. Conversely, curvature of an organ away from a stimulus is called a negative tropism. Roots, which usually grow away from light, are negatively phototropic. Tropisms begin within thirty minutes after a plant is exposed to the stimulus and are usually completed within approximately five hours. Phototropism Phototropism is a growth response of plants to light coming from one direction. Positive phototropism of stems results from cells on the shaded side of a stem growing faster than cells along the illuminated side; as a result, the stem curves toward the light. The rapid elongation of cells along the shaded side of a stem is controlled by a plant hormone called auxin that is synthesized at the stem’s apex. Unidirectional light causes the auxin to move to the shaded side of stems. The increased amount of auxin on the shaded side of stems causes cells there to elongate more rapidly than cells on the lighted side of the stem. This, in turn, causes curvature toward the light. Only blue light having a wavelength of less than 500 nanometers can induce phototropism. The photoreceptors in this system are called cryprochromes and may alter the transport of auxin across cellular membranes, 650
Tropisms thereby facilitating its transport to the shaded side of the stem. Phototropism is important for two main reasons: It increases the probability of stems and leaves intercepting light for photosynthesis and of roots obtaining water and dissolved minerals that they need. Gravitropism Gravitropism is a growth response to gravity. The positive gravitropism of roots involves the root cap, a tiny, thimble-shaped organ approximately 0.5 millimeter long that covers the tip of roots. Decapped roots grow but do not respond to gravity, indicating that the root cap is necessary for root gravitropism. Gravity-perceiving cells, called columella cells, are located in the center of the root cap. Each columella cell contains fifteen to twentyfive amyloplasts (starch-filled plastids) which, under the influence of gravity, sediment to the lower side of columella cells. This gravity-dependent sedimentation of amyloplasts is the means whereby roots sense gravity, possibly by generating electrical currents across the root tip. These gravityinduced changes are then transmitted to the root’s elongating zone, lo-
Tropisms
Gravitropism (geotropism)
Phototropism
Heliotropism (solar tracking)
Thigmotropism
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Tropisms cated 3 to 6 millimeters behind the root cap. The differential growth that causes curvature occurs in the elongating zone. When roots are oriented horizontally, growth along the lower side of the elongating zone is inhibited, thereby causing the root to curve downward. Among the first events that produce this differential growth is the accumulation of calcium ions along the lower side of the root tip. Calcium ions move to the lower side of the cap and elongating zone of horizontally oriented roots. This movement may be aided by electrical currents in the root. The accumulation of calcium along the lower side of the root causes the auxin to accumulate there as well. Because auxin inhibits cellular elongation in roots, the lower side of the root grows slower than the upper side of the root, and the root curves downward. When the root becomes vertical, the lateral asymmetries of calcium and auxin disappear, and the root grows straight down. Gravity-sensing cells in stems are located throughout the length of the stem. As in roots, the auxin and calcium ions in stem cells direct the negative gravitropism (in this case, upward curvature) of shoots. As auxin accumulates along the lower side, calcium ions gather along the upper side of horizontally oriented stems. The accumulation of auxin along the stem’s lower side stimulates cellular elongation there. Gravitropism increases the probability of two important results: Roots will be more likely to encounter water and minerals, and stems and leaves will be better able to intercept light for photosynthesis. Thigmotropism Thigmotropism is a growth response of plants to touch. The most common example of thigmotropism is the coiling exhibited by specialized organs called tendrils. Tendrils are common on twining plants such as morning glory and bindweed. Prior to touching an object, tendrils often grow in a spiral. This type of growth is called circumnutation, and it increases the tendril’s chances of touching an object to which it can cling. Contact with an object is perceived by specialized epidermal cells on the tendril. When the tendril touches an object, these epidermal cells control the differential growth of the tendril. This differential growth can result in the tendril completely circling the object within five to ten minutes. Thigmotropism is often long-lasting. For example, stroking one side of a tendril of garden pea for only a few minutes can induce a curling response that lasts for several days. Thigmotropism is probably controlled by auxins and ethylene, as these regulate thigmotropic-like curvature of tendrils even in the absence of touch. Growing tendrils touched in the dark do not respond until they are illuminated. This light-induced expression of thigmotropism may indicate a 652
Tropisms requirement for adenosine triphosphate (ATP), as ATP will substitute for light in inducing thigmotropism of dark-stimulated tendrils. Tendrils can store the sensory information received in the dark, but light is required for the coiling growth response to occur. Thigmotropism by tendrils allows plants to “climb” objects and thereby increases their chances of intercepting light for photosynthesis. Hydrotropism and Heliotropism Roots also grow toward wet areas of soil. Growth of roots toward soil moisture is called hydrotropism. Roots whose caps have been removed do not grow toward wet soil, suggesting that the root cap is the site of moisture perception by roots. Hydrotropism is probably controlled by interactions of calcium ions and hormones such as the auxins. Heliotropism, or “solar tracking,” is the process by which plants’ organs track the relative position of the sun across the sky, much like a radio telescope tracks stars or satellites. Different plants have different types of heliotropism. The “compass” plants (Lactuca serriola and Silphium laciniatum) that grow in deserts orient their leaves parallel to the sun’s rays, thereby decreasing leaf temperature and minimizing desiccation. Plants that grow in wetter regions often orient their leaves perpendicular to the sun’s rays, thereby increasing the amount of light intercepted by the leaf. Heliotropism occurs in many plants, including cotton, alfalfa, and beans. Sunflowers get their name from the fact that their flowers follow the sun across the sky. On cloudy days, leaves of many heliotropic plants become oriented horizontally in a resting position. If the sun appears from behind the clouds late in the day, leaves rapidly reorient themselves—they can move up to 60 degrees in an hour, which is four times more rapid than the movement of the sun across the sky. Heliotropism is controlled by many factors, including auxins. Practical Implications Biologists are studying tropisms in hopes of being able to mimic these detection and “guidance” systems for human use. Scientists at the National Aeronautics and Space Administration (NASA), for example, have been studying the way plants perceive and respond to gravity to learn how to grow plants in deep space. Understanding the gravity detection and guidance systems in plants may help people design more effective rockets, which, like plants, must respond to gravity to be effective. Randy Moore See also: Adaptations and their mechanisms. 653
Tropisms Sources for Further Study Campbell, Neil A., and Jane B. Reece. Biology. 6th ed. San Francisco: Benjamin Cummings, 2002. Evans, Michael L., Randy Moore, and Karl H. Hasenstein. “How Roots Respond to Gravity.” Scientific American 255 (December, 1986): 112-119. Hart, James Watnell. Plant Tropisms and Other Growth Movements. Boston: Unwin Hyman, 1990. Haupt, W., and M. E. Feinleib, eds. The Physiology of Movements. New York: Springer-Verlag, 1979. Salisbury, Frank B., and Cleon W. Ross. Plant Physiology. 4th ed. Belmont, Calif.: Wadsworth, 1992. Satter, R. L., and A. W. Galston. “Mechanisms of Control of Leaf Movements.” Annual Review of Plant Physiology 32 (1981): 83-103. Taiz, Lincoln, and Eduardo Zeiger. Plant Physiology. 2d ed. Sunderland, Mass.: Sinauer Associates, 1998.
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TUNDRA AND HIGH-ALTITUDE BIOMES Types of ecology: Biomes; Ecosystem ecology Regions where no trees grow because of frozen soil or extreme water runoff due to steep grades (at high altitudes) are known as tundra. High altitude biomes have similar limitations on the growth of plant life.
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undra landscapes appear where long, cold winters, a permanently frozen subsoil, and strong winds combine to prevent the development of trees. The resulting landscapes tend to be vast plains with low-growing forbs and stunted shrubs. Vast areas of this biome encircle the northernmost portions of North America and Eurasia, constituting the Arctic tundra. Climatic conditions atop high mountains at all latitudes are similar; these small, isolated areas are called the alpine tundra. Permafrost The low temperatures of the tundra regions cause the formation of a permanently frozen layer of soil known as permafrost. Characteristic of Arctic tundra, permafrost, which varies in depth according to latitude, thaws at the surface during the brief summers. As the permafrost below is impenetrable by both water and plant roots, it is a major factor in determining the basic nature of tundra. The alternate freezing and thawing of soil above the permafrost creates a symmetrical patterning of the land surface characteristic of Arctic tundra. Perhaps the best known features of the landscape are stone polygons that result when frost pushes larger rocks toward the periphery, with smaller ones occupying the center of each unit. This alteration of the tundra landscape, called cryoplanation, is the major force in molding Arctic tundra landscapes. In contrast, alpine tundra generally has little or no permafrost. Even though alpine precipitation is almost always higher than for Arctic tundra, steep grades result in a rapid runoff of water. Alpine soils are, therefore, much drier, except in the flat alpine meadows and bogs, where conditions are more like those of Arctic areas. Vegetation Both Arctic and alpine tundra regions are composed of plants that have adapted to the same generally stressful conditions. Biodiversity of both 655
Tundra and high-altitude biomes plants and animals—the total number of species present—is low compared to most other ecosystems. Plant growth is slow because of the short growing seasons and the influence of permafrost. Most tundra plants are low-growing perennials that reproduce vegetatively rather than by seed. Often they grow in the crevices of rocks that both shelter them in the winter and reflect heat onto them in summer. Common plants of the low-lying Arctic tundra sites include various sedges, especially cottongrass, and sphagnum moss. On better-drained sites, biodiversity is higher, and various mosses, lichens, sedges, rush species, and herbs grow among dwarfed heath shrubs and willow. The arrangement of plants within a small area reflects the numerous microclimates resulting from the peculiar surface features. Alpine plants possess many of the features of Arctic plants. However, because strong winds are such a prominent feature of the alpine environment, most of the plants grow flat on the ground, forming mats or cushions. Below alpine tundra and south of Arctic tundra, there is the boreal (also known as taiga) biome, dominated by coniferous forest. Between the forest and tundra lies a transitional zone, or ecotone. This ecotone is characterized by trees existing at their northern (or upper) limit. Especially in alpine regions, stunted, gnarled trees occupy an area called krummholz. In North
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Tundra and high-altitude biomes America, the krummholz is much more prominent in the Appalachian Mountains of New England than in the western mountains. Conservation Like all world biomes, tundra regions are subject to degradation and destruction, especially as a result of human activities. Because of low human population density and their unsuitability for agriculture, tundras generally are less impacted by humans than are grasslands and forests. However, tundra ecosystems, when disturbed, recover slowly, if at all. As most tundra plants lack the ability to invade and colonize bare ground, the process of ecological succession that follows disturbances may take centuries. Even tire tracks left by vehicles can endure for decades. The melting of permafrost also has long-lasting effects. The discovery of oil and gas in tundra regions, such as those of Alaska and Siberia, has greatly increased the potential for disturbances. Heavy equipment used to prospect for fossil fuels and to build roads and pipelines has caused great destruction of tundra ecosystems. As the grasses and mosses are removed, the permafrost beneath melts, resulting in soil erosion. The disposal of sewage, solid wastes, and toxic chemicals poses special problems, as such pollutants tend to persist in the tundra environment longer than in warmer areas. Animals of the Arctic tundra, such as caribou, have been hunted by the native Inuit using traditional methods for centuries without an impact on populations. The introduction of such modern inventions as snowmobiles and rifles has caused a sharp decline in caribou numbers in some areas. Although efforts at restoring other ecosystems, especially grasslands, have been quite successful, tundra restoration poses difficult problems. Seeding of disturbed Arctic tundra sites with native grasses is only marginally successful, even with the use of fertilizers. In alpine tundra, restoration efforts have been somewhat more successful but involve transplanting as well as seeding and fertilizing. A recognition of natural successional patterns and long-term monitoring is a necessity in such efforts. Thomas E. Hemmerly See also: Biomes: determinants; Biomes: types; Forests; Habitats and biomes; Mountain ecosystems; Taiga. Sources for Further Study Johnson, Rebecca L. A Walk in the Tundra. Minneapolis: Carolrhoda Books, 2000. 657
Tundra and high-altitude biomes Sayre, April Pulley. Tundra. Frederick, Md.: Twenty-first Century Books, 1995. Shepherd, Donna W. Tundra. New York: Franklin Watts, 1997. Smith, R. L., and T. M. Smith. Elements of Ecology. 4th ed. San Francisco: Benjamin Cummings, 1998. Walker, Tom. Caribou: Wanderer of the Tundra. Portland, Oreg.: Graphic Arts Center, 2000. Zwinger, Ann H., and Beatrice E. Willard. Land Above the Trees: A Guide to American Alpine Tundra. Boulder, Colo.: Johnson Books, 1996.
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URBAN AND SUBURBAN WILDLIFE Types of ecology: Landscape ecology; Restoration and conservation ecology The global increase in the human population growth and density has seen a simultaneous increase in the growth of urban and suburban areas throughout the world. As urban habitats and their suburban extensions have become more common, the wildlife of these human landscapes has become the focus of attention and study.
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nimals and plants of cities and suburbs are categorized as urban wildlife. As cities and suburbs grow ever larger and displace natural habitats, many city and suburban landscapes have become more attractive for certain kinds of wildlife, or at least urban wildlife has become more noticeable. Urban wildlife consists of an eclectic and unlikely mix of escaped pets (including cats, dogs, reptiles, exotics, and caged birds), feral animals, furtive and temporary intruders from adjacent natural habitats, and species whose natural ecology and behavior enable them to fit within humanmodified landscapes and tolerate living in close proximity to humans. Urban Habitats Urban landscapes present a seemingly stark and forbidding environment for wildlife. The horizontal streets and sidewalks are punctuated by rising angles and arches of concrete and steel that in turn are topped by wood and metal rooftops. Overhead, a maze of telephone, power, and cable lines limits vertical movement, while vehicle and foot traffic poses a constant threat to surface movement. All of these edifices and connecting corridors and lines result in a complex, vertically structured environment that some animals find difficult to maneuver yet to which other animals quickly adapt. In addition to this monotonous and often dangerous structural diversity, urban wildlife is subject to elevated and often almost continuous noise and disturbance and is constantly exposed to an enormous variety of residential wastes (garbage, litter, excess water, salts, sewage), vehicular pollutants (lubricants, greases, gasoline, hydrocarbons, nitrogen oxides), and chemical wastes (pesticides, paints, lead, mercury, contaminants). Despite the forbidding features of urban habitats, a surprising variety of wildlife manages to exist on a more or less permanent basis. In fact, some kinds of wildlife can be found even in the midst of the most degraded forms of urban blight. Ailanthus, which is also commonly called tree-of-heaven, is but one of many opportunistic trees and shrubs that can take root and 659
Urban and suburban wildlife grow given a bare minimum of soil and nutrients. A simple linear crack in the pavement of a sidewalk, a little-used roadway, an unused parking area, or a vacant lot can trap enough windswept dirt to offer a growing substrate for Ailanthus and similar hardy plants. Each Ailanthus, in turn, provides food and shelter for equally tough and adaptable wildlife, ranging from the variety of invertebrates that colonize and feed upon Ailanthus to birds and mammals that take shelter or find food in its branches and foliage. Similarly, every invading sprig of grass, wildflower, shrub, or tree, however large or small, creates its own suite of microhabitats which, in turn, offer colonization opportunities for other plants and animals, the whole ultimately contributing to an overall increase in urban biodiversity. Benefits of Urban Habitats Ailanthus is an example of those plants and animals able to tolerate the most extreme urban conditions, but in reality most urban wildlife derives a number of benefits by living within the confines of cities and suburbs. Far from being homogeneous expanses of concrete, most urban centers are a patchwork of different habitats—residential, commercial, and industrial buildings, warehouses, power stations, vacant lots, detached gardens, rooftop gardens, and alleyways—that each offer innumerable opportunities for wildlife. Many urban areas also have a number of limited access areas that animals are quick to adopt for shelter and breeding places; these include fenced-in lots and boarded-up buildings, along with a rabbit warren of underground tunnels, ducts, steam and water pipes, basements, and access ways. City lights extend foraging time and opportunities, allowing wildlife to hunt for food not only throughout the day but also during much of the night, as needed. Urban nooks and crannies offer an extensive variety of microhabitats that differ fundamentally in size, microclimate, and structural features. These microhabitats serve primarily as shelters and breeding sites for city wildlife. Many birds, such as house sparrows (Passer domesticus) and Eurasian starlings (Sturnis vulgaris) nest in innumerable crevices, cracks, nooks, niches, and sheltered rooftops. Pigeons (Columbia livia) and starlings hide in sheltered enclaves offered by bridge abutments and supports, archways, and other edifices. The most adaptable forms of wildlife are quick to find and take advantage of subtle advantages offered in urban habitats: Many birds cluster around chimneys and roof reflectors or in shelters afforded by lee sides of rooftops during harsh cold and windstorms. Others are equally quick to obtain warmth by sitting on poles, rooftops, or other elevated perches to orient toward sunlight, while at ground level animals gather near gratings, vents, and underground heating pipes. 660
Urban and suburban wildlife Urban Scavengers Urban wildlife just as quickly concentrates in areas where potential food is made available—for instance, during trash pickup—then just as quickly disperses to find new food sources. Most forms of urban wildlife forage opportunistically as scavengers, specializing in finding and consuming all bits of discarded food, raiding trash cans, and concentrating at waste collection and disposal centers. Thus, the rubbish dumps, found in or immediately adjacent to every city of the world, attract an amazing diversity of small mammals and birds. Feeding on the scavenged food of urban areas and bird feeders is much more efficient because it requires less energy to find or catch and is usually available throughout the year. Because of the need to find and exploit temporary food resources, some of the most successful urban animals forage in loose groupings or flocks: The more eyes there are for searching, the more feeding opportunities can be identified and exploited. Solitary and nonsocial species often do less well in urban environments simply because they lack the collective power of the group to find food and shelter, and avoid enemies. The availability of a year-round food supply—however tenuous and temporary—along with the presence of an enormous variety of safe shelters and breeding sites promotes a higher life expectancy, which partly or mostly balances the higher vehicle-related death rates to which urban wildlife is continuously subject. Urban Parks Parks and open space provide the only true natural habitat refuges set deep within urban and suburban landscapes. Such open-space habitats function as ecological islands in a sea of urbanism. Most are necessarily managed habitats rather than entirely natural and, like the urban environment that surrounds them, are usually subject to constant disturbance from adjacent traffic, noise, and other forms of pollution. Economically, since most open-space parks are set aside and maintained for a variety of recreational purposes rather than as natural habitats, the wildlife that colonizes these unnatural natural habitats must have an unusually high tolerance for human presence and recreational activities of all kinds. Urban Birds For some forms of urban wildlife, the urban landscape is merely a humanmade version of their natural environment. Thus, for pigeons the ledges, cracks, and crevices of buildings and bridges represent an urban version of the cracks and crevices of cliffs and rock outcrops that they use for roosting 661
Urban and suburban wildlife and nesting in their native habitats. Similarly, the short-eared owls (Asio flammeus) and snowy owls (Nyctea scandiaca) that show up in winter to stand as silent sentinels at airports, golf courses, and other open areas are simply substituting these managed short-grass habitats for the tundra habitats preferred by snowy owls and the coastal marshes hunted by shorteared owls. Their summer replacements include a host of grassland nesting species such as grasshopper sparrows, kildeer, and upland sandpipers, which all find these managed habitats to be ideal substitutes for the native grasslands which they displaced or replaced. Many bird inhabitants of urban and suburban environments are exotics which were deliberately or inadvertently introduced into urban areas. Certainly the three birds with the widest urban distribution in North America, the pigeon or rock dove, European starling, and house sparrow or English sparrow, all fit within this category. The introduction of the European starling into North American cities and suburbs resulted from the dedicated efforts of the American Acclimitization Society of the late 1800’s. The goal of this society was the successful introduction of all birds mentioned in the works of Shakespeare into North America. Unfortunately for North Americans, the character of Hotspur in Henry IV makes brief note of the starling, so the society repeatedly attempted to introduce the starling into Central Park until they were finally successful. Since then, the starling has become the scourge of cities and suburbs throughout much of North America and the rest of the civilized world. Starlings damage and despoil crops, and dirty buildings with their droppings. The association between house sparrows and urban centers is apparently very old. Evidence suggests that they abandoned their migratory ways to become permanent occupants of some of the earliest settlements along the Nile and Fertile Crescent, a trend that has continued to this day. Sparrows and starlings both share certain characteristics that enable them effectively to exploit urban and suburban habitats; both are aggressive colonizers and competitors, able to feed opportunistically on grains, crops, discarded bits of garbage, and other food supplies. Avian occupants also include an increasing diversity of released caged pets, avian and otherwise. Thus, urban locales in Florida, Southern California, and along the Gulf Coast support an ever increasing diversity of parakeets, parrots, finches, and lovebirds, all stemming from caged pet birds either deliberately released or lost as escapees. Feral Animals Feral animals, mostly dogs (Canidae) and cats (Felidae), represent another important source and component of urban wildlife. Feral dogs revert to 662
Urban and suburban wildlife
Along with squirrels, opossums, rats, coyotes, deer, bears, and other animals, the omnivorous raccoons are among the most familiar forms of wildlife that coexist with humans in urban and suburban neighborhoods, eating everything they can find and often so accustomed to the human presence that they approach people to beg for handouts. (PhotoDisc)
primal adaptive behaviors, gathering in loose packs that usually forage and take shelter together, but have limited success because almost all cities in developed countries have ongoing measures to control and remove them whenever found. Feral cats are often more successful because they are secretive, mostly nocturnal, and can better exploit available urban food sources. The role of other feral animals as urban wildlife, mostly escaped pets, is not well known. Humans and Urban Wildlife The attitude of urban dwellers toward urban wildlife varies greatly. For many humans, urban wildlife offers a welcome respite from their otherwise dreary and mundane surroundings. Urban wildlife in all of its forms and colors can be aesthetically attractive, even beautiful, and is also compellingly interesting. For example, the nesting of a pair of red-tailed hawks (Buteo jamaicensis) in New York City’s Central Park sparked a remarkable interest in bird-watching in the city and a heightened awareness of exactly how exciting wildlife watching can be. All facets of the pair’s courtship and nesting were observed and reported in newsprint, novellas, and even 663
Urban and suburban wildlife a book, Red-Tails in Love. Other animals, while not nearly as large, conspicuous, and glamorous in their color and disposition, also elicit interest. Urban wildlife adds lively color and contrast to the otherwise monotonous gray and grime of streets and sidewalks. Part of the attraction is that urban birds are usually already sufficiently tolerant to be semitame in spirit, easily seen and observed, and, in some instances, easily attracted by strategically placed bird feeders and birdhouses. Public attitudes toward urban predators vary considerably. Some people find them attractive and interesting and even put out food for them. Others consider them pests or potentially dangerous and avoid them. During rabies outbreaks or public scares, most urban wildlife is targeted by various control programs to remove unwanted animals. Suburban Wildlife Habitats The vast sprawl of suburbs across the landscape offers many types of wildlife yet another habitat to exploit, either as residences or as waystations during the search for food or shelter. Like urban areas, suburbs offer a range of differing habitats. The simplest suburbs are merely extensions of urban row houses with minimal yardscapes, but there is an increasing progression toward more open and natural yards in outlying suburbs that merge with rural areas and natural habitats. The larger and more diverse yards at the edges of suburbs often help blur the distinction and diversity between human landscapes and natural landscapes. Ornamental trees, shrubs, flowers, gardens, and lawns that characterize almost all suburban habitats provide a series of artificial habitats that can actually increase wildlife diversity. Again, the chief wildlife benefactors are species that can best ecologically exploit the unnatural blend of woodland, edge, and meadow that suburban landscapes offer. It is no accident that some of the most common components of suburban wildlife include thrushes such as robins, finches, cardinals, titmice, blue jays, crows, and many other similar birds. All of these species are actually responding to the structural components of the suburban landscape, which provide suitable substitutes for their natural landscapes. The blend of ornamental and garden vegetation offered by most suburban landscapes offers food for a diversity of what were once considered less tolerant wildlife. Deer, wild turkey, grouse, and a host of other animals, large and small, make periodic forays into suburbs in search of food. Crepuscular and nocturnal wildlife is much more likely effectively to exploit food sources offered by suburban landscapes than diurnal wildlife, which is more at risk because of its high visibility during daylight hours. 664
Urban and suburban wildlife Predators Well-wooded suburban habitats that attract a variety of wildlife also attract an increasing number of predators. American kestrels (Falco sparverius), Cooper’s hawks (Accipiter cooperi), barn owls (Tyto alba), screech owls (Otus spp.), and little owls (Athene noctua) provide but a small sampling of birds of prey that nest deep within urban and suburban environments, taking advantage of open-space habitats deep within cities and quickly exploiting unused areas within most suburbs. Terrestrial predators are almost equally common, but most are nocturnal or nearly so; consequently, their contacts with humans are quite limited. Many urban predators, are, in fact, mistaken for neighborhood pets and left alone or are recognized and avoided: Coyotes (Canis latrans) are often mistaken for dogs, especially when seen in twilight. The wily coyote is equally at home in the suburbs of Los Angeles, California, and the urban parks of New Haven, Connecticut, joining a host of small and medium-sized mammal predators such as foxes (Vulpes spp.) and scavengers such as opossums (Didelphis marsupalis), raccoons (Procyon lotor), and skunks (Mephitis mephitis). These urban predators have many behavioral attributes in common. All are omnivorous and able to feed on a wide variety of natural foods such as fruit, small birds and mammals, insects, and invertebrates such as beetles, grasshoppers, and earthworms. Foraging and food habits of urban predators sometimes conflict with human concerns. Urban foxes hunt and kill cats, especially kittens, if given the opportunity, while the larger and stronger urban coyote will often not hesitate to kill and eat cats and dogs, to pet owners’ dismay. Wildlife Management Urban wildlife must be much more closely managed than wildlife of natural environments because urban and suburban habitats attract an enormous number of pest species as well as interesting and beneficial species. Introduced species such as starlings may also transmit histoplasmosis, a fungal disease that attacks human lungs. Other birds may also be harbingers, carriers, and vectors of various diseases, the most notable of which are the parrots and parakeets, which transmit parrot fever or psittocosis. Rats and mice (Rodentia) carry and spread disease and despoil both residential and public buildings and other structures. The growing interest in urban wildlife has stimulated innumerable programs to promote beneficial wildlife. Both public and private organizations and agencies have embarked on a variety of programs aimed at remodeling existing habitats and even creating new habitats for urban wildlife. 665
Urban and suburban wildlife Programs aimed at creating new or modifying existing urban habitats come in a variety of categories, such as linear parks, greenways, urban wildlife acres programs, backyard gardens, and treescaping streets and roadways, all of which create biodiversity, which in turn provides attractive habitats for colonization by additional animals and plants. Modifications of existing habitats to increase animal biodiversity include “critter crossings,” roadside habitats, backyard gardens, arbor plantings, all of which provide refuges, shelters, breeding sites, connecting corridors, and safe havens that promote the welfare of urban and suburban wildlife. Many existing open-space habitats are also being modified. Many urban renewal commissions have placed new and more restrictive regulations on the use of pesticides and fertilizers on golf courses, which not only reduces incidence and intensity of nonpoint pollution from the golf courses but also reduces the incidence of wildlife poisoning. These steps cannot help but increase the biotic potential of golf courses for supporting local biodiversity. Dwight G. Smith See also: Biodiversity; Food chains and webs; Landscape ecology; Trophic levels and ecological niches; Wildlife management. Sources for Further Study Adams, Lowell W. Urban Wildlife Habitats: A Landscape Perspective. Minneapolis: University of Minnesota Press, 1994. Bird, David, Daniel Varland, and Juan Josè Negro, eds. Raptors in Human Landscapes. San Diego, Calif.: Academic Press, 1996. Forman, Richard, and Michel Godron. Landscape Ecology. New York: John Wiley & Sons, 1986. Gill, Don, and Penelope Bonnett. Nature in the Urban Landscape: A Study of City Ecosystems. Baltimore: York Press, 1973. McDonnell, Mark J., and Steward T. A. Pickett, eds. Humans as Components of Ecosystems. New York: Springer-Verlag, 1993.
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WASTE MANAGEMENT Types of ecology: Ecotoxicology; Restoration and conservation ecology Waste management concerns the physical by-products of human activity that cannot be reintegrated into the ecological biomass cycle. These by-products include solid, liquid, and airborne substances that are potentially harmful to living organisms. As the human population grows and the use of manufactured materials expands, disposing of waste becomes more challenging.
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ccording to the World Watch Institute, world production of manufactured materials (not counting recycled materials) increased nearly 2.5 times between the early 1960’s and the late 1990’s. In industrialized countries the increase is far greater: The United States, for example, has seen an eighteenfold increase in materials production since 1900. The average U.S. citizen throws away an estimated 2 to 8 pounds of garbage daily, and although studies demonstrate that the per-person production of waste remained approximately the same throughout the twentieth century, the sharp rise in population and expanding industrial base meant greater total accumulations of waste. Furthermore, the types of waste changed. Waste is commonly categorized as domestic, or solid, waste, and industrial, or liquid, waste, although the distinction is not absolute. Both may contain toxic substances, but the percentage of toxins in industrial waste is likely to be higher, and the types of waste are disposed in different ways. The smoke emitted from industrial processing of materials and vehicle exhaust are additional types of waste, although they are commonly thought of as pollution rather than waste. Solid Waste Solid waste is the familiar garbage that households and businesses in the United States have sent to the dump since garbage collection began late in the nineteenth century. The largest portion, more than 40 percent, consists of paper products, especially newspaper and containers. Yard waste, food debris, plastic containers and wrappings, bottles, metals, and appliances are also regularly thrown away. About 1 percent of this waste involves hazardous materials, typically insecticides, beauty aids, and cleaning products. Construction waste accounts for a large share—about 12 percent—of solid waste and may contribute a higher proportion of hazardous materials, such as solvents and paint. Although most of these materials are solid, when dumped together 667
Waste management
A wastewater treatment plant collects the domestic and industrial effluent that has been conveyed to its location by a sewage system and treats this contaminated water by removing solids, filters, biological decomposition, and other processes, ending in release into the ground or, more usually, into a surface watercourse. (PhotoDisc)
they can soak up rainwater and then ooze chemical-laden liquids. This leachate may filter down into the groundwater and pollute nearby streams and wells. If it contains toxic elements, such as the lead or mercury from batteries, the leachate can be dangerous to health. The odor from rotting garbage may also foul the air, seldom enough to be harmful but still repellent to people living nearby. It can attract animal scavengers, which may become infected with diseases from the garbage and spread them to other animals or even humans, especially if feces are part of the waste. In order to combat these effects, sanitary landfills place a plastic lining under the waste to contain leachate and cover each day’s load of garbage under a thin layer of soil. Pipe systems also disperse methane gas produced by rotting organic materials. The landfills are therefore less dangerous to human health or the environment, but many old, abandoned sites were not so well engineered. They may continue to dribble harmful chemicals into groundwater for decades and emit methane, which is flammable. Numerous small, illegal dumps and litter compound the problem. Measures to reduce the amount of waste deposited in landfills have partially succeeded. Recycling has drastically cut the total paper, metal, 668
Waste management and glass waste in some U.S. states and industrialized countries. The use of garbage disposals and composting has caused the proportion of organic materials to decline. However, such reductions did not eliminate solid waste. By the end of the twentieth century, cities were finding it increasingly difficult to find room for new landfill sites, even when the space was urgently needed. Stringent regulations about the geological composition of landfills reduced the number of usable sites, while objections from citizen action committees, known as “not in my back yard” (NIMBY) groups, also eliminated sites near populated areas. Facilities used to incinerate waste, which sometimes powered electrical generators with the resulting heat energy, also faced objections because burning could release health-threatening materials, such as dioxins, into the air. Moreover, a significant proportion of waste, such as appliances and concrete, cannot be eliminated by burning. Tires, too hazardous to burn, float to the surface in landfills, causing continuous problems for waste managers; they often end up stacking the tires in immense piles that, if accidentally ignited, can burn out of control and create large clouds of black fumes. Industrial Waste The effluent stream of by-products from factories, as well as chemical and petroleum refineries, is made up of water, solid filings and cuttings, liquid solvents and oil derivatives, and semisolid sludge. The solid components are usually no more hazardous than household wastes, although medical waste—particularly tainted blood and used “sharps,” such as needles and scalpels—may pose the additional danger of spreading disease. However, liquids and semiliquids sometimes contain a high proportion of hazardous chemicals. Rain also leaches chemicals, such as cyanide and mercury, out of the smelted tailings from mines. Agricultural fertilizers and pesticides can enter groundwater or streams as well. Because these liquid wastes rapidly spread through waterways and groundwater, they are often collectively known as toxic waste. Industry now uses all ninety-two naturally occurring elements on the periodic table, and the isotopes of some of these are radioactive. Nuclear weapons manufacturing in particular leaves radioactive debris, but medical procedures that use radioactive tracers and scientific instruments may also create radioactive wastes. This nuclear waste continues to emit radiation for thousands or hundreds of thousands of years, and improperly stored radioactive materials have been associated with increased risk of disease for people, animals, and plants. During the 1980’s and 1990’s federal and state regulations brought industrial waste management under rigorous control. Facilities known as se669
Waste management cure landfills are designed to contain nonradioactive industrial wastes in tightly lined, self-contained areas. Incinerators reduce the waste to harmless ash while releasing few or no harmful particulates into the atmosphere. Separate repositories store nuclear wastes deep underground in leak-proof containers. The public is seldom reassured by such measures, however. Leakage occasionally occurs from secure landfills. Near-zero toxic emissions from incineration means that some toxins do, in fact, escape into the atmosphere. In addition, nuclear repositories may not be catastrophe proof; for example, an earthquake could crack open containers, releasing radioactive material into groundwater supplies. Although waste managers insist that these dangers are minimal, the news media bring them to public attention, and NIMBYs regularly resist the opening of new secure landfills and radioactive waste repositories. State governments often object as well, as was the case when the Nevada legislature stalled the construction of a nuclear repository at Yucca Mountain. Many old facilities, built before strict government oversight, remain in use and could leak toxic materials into the environment undetected. The memory of deadly chemical leaks, such as that discovered at Love Canal in New York in 1976, and of released radioactive material, such as the plutonium that escaped the Hanford Nuclear Reservation in Washington State, makes the public wary of hazardous wastes. As a result of citizen concern, most new hazardous waste disposal sites are now located far from population centers. This has created a new peril. The waste must be transported, primarily by trucks and trains, to a facility. Traffic accidents and train derailings en route can dump extremely dangerous chemicals straight into water or the atmosphere. Evacuations of residents near such accidents, while not common, increased during the 1990’s. Even if people are rescued, however, plant and animal life is not safeguarded. Environmental Consequences Many critics of waste management insist that only source reduction—a drastic decrease in the use of raw materials—will make waste disposal safe. Accordingly, during the 1990’s some countries, notably Denmark and Germany, sought to reduce virgin material use as much as 90 percent by intensifying recycling. In the United States, Superfund legislation was passed to set aside federal funds to pay for cleanups of the most dangerous hazardous waste sites. Other industrial countries have similar projects. Still, only a fraction of sites receive attention, and until source reduction goals are met, household and industrial wastes will continue to swell land670
Waste management fills with environmentally hazardous substances. Illegal dumping of hazardous waste exacerbates the danger. Scientists disagree about how severely wastes damage the environment, but there is agreement that repercussions are evident and likely to increase. Methane from dumps, smoke-stack emissions, and vehicle exhaust contain greenhouse gases, which are implicated in global warming. Nutrients released from sewers, as well as runoff from agriculture and mining, degrade the environment of rivers and streams, harming aquatic life and leaving the water unusable without special treatment. The waterborne wastes that reach the ocean, supplemented by ocean dumping of toxic materials, alter and sometimes destroy offshore ecosystems, as is the case for many coral reefs worldwide. Roger Smith See also: Biological invasions; Biomagnification; Biopesticides; Deforestation; Eutrophication; Genetically modified foods; Integrated pest management; Invasive plants; Ocean pollution and oil spills; Ozone depletion and ozone holes; Pesticides; Phytoplankton; Pollution effects; Slash-and-burn agriculture. Sources for Further Study Baarschers, William H. Eco-Facts and Eco-Fiction: Understanding the Environmental Debate. New York: Routledge, 1996. Dunne, Thomas, and Luna B. Leopold. Water in Environmental Planning. San Francisco: W. H. Freeman, 1978. Gourlay, K. A. World of Waste: Dilemmas of Industrial Development. New York: St. Martin’s Press, 1992. Laak, Rein. Wastewater Engineering Design for Unsewered Areas. Lancaster, Pa.: Technomic, 1986. McGhee, Terrence. Water Supply and Sewerage. New York: McGraw-Hill, 1991. Qasim, Syed R. Wastewater Treatment Plants: Planning, Design, and Operation. 2d ed. Lancaster, Pa.: Technomic, 1999. Rathje, William, and Cullen Murphy. Rubbish! The Archaeology of Garbage. Tucson: University of Arizona Press, 2001. Salvato, Joseph A. Environmental Engineering and Sanitation. 4th ed. New York: Wiley, 1992. Tillman, Glenn M. Wastewater Operations: Troubleshooting and Problem Solving. Chelsea, Mich.: Ann Arbor Press, 1996. Whitaker, Jennifer Seymour. Salvaging the Land of Plenty: Garbage and the American Dream. New York: William Morrow, 1994. 671
WETLANDS Types of ecology: Biomes; Ecosystem ecology Wetlands, transitional areas between aquatic and terrestrial habitats, are home to a variety of flood-tolerant and salt-tolerant plant species.
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etlands represent one of the most biologically unique and productive of all natural habitats. In their unaltered state, these waterinfluenced areas are used by a variety of wildlife species. These habitats also have the ability to take up and store water during floods, and their soils and plants have the ability to remove nutrients and heavy metals from water. The recognition of these values helped to slow the rate of wetlands loss to such uses as agricultural development and urban expansion. A desire to protect remaining wetland acres has led to a significant movement for wetlands preservation. Definition of Wetlands Ecologists recognize wetlands as a type of ecotone. Ecotones are unique areas that represent a transition from one type of habitat to another. Often, these transitional areas have characteristics of both habitats. Wetlands are areas located between aquatic, water-based habitats and dry land. Because they are located at the edge of an aquatic habitat, wetlands are always influenced to some degree by water. They are not always under water, as are aquatic habitats, and they are not always dry, as are terrestrial habitats. The most important environmental factor in wetlands is the periodic or frequent occurrence of water. This presence of water influences both the nature of the soil and the flora and fauna of a region. Soils which experience periodic coverage with water become anoxic, develop a dark color, and give off an odor of hydrogen sulfide. These soil characteristics differ from those of upland soils and give wetland soils their unique hydric nature. In these soils influenced by water, only flood-tolerant hydrophyte species can exist. Hydrophytic plants vary in their tolerance to flooding from frequent (such as bald cypress) to infrequent (such as willows). In defining a particular area as a wetland, often all three of the components listed above are used: water, hydric soils, and hydrophytic plants. However, the presence of water is not always a reliable indicator because water rarely covers a wetland at all times. Often, a wetland is dry during a period of low river flow or during a low tide. For this reason, only hydric 672
Wetlands soils and hydrophytic plants should be used as reliable indicators of a wetland. The broadest classification of wetlands includes two categories: freshwater and saltwater wetlands. Freshwater wetlands occur inland at the edges of rivers, streams, lakes, and other depressions that regularly fill with rainwater. Saltwater wetlands occur along the coast in bays, where salt water and fresh water mix and wave energy is reduced. Freshwater Wetlands Of the two categories, freshwater wetlands are by far the most common. Freshwater wetlands are subdivided into two categories: tree-dominated types and grass-dominated types. Tree-dominated freshwater wetlands include areas that are frequently covered with water (such as cypress swamps) and those that are only occasionally covered with water (such as bottomland forests). Grass-dominated types include freshwater marshes, prairie potholes, and bogs. While freshwater marshes are widespread, prairie potholes and bogs occur regionally in the United States. Prairie potholes are located in the central portion of the United States, while bogs are found in the Northeast and Great Lakes regions.
Wetlands are a special ecotone, or transitional environment, with characteristics of both dry and aquatic habitats and therefore are home to a large variety of plants, animals, birds, and other forms of life. (PhotoDisc) 673
Wetlands Saltwater Wetlands Saltwater wetlands are also subdivided into tree-dominated and grassdominated types. Tree-dominated types include tropical mangrove swamps. Grass-dominated types can be further subdivided into salt marshes and brackish marshes. Salt marshes occur in bays along the coast where salt water and fresh water mix in almost equal proportions. Brackish marshes occur farther inland than salt marshes do; their mix contains less seawater and more fresh water. Both grass-dominated types are common in bays along the Gulf of Mexico and the East Coast of the United States. The Biota of Wetlands The most noticeable feature of all wetlands is the abundance of plant life. A variety of plant species thrive in wetlands, but each occurs only in a particular kind of habitat. Freshwater wetlands that are frequently flooded provide a favorable habitat for water-tolerant trees, such as bald cypress and water tupelo, and water-tolerant herbaceous plants, such as cattail, arrowhead, bulrush, spike rush, water lily, and duckweed. Less frequently flooded freshwater areas support trees such as willow, cottonwood, water oak, water hickory, and red maple. Seawater areas in tropical bays favor the development of mangroves, while temperate bays favor the development of cordgrass. Wetland plants provide a habitat for a variety of animals. Cypress swamps and cattail marshes support a large assortment of animals, including alligators, ducks, crayfish, turtles, fish, frogs, muskrat, wading birds, and snakes. Likewise, mangrove prop roots provide attachment sites for a variety of invertebrates and shelter for numerous small fish, while upper branches provide roosting and nesting sites for birds. In salt marshes, mussels live among cordgrass roots, while snails, fiddler crabs, oysters, and clapper rails live among plant stalks. When water covers cordgrass at high tide, plant stalks shelter small fish, crabs, and shrimp seeking refuge from large predators. The Value of Wetlands The amount of plant material produced in wetlands is higher than that produced in most aquatic and terrestrial habitats. This large amount of plant material supports an abundance of animal life, including commercially important species such as crayfish, ducks, fish, muskrat, shrimp, and crabs. The biotic value of wetlands is well recognized, but it represents only a part of their total value. Wetlands provide “services” for other areas that often go unrecognized. For example, freshwater wetlands are capable of 674
Wetlands storing large amounts of water during periods of heavy rainfall. This capability can be important in minimizing the impact of flooding downstream. Saltwater wetlands along coastlines are an effective barrier against storms and hurricanes. These natural barriers hold back the force of winds, waves, and storm surges while protecting inland areas. Wetlands are also capable of increasing water quality through the trapping of sediment, uptake of nutrients, and retention of heavy metals. Sediment trapping occurs when moving water is slowed enough by grass and trees to allow suspended sediment particles to settle. Wetland plants take up nutrients, such as nitrates and phosphates, from agricultural runoff and sewage. For this reason, wetlands are used as a final treatment step for domestic sewage from some small cities. Wetland soils are capable of binding heavy metals, effectively removing these toxic materials from the water. Wetlands Loss and Preservation It is estimated that the United States once contained more than 200 million acres of wetlands. Less than half this amount remains today. Once considered wastelands, wetlands were prime targets for “improvement.” Extensive areas of freshwater wetlands and prairie potholes have been drained and filled for agricultural development. Saltwater wetlands have been replaced by urban or residential development and covered with dredge spoil. Wetlands loss rates have slowed, but an estimated 300,000 acres continue to be lost each year in the United States. The loss of wetlands habitat threatens the survival of a number of animal species, including the whooping crane, American crocodile, Florida panther, manatee, Houston toad, snail kite, and wood stork. Since the 1970’s the rate of wetlands loss has slowed for several reasons. One is the passage of federal and state laws designed to protect wetlands; another is the efforts of conservation organizations. At the federal level, the single most effective tool for wetlands preservation is Section 404 of the Clean Water Act. Section 404 requires that a permit be issued before the release of dredge or fill material into U.S. waters, including wetlands. At the state level, Section 401 of the Clean Water Act allows states to restrict the release of dredge or fill material into wetlands. Subsequent legislation, notably the North American Wetlands Conservation Act of 1989, worked to conserve wetland habitat. The 1989 act was passed in part to support the North American Waterfowl Management Plan, an international agreement between Canada, Mexico, and the United States to protect wetland/upland habitats on which waterfowl and other migratory birds in North America depend. In December, 2002, President George W. Bush signed the North American Wetlands Conservation Reauthorization Act, intended to 675
Wetlands “keep our water clean and help provide habitat for hundreds of species of wildlife.” Several conservation organizations also support wetlands preservation, including Ducks Unlimited, the National Audubon Society, the National Wildlife Federation, and the Nature Conservancy. These organizations keep the public informed regarding wetlands issues and are active in wetlands acquisition. Steve K. Alexander, updated by Christina J. Moose See also: Biomes: determinants; Biomes: types; Chaparral; Deserts; Forests; Grasslands and prairies; Habitats and biomes; Lakes and limnology; Marine biomes; Mediterranean scrub; Mountain ecosystems; Old-growth forests; Rain forests; Rain forests and the atmosphere; Rangeland; Reefs; Savannas and deciduous tropical forests; Taiga; Tundra and high-altitude biomes. Sources for Further Study Hey, Donald L., and Nancy S. Philippi. A Case for Wetland Restoration. New York: Wiley, 1999. Littlehales, Bates, and William Niering. Wetlands of North America. Charlottesville, Va.: Thomasson-Grant, 1991. Mitchell, John. “Our Disappearing Wetlands.” National Geographic 182, no. 4 (1992). Mitsch, William J., and James G. Gosselink. Wetlands. 3d ed. New York: John Wiley, 2000. Monks, Vicki. “The Beauty of Wetlands.” National Wildlife 34, no. 4 (1996). Vileisis, Ann. Discovering the Unknown Landscape: A History of America’s Wetlands. Washington, D.C.: Island Press, 1999. Watzin, Mary, and James Gosselink. The Fragile Fringe: Coastal Wetlands of the Continental Unites States. Rockville, Md.: National Oceanic and Atmospheric Administration, 1992.
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WILDLIFE MANAGEMENT Type of ecology: Restoration and conservation ecology Wildlife management strives to allow the use of ecological communities for human benefit while preserving their ecological components unharmed. It also seeks to restore biological communities by managing habitats and controlling the taking of organisms for sport or economic gain.
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ildlife management, also known as game management, is often compared with farming or forestry, because one of its goals is to ensure annual “crops” of wild animals. Conservationist Aldo Leopold, in 1933, defined “game management” as the art of making land produce sustained annual crops of wild game for recreational use. At that time, animals considered to be game included deer and animals such as coyotes that do damage to domestic animals or crops. Now, however, the term “wildlife” has replaced game, and virtually all living organisms, including invertebrates and plants, are included in management considerations.
Approaches to Wildlife Management The process of wildlife management has moved through a sequence of six approaches: the restriction of harvest (by law); predator control; the establishment of refuges, reserves, and parks; the artificial stocking of native species and introduction of exotic ones; environmental controls, or management of habitat; and education of the general public. All six are used in modern wildlife management programs, but most emphasis is placed on habitat management and control of harvest. All fifty states of the United States have departments responsible for wildlife conservation. An appointed board of directors or commission oversees the actions of the departments. Groups for wildlife law enforcement, research, management, and information and education make recommendations to the board of directors regarding wildlife management actions. The federal government of the United States also has many agencies that manage wildlife on public lands. The U.S. Fish and Wildlife Service is involved with animals that cross state lines, including migratory birds such as waterfowl, marine mammals, and any plants and animals listed as rare or endangered under the National Environmental Protection Act of 1970. Other agencies, such as the U.S. Forest Service, Bureau of Land Management, Soil Conservation Service, and the U.S. National Park Service, do 677
Wildlife management extensive wildlife work. Many private organizations, such as the National Wildlife Federation, the Audubon Society, and the Sierra Club actively promote wildlife conservation. Wildlife management decisions involve the entire range of biological, sociological, political, and economic considerations of human society. Today, the wildlife resource in the United States is managed primarily either for consumptive use (such as sport hunting) or for nonconsumptive use (such as bird-watching). Virtually all wildlife management problems are related to the large human population of the earth. Some specific problems are habitat loss (for example, the destruction of tropical rain forests), pollution, diseases introduced by domestic animals into wildlife populations, and the illegal killing of animals for their parts, such as the poaching of elephants for their ivory. Managing Wildlife Communities A wildlife manager must first determine the physical and biological conditions of the organism or organisms being managed. Issues include what the best habitat for the animal is and how many animals this habitat can support. The stage of ecological succession determines the presence or absence of particular animals in an area. All animals need food, water, and protection from weather and predators. Special needs, such as a hollow tree in which to raise young, for example, must be fulfilled within the animal’s home range. Wildlife managers attempt to remove or provide items that are most limiting to a population of animals. In many respects, solving wildlife management problems is an art; it is similar to medicine in that it often must deal with symptoms (birds dying, for example) and imprecise information. The stage of ecological succession may be maintained by plowing lands, spraying unwanted plants with a chemical to kill them, or using fire, under controlled conditions, to burn an area to improve the habitat for a certain wildlife group. Refuges and preserves may be set aside to assure that some of the needed habitat is available; nest boxes and water supplies may even be provided. Periodic surveys of the number of animals in a population provide guidelines for their protection. If animals are more abundant than the lowest carrying capacity, a controlled harvest may be allowed. Sustained annual yield assures that no more than the population surplus is taken. Wildlife laws protect the animals, provide for public safety, often set ethical guides for sporting harvest, and attempt to provide all hunters with an equitable chance of obtaining certain animals (for example, by setting bag limits). If proper wildlife management procedures are followed, no animal 678
Wildlife management need become rare or endangered by sport hunting. Market hunting, the taking of animals for the sale of their products, such as meat or hides, has been stopped in the United States since the 1920’s and is also illegal in most other areas of the world. There are almost no societies left that are true subsistence hunters—that is, living exclusively on the materials produced by the wildlife resource. The Need for Wildlife Management The proper management of wildlife resources, based on sound ecological principles, is essential to the well-being of humans. All domestic plants and animals came from wild stock, and this genetic reservoir must be maintained. Maintaining the web of life that includes these organisms is necessary for human survival. Wildlife resources are used by at least 60 percent of the citizens of the United States each year, and about 6 percent are sport hunters. Wildlife provides considerable commercial value from products, such as meat; it also offers aesthetic values of immeasurable worth. Seeking and observing wildlife provides needed relief from the everyday tensions of human life. Moreover, by observing wildlife reactions to environmental quality, investigators can monitor the status of the biological system within which humans live. Wildlife populations serve as a crucial index of environmental quality. Perhaps most important of all, wildlife management helps preserve the biodiversity of communities and ecosystems. Without an effort toward including these ecological considerations along with economic resource concerns, habitat and species loss would quickly ensue, even more rapidly than it now does, in response to urban, suburban, industrial, and agricultural development. Wildlife management is a dynamic activity that, to be effective, must reflect an understanding of and respect for the natural world. It cannot be practiced in a vacuum but must encompass the realm of complex human interactions that often have conflicting goals and values. Aldo Leopold once defined conservation as man living in harmony with the land; successful wildlife management will help assure that this occurs. David L. Chesemore See also: Biodiversity; Conservation biology; Deforestation; Endangered animal species; Endangered plant species; Erosion and erosion control; Forest management; Genetic diversity; Grazing and overgrazing; Habitats and biomes; Landscape ecology; Multiple-use approach; Old-growth forests; Reforestation; Restoration ecology; Species loss; Sustainable development; Urban and suburban wildlife; Zoos. 679
Wildlife management Sources for Further Study Anderson, S. H. Managing Our Wildlife Resources. 3d ed. Upper Saddle River, N.J.: Prentice Hall, 1999. Bailey, James A. Principles of Wildlife Management. New York: John Wiley & Sons, 1984. Bissonette, John A., ed. Wildlife and Landscape Ecology: Effects of Pattern and Scale. New York: Springer, 1997. Cooperrider, Allen Y., R. J. Boyd, H. R. Stuart, and Shirley L. McCulloch. Inventory and Monitoring of Wildlife Habitat. Washington, D.C.: U.S. Government Printing Office, 1986. Dasmann, R. F. Wildlife Biology. New York: John Wiley & Sons, 1981. Di Silvestro, Roger, ed. Audubon Wildlife Report, 1986. New York: National Audubon Society, 1986. Giles, R. H., Jr. Wildlife Management. San Francisco: W. H. Freeman, 1978. Leopold, Aldo. Game Management. New York: Charles Scribner’s Sons, 1939. Reprint. Madison: University of Wisconsin Press, 1986. Matthiessen, Peter. Wildlife in America. New York: Viking Press, 1987. Robinson, W. L., and E. G. Bolen. Wildlife Ecology and Management. 4th ed. Upper Saddle River, N.J.: Prentice Hall, 1999.
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ZOOS Type of ecology: Restoration and conservation ecology Keeping wild animals has evolved, over the past five thousand years, from animal collections maintained by ancient societies to modern zoological gardens and aquariums with significant programs in wildlife appreciation, education, science, and conservation. Originally entertainment venues, zoos have shifted their focus to education and active conservation of endangered and threatened species.
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early 600 million people worldwide visit a zoo each year—roughly 10 percent of the global population. Modern zoos, often called wildlife conservation parks or natural wildlife parks, have replaced cages of concrete and steel with simulated natural environments, and new animals are obtained via selective breeding instead of being captured from the wild. History of Zoos Early zoos were the sole province of the wealthy; the first recorded zoo in history belonged to a Chinese emperor in 1100 b.c.e. It was not until the nineteenth century that zoos were open to the public. The word “zoo” derives from the phrase “zoological park,” and that was what the first zoos were designed to be: afternoon diversions along the same lines as the amusement park or the circus. Exotic beasts from newly charted regions were captured and displayed with little regard for their health or emotional well being. Mortality was high, and display animals were constantly replaced with animals captured from the wild, of which there seemed to be an inexhaustible supply. The first zoo to use moats to separate animals from visitors was established in Germany by Carl Hagenbeck in 1907. These moats provided visitors with an unobstructed view and, depending on their placement, made it seem as if the animals were free. While the bars were gone, the habitat was still nothing like what the animals were accustomed to in the wild. Those animals that did not spend their days sleeping often displayed nearpsychotic behavior patterns, such as pacing, head butting, and even selfmutilation. A New Role Two things changed the way zoos functioned during the twentieth cen681
Zoos tury. First, movies and television allowed potential visitors to see the animals in their natural habitats, and suddenly giraffes, lions, and zebras were no longer quite so exotic. Second, wild animals were becoming more scarce, and words such as “conservation” and “endangered” entered the collective vocabulary. Acquiring specimens from the wilderness became more costly, and zoos began to look at internal breeding programs to replenish their stock. However, they found that animals kept in unnatural and in some cases inhumane conditions would not breed. New zoo enclosures were designed to encourage natural behavior in animals by replicating their natural environment as much as possible while still ensuring the safety of both the animals and the zoo visitors. Animals began receiving healthier diets and, when possible, were allowed to feed in much the same way they would in the wild—by digging, foraging, or grazing. Human contact with orphaned and injured animals was kept to an absolute minimum, and some zoos took the additional step of not naming their animals to discourage anthropomorphism. By 1995, 80 percent of the mammals on display in zoos were born in captivity.
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Zoos Another trend that began in the late twentieth century was the building of “wild animal parks.” The San Diego Zoo, for example, established one of the earliest wild animal parks northeast of San Diego near Escondido, California, which turns the tables by restricting human visitors behind fences and within tram cars as the animals roam freely over large land tracts that approximate their natural habitats. Mission: Preservation As concern over endangered animal species, coupled with ecologists’ alarm over a decline in biodiversity, spread at the end of the twentieth century, zoos increasingly took on the mission of preservation and breeding. The American Zoo and Aquarium Association (AZA), a nonprofit organization dedicated to the advancement of zoos and aquariums in the areas of conservation, education, science, and recreation, states its members’ mission as “work[ing] cooperatively to save and protect the wonders of the living natural world.” The AZA has accredited more than two hundred zoos worldwide and sponsors a variety of research, education, and preservation programs. One of these, the Species Survival Plan (SSP) program, was established in 1981 to “help ensure the survival of selected wildlife species into the future and to provide a link between zoo and aquarium animals and the conservation of their wild counterparts” through breeding and, where possible, reintroduction into the wild. Zoo managers continue to struggle to balance science, conservation biology, scarce resource allocation, and ethics. Among the choices that must be made are whether predators should be offered the chance to exercise natural hunting behaviors by being offered live prey, or whether zoos should maintain potentially deadly animals that are necessary for breeding programs but are dangerous and difficult to control, such as macaques, many of which harbor the deadly hepatitis B virus, or adult male elephants. Another dilemma is the question of what should become of “surplus” animals that are inbred, unable to reproduce, or are otherwise genetically inferior. Municipal bureaucracies can also hamper zoo conservation efforts. Zoo managers must often combat local governments and public opinion when dealing with unpopular issues, such as surplus animals and resource allocation. In addition, budget cuts have forced zoo managers to turn to the private sector for financial assistance. Fund-raising activities range from the traditional “adopt an animal” programs to the extraordinary commercial venture of selling “exotic compost.” There are those who question whether zoos should exist at all— 683
Zoos whether it is cruel or unusual to take animals from their natural habitat and place them on display. The People’s Republic of China, for example, has “rented” its zoo’s giant pandas when the pandas might be better served by remaining in the wild or in a captive-breeding program that would allow them to replenish their numbers. Critics claim that the money devoted to zoos and captive-breeding programs would be better spent on preserving the animals’ natural habitats. To combat these types of criticism, some zoos began to change their focus from “collecting” wildlife to “protecting” wildlife, also known as field conservation. In these new exhibits, zoo visitors view exhibits linked with protection and conservation programs in natural habitats, allowing visitors to connect what they are seeing in captivity to what’s worth saving in the wilderness. Some zoos have taken the additional step of “adopting” wildlife refuges. Despite the criticism, the fact remains that there are many animal species that could not survive without the existence of zoos and captivebreeding programs. Ironically, where historical zoos replenished their stock from the wilderness, some zoos are now replenishing the wilderness with captive-bred animals. P. S. Ramsey, updated by Christina J. Moose See also: Biodiversity; Conservation biology; Deforestation; Endangered animal species; Genetic diversity; Restoration ecology; Species loss; Sustainable development; Urban and suburban wildlife; Wildlife management. Sources for Further Study Bell, Catharine, et al., eds. Encyclopedia of the World’s Zoos. Chicago: Fitzroy Dearborn, 2001. Croke, Vicki. The Modern Ark: The Story of Zoos, Past, Present, and Future. New York: Charles Scribner’s Sons, 1997. Hoage, R. J., and William A. Deiss, eds. New Worlds, New Animals: From Menagerie to Zoological Park in the Nineteenth Century. Baltimore: The Johns Hopkins University Press, 1996. Kisling, Vernon N., Jr., ed. Zoo and Aquarium History: Ancient Animal Collections to Zoological Gardens. Boca Raton, Fla.: CRC Press, 2001. Koebner, Linda. Zoo Book: The Evolution of Wildlife Conservation Centers. Preface by William Conway. New York: T. Doherty, 1994. Norton, Bryan G., Michael Hutchins, Elizabeth F. Stevens, and Terry L. Maple, eds. Ethics on the Ark: Zoos, Animal Welfare, and Wildlife Conservation. Washington, D.C.: Smithsonian Institution Press, 1995. 684
Zoos Tudge, Colin. Last Animals at the Zoo: How Mass Extinction Can Be Stopped. Washington, D.C.: Island Press, 1992. Wemmer, Christen M., ed. The Ark Evolving: Zoos and Aquariums in Transition. Front Royal, Va.: Smithsonian Institution Conservation and Research Center, 1995.
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GLOSSARY abiotic: Not living; used to refer to the nonliving elements of an ecosystem or biome, consisting of climate, the minerals in soil, rocks, water, oxygen, carbon dioxide, and other physical components. abundance: The density and prevalence of organisms living in a particular population, community, or ecosystem. abyssal marine zone: The dark marine zone that extends from the ocean floor to where the continental slope begins. acclimatization: A process by which animals habituate their physiological responses to the conditions of a particular environment. acid deposition: The process whereby acidic (very low pH, usually under 5.6) gases, particles, and precipitation (rain, fog, dew, snow, or sleet) fall on the surface of the earth. active or wide foraging: Moving across a relatively large area in search of prey. adaptation: In evolutionary biology, a heritable structure, physiological process, or behavioral pattern that gives an organism a better chance of surviving and reproducing; in physiology, the change in the response of a sense organ following continuous application of a constant stimulus. adaptive radiation: The relatively rapid evolution of several new species from a common ancestor following invasion of a new geographic region or ecological niche, or exploitation of a new ecological opportunity. aerobic: Characterizing any biological process that occurs in the presence of free oxygen. aestivation: See estivation. aggregation: A group of organisms that live in closer proximity than they would were they to be randomly or evenly distributed. Aggregations of the same species are known as populations. aggression: A physical act or threat of action by one individual that reduces the freedom or genetic fitness of another. agricultural ecology: Also called agroecology, the study of agricultural ecosystems, their components (such as crop species), functions, interactions, and impact on natural ecosystems and abiotic factors such as atmospheric and water systems—often with an emphasis on the development of sustainable systems. agricultural revolution: The transition by humans from hunting and gathering all their food to domesticating plants for food. alleles: Different forms of a particular gene, located at the same position on 687
Glossary a chromosome. Most genes have at least two naturally occurring alleles. These alleles may be the same or may be different. allelochemical: A general term for a chemical used as a messenger between members of different species; allomones and kairomones are allelochemicals, but hormones and pheromones are not. allelopathy: The phenomenon in which an organism produces and releases chemicals that are toxic to, or inhibit the growth of, another organism, although sometimes with beneficial effects to the other organism. allopatric speciation: The evolution of two new species as a result of the separation of two groups of the same species from each other. allopolyploidy: Formation of a new species resulting from the mating of two different species, resulting in a sterile or reproductively isolated hybrid. alpine tundra: The area of Europe, Asia, and North America north of the boreal coniferous forest zone, where the soils remain frozen most of the year, constituting about 3 percent of the earth’s surface. altruism: A behavior that increases the fitness of the recipient individual while decreasing the fitness of the performing individual. amensalism: An interspecies relationship in which one species is harmed while the other remains uneffected. anaerobic: Lacking, or living in the absence of, oxygen. antagonism: Any type of interactive, interdependent relationship between two or more organisms that is destructive to one of the participants. antithesis, principle of: The observation that signals communicating opposite meaning tend to be expressed using displays having opposite characteristics. aposematic coloration: Bright warning coloration that toxic species use to advertise their distastefulness to would-be predators. aquatic ecology: The study of the ecology of freshwater systems (rivers, lakes), estuaries, and marine environments (both coastal and open ocean), including the physical, chemical, and biological processes associated with them. Arctic tundra: Treeless biome of very cold climates near to and north of the Arctic Circle, in which the predominant plants are low-growing, perennial woody plants and grasses. Lichens and mosses may also be common. area-sensitive species: Species that require large blocks of natural area for activities such as reproduction, finding food, and raising of young, are called area-sensitive species. This required area may include portions of open habitat, edge, and interior habitat. Area-sensitive species are especially sensitive to any reduction in area caused by habitat fragmentation. 688
Glossary artificial selection: Choices made by plant breeders to produce varieties of plants that have some desirable quality, such as improved yield, greater height, or an unusual flower color. asexual reproduction: Reproduction of cells or organisms without the transfer or reassortment of genetic material, resulting in offspring that are genetically identical to the parent. autoecology: See physiological ecology. autopolyploidy: Formation of a new species by the doubling of chromosomes of a single existing species. Many related species of plants within a genus have been found to result from repeated occurrences of autopolyploidy. autotrophs: Organisms that have the ability to make their own food from inorganic substances. See also photosynthesis; primary producers. back-cross: A cross involving an offspring individual crossed with one of its parents. banding: Technique for studying the movement, survival, and behavior of birds by means of identification tags. Batesian mimicry: An evolutionary trend in which an edible species mimics the form of a distasteful species to avoid predation. behavioral ecology: The systematic study of the strategies animals use to overcome environmental problems and the adaptive value of those strategies. benthos: The area of the ocean floor; organisms associated with the sea bottom. bioaccumulation: See biomagnification. bioclimatic zone: A zone of transition between differing yet adjacent ecological systems. biodegradable: Capable of being broken down, or degraded, into simpler substances by natural decomposers. biodiversity: This term represents an amalgamation of biology and diversity. Ecologists typically recognize three types of biodiversity—species biodiversity, genetic biodiversity, and habitat biodiversity. Habitat biodiversity refers to the variety of habitats in a given landscape, genetic biodiversity refers to the number of alleles in a species genome or gene pool in a given area. Species diversity refers to both the variety of species and equal numbers of individuals among each species. biogenetic law: Ernst Haeckel’s term for his generalization that the ontogeny of an organism recapitulates the adult stages of its ancestors (recapitulation). biogeochemical cycles: Movement of elements or water through both liv689
Glossary ing and nonliving parts of an ecosystem. Carbon as carbon dioxide is made into carbohydrate during photosynthesis and released through decay to the nonliving atmosphere, from which it can later be reused in photosynthesis. biogeography: The science that seeks to understand spatial patterns of biodiversity. See also island biogeography. bioluminescence: Production of visible light by living organisms. biomagnification: Also called bioaccumulation, the increasing accumulation of a toxic substance in progressively higher feeding levels biomass: The weight of organic matter in an environment or ecosystem, often expressed in terms of grams per square meter per year. biomes: The primary, large-scale ecosystems of the world, largely identified with geographical regions typified by climate and weather and classified in the Köppen system on the basis of precipitation, temperature, climate, soil types, flora, fauna, and location. Major biomes include Tropical (rain forests, savannahs, tropical deciduous forests, and tropic scrub), Mid-Latitude to Equatorial (temperate, hot, and cold grasslands, including steppe and chapparal; hot and cold deserts), Continental (woodlands, deciduous temperate forests, mediterranean woodland and shrub), Moderate Continental (moderate grasslands, deciduous forests, taiga and boreal forests), and Polar (ice caps, tundra). biopesticides: Biological agents, such as viruses, bacteria, fungi, mites, and other organisms used to control insect and weed pests in an environmentally and ecologically friendly manner. biosphere: Specifically, the 20-kilometer-thick zone extending from the floor of the oceans to the top of mountains, within which all life on earth exists. Generally, the sum of all the occupiable habitats for life on earth. biota: All living things in a particular area, including microbes, fungi, algae, plant life, and animals. biotechnology: Combination of techniques whereby humans are able to alter permanently the genetic makeup of organisms. Includes the industrial application of these techniques. biotic: Living. Refers to the living components of an ecosystem or biome, consisting of all organisms. boreal forest: Located in two broad belts of vegetation that stretch from east to west in the Northern Hemisphere, the primarily coniferous forests that dominate this biome, which is also known as taiga. bottleneck effect: In evolution, the reduction in size of a population causing a major loss of genetic variation. If the population size later expands, the new larger population will be genetically uniform and may lack the ability to survive in a changing climate. 690
Glossary brood: All the immature insects within an insect colony, including eggs, larvae, and, in the Hymenoptera, the pupal stage; also, to cover young with the wings. brood parasite: See nest parasite. browser: An animal that feeds on leaves and twigs from trees. budding: A form of asexual reproduction that begins as an outpocketing of the parental body, resulting in either separation from or continued connection with the parent, forming a colony. C3 plants: Plants whose system of photosynthesis produces a three-carbon compound as the first identified compound after the uptake of carbon dioxide during the light-independent reactions. See also CAM plants. C4 plants: Plants whose system of photosynthesis produces a four-carbon compound as the first identified compound after the uptake of carbon dioxide during the light-independent reactions. C4 photosynthesis is distinguished from CAM photosynthesis because C4 occurs during the day and CAM occurs during the night. C4 plants are especially adapted to hot, dry climates. Corn is an example. See also CAM plants. calorie: The traditional unit of heat; one calorie is the amount of heat required to raise the temperature of one gram of water 1 degree Celsius. CAM plants: Plants in desert biomes that use a crassulacean acid metabolism to take in carbon dioxide during the night and store it as an acid, and then use the carbon dioxide in the light-independent reactions during the day, when sunlight is available. Cacti are CAM plants. See also C3 plants; C4 plants. Cambrian explosion: The main period of evolutionary expansion in the Phanerozoic era at the base of the Cambrian period, 544 million years ago, which marks the development of all the modern phyla of organisms. camouflage: Patterns, colors, and/or shapes that make it difficult to differentiate an organism from its surroundings. canopy: The uppermost portion of a rain forest, which shades the understory and the forest floor. capture-recapture: See mark-capture-release method. carbohydrates: Large class of organic molecules containing starch, carbon, hydrogen, and oxygen and in which the ratio of hydrogen to oxygen is two to one, the same as in a molecule of water. Sugars and cellulose are examples. carbon cycle: Biogeochemical cycle of the element carbon. carbon fixation (CO2 ): Process by which carbon dioxide is made into glucose during photosynthesis. This occurs during the part of photosynthesis called the Calvin cycle. 691
Glossary carcinogen: Any physical or chemical cancer-causing agent. carnivore: A member of the meat-eating order Carnivora, which includes dogs, cats, weasels, bears, and their relatives. carnivorous plant: Plant that traps insects and digests them. These plants usually live in nitrogen-poor habitats and use the insect proteins to supplement their nitrogen intake. carnivory: Subsisting or feeding on meat or flesh. carrion: Dead animal flesh. carrying capacity: The maximum number of animals that a given area can support indefinitely. caste: One of the recognizable types of individuals within an insect colony, such as queens, workers, soldiers, and males or drones; usually these individuals are physically and behaviorally adapted to perform specific tasks. catastrophism: A scientific theory which postulates that the geological features of the earth and life thereon have been drastically affected by natural disasters of huge proportions in past ages. cellulose: A fibrous polysaccharide that chiefly constitutes the cell walls of plants and is not easily dissolved in water. Primary consumers, including ruminants, require specialized digestive systems to break down cellulose. census: The counting of populations of naturally occurring organisms to understand their ecology more fully. CFCs: See Chlorofluorocarbons (CFCs). chaparral: Biome found along the coast of Southern California, characterized by short trees with leathery leaves, shrubs, and open grassy areas. character displacement: A change in the morphological, behavioral, or physiological state of a species without geographical isolation, as a result of natural selection arising from competition between one or more ecologically similar species. chemical ecology: Ecology that concerns the biochemicals (called semiochemicals) produced and released by organisms that have physiological and behavioral effects on other organisms. Studies in chemical ecology are often interdisciplinary (integrating several fields of science such as chemistry and ecology) but also more specific areas in biochemistry (such as biosynthesis of compounds), molecular biology, or physiology (reception of the compounds and transmission of nerve impulses), as well as in behavioral ecology (orientation movements of an organism) and population ecology (aggregation and competition of organisms) and even the interactions among trophic levels (such as predator-prey 692
Glossary interactions). Evolutionary studies at all these levels are of interest to understand how stable the semiochemical systems are and whether adaptations to new systems are constrained. chemical pollutants: Harmful chemicals manufactured and released to the environment. chemosynthetic autotrophs: Organisms (usually bacteria) that make complex food molecules from simpler molecules using energy of chemical reactions rather than light energy used by photosynthetic autotrophs. chlorofluorocarbons (CFCs): A group of very stable compounds used widely since their development in 1928 for refrigeration, coolants, aerosol spray propellants, and other uses; once risen in stratosphere, they cause ozone depletion. circadian rhythm: A physiological or behavioral cycle that occurs roughly in a twenty-four-hour pattern. cladistics: System of describing evolutionary relationships in which only two groups, or clades, branch from each ancestral group. The more recently two clades diverged, the more characteristics they have in common and the closer they will appear in a cladistic diagram. class: The taxonomic category composed of related genera; closely related classes form a phylum or division. classification: The arranging of organisms into related groups based on specific relationships. See also systematics; taxonomy. clear-cutting: The removal of all trees from an area. climax community: Group of plants that appear late in succession and are not replaced by plants of different species unless the climate changes or the area is disturbed, as by fire or cultivation. cline: A graduated series of populations of the same species. Each population has a slightly different physiology from the ones on each side. Clines typically develop where environmental factors change in a gradual way, such as from the bottom of a mountain to the top. clone: An organism that is genetically identical to the original organism from which it was derived. cloning: The technique of making a perfect genetic copy of a DNA molecule, a cell, or an entire organism. clutch: A group of eggs laid in a single reproductive effort. coevolution: Simultaneous evolutionary change through time of two species, such as a flower and its pollinating insect, each influenced by the changes the other species is undergoing. Over a period of time, the two species often become dependent on each other, so that one would not survive the disappearance of the other. 693
Glossary cognitive ethology: The study of animal intelligence. cohort: A group of organisms of the same species, and usually of the same population, that are born at about the same time. colony: A cluster of genetically identical individuals formed asexually from a single individual. coloration: See aposematic coloration; cryptic coloration. commensalism: A type of coevolved symbiotic relationship between different species that live intimately with one another without injury to any participant. communication: The exchange of information between members of a species by means of chemical signals (pheromones), displays, calls, and other means. community: A population of plants and animals that live together and interact with one another through the processes of competition, predation, parasitism, and mutualism, making up the biotic part of an ecosystem. community ecology: The study of the impacts that populations of different species have on populations of other species with which they interact, be those interactions between plants and other plants, animals and other animals, or plants and animals. The emphasis is on how these populations of different species change, enhance, or delimit one another. Population ecology is related but is focused on the growth and change in populations of discrete species. comparative physiology: See physiological ecology. compartmentalization: A characteristic of most communities, in which a given set of producers tends to be consumed by a limited number of consumers, which in turn are preyed upon by a smaller number of predators, and so on. competition: The interactions among individuals that attempt to utilize the same limited resource. competitive exclusion, principle of (Gause’s principle): If two or more species compete for the same niche, one of them will be successful, and the other will be eliminated over time. coniferous forest: Large group of trees that are predominantly conifers, such as a pine forest or a spruce-fir forest. conjugation: Type of sexual reproduction that occurs in green algae such as Spirogyra and in certain kinds of fungi. Also, the transfer of genetic material from one bacterium to another through a cytoplasmic bridge. connectivity: The ability of organisms to use corridors of habitat to disperse from one habitat patch to another. 694
Glossary conservation biology: The use of biological science to design and implement methods to ensure the survival of species, ecosystems, and ecological processes. Conservation biologists are concerned with the process of speciation, the measurement of biodiversity, and factors involved in the extinction process. However, the primary thrust of their efforts is the development of strategies to preserve biodiversity; hence, conservation biology is a value-laden science. conservation easement: An arrangement in which a national government, private organization, or consortium of countries compensates a tropical country for protecting a specific habitat. See also debt-for-nature swap. consort pair: A temporarily bonded pair within a polygamous group; also called consortship. conspecific: A member of the same species. constriction: A method of killing prey using increasingly tight coils around the body to trigger stress-induced cardiac arrest. consumer: An organism other than a primary producer—that is, one that eats other organisms, including primary consumers (herbivores), secondary consumers (omnivores and carnivores), scavengers, and decomposers. continuous growth: Growth in a population in which reproduction takes place at any time during the year rather than during specific time intervals. convergent evolution: The process by which evolutionarily unrelated animals tend to resemble one another as a result of adaptations to similar environments. cooperation: A social behavior in which members of a group act for the good of all. coral reef: A reef built primarily by coral species. core species: A species that utilizes the interior area or core of a habitat. Core species such as many neotropical migrants typically require large blocks of contiguous natural habitat for reproduction and are typically very sensitive to the ratio of core-to-edge habitat in a given patch or parcel of landscape. corridor: Narrow link of habitat that connects two or more patches in a landscape. Natural corridors serve as wildlife dispersal conduits, permitting movement between natural habitats with minimal risk of exposure. countershading: A form of crypsis involving dark coloration on top and light coloration on the underside. coupled oscillations: In predator-prey relationships, the waxing and wan695
Glossary ing of population sizes of two species in a community, based on cycles of predation. crassulacean acid metabolism (CAM): See CAM plants. crepuscular: Active after sunset and in early morning. Cretaceous-Tertiary (KT) event: An event that occurred about 66.4 million years ago, sometimes hypothesized to be a meteoritic impact, that marks the boundary between the Cretaceous and Tertiary periods and that initiated the mass extinctions of many species, notably the dinosaurs. critical period: A very brief period of time in the development of an animal during which certain experiences must be undergone; the effects of such experiences are permanent. critical photoperiod: Specific day length necessary to produce flowers in long-day and short-day plants. cross-pollination: The transfer of pollen grains and their enclosed sperm cells from the male portion of a flower to a female portion of another flower within the same species. crown: The branched, leafy part of a tree. crypsis: The phenomenon of hiding or remaining hidden. cryptic coloration: Any color pattern that blends into the background. cuckold: A partnered male who is helping his mate to raise offspring which are not genetically his own. cud: Food regurgitated and chewed a second time after its initial ingestion. cultural diversity: Variety of learned behaviors among individuals of a species. cyanobacteria: Photosynthetic prokaryotes that were once called bluegreen algae. debt-for-nature swap: An arrangement in which tropical countries act as custodians of the tropical forest in exchange for foreign aid or relief from debt. See also conservation easement. deciduous tropical forest: Forests of tropical regions that shed their leaves during annual dry periods. decomposers: Bacteria and fungi that break down dead organic matter. In the process, they obtain energy and facilitate the recycling of elements. deep ecology: A philosophy, introduced by the Norwegian philosopher Arne Naess, that values the natural world and biodiversity in and of themselves and advocates seeing nature as more than a resource for human use. defense mechanism: Any of a variety of chemical, behavioral, anatomical, or physiological means by which an organism prevents or discourages predation. 696
Glossary definitive host: The host in which a symbiont (the organism living within the host) matures and reproduces. defoliant: A chemical that kills the leaves of trees. deforestation: The removal of trees from forests to an extent that degrades the forest biome without human intervention. See also reforestation. deme: A local population of closely related living organisms. demography: The study of the numbers of organisms born in a population within a certain time period, the rate at which they survive to various ages, and the number of offspring that they produce. Also referred to as demographics. dendrochronology: The examination and comparison of growth rings in both living and aged woods to draw inferences about past ecosystems and environmental conditions. dendroclimatology: The study of tree-ring growth as an indicator of past climates. denitrification: Process in which bacteria convert nitrogenous compounds in the soil to nitrogen gas. denning: The period of winter sleep during which a bear does not eat, drink, urinate, or defecate. density: The number of animals present per unit of area being sampled; for example, ten mice per hectare or five moose per square kilometer. density-dependent growth: Growth in a population in which the per capita rates of birth and death are scaled by the total number of individuals in the population. density-dependent population regulation: The regulation of population size by factors or interactions intrinsic to the population; the strength of regulation increases as population size increases. deoxyribonucleic acid (DNA): The genetic material of cells, having the molecular form of a twisted double helix that is linked by purine and pyrimidine base pairs; carries the inherited traits and controls for cell activities. desert: Biome that receives less than 10 inches of precipitation per year. desertification: The degradation of arid, semiarid, and dry, subhumid lands as a result of human activities or climatic variations, such as a prolonged drought. despotism: A type of hierarchy in which one individual rules over all other members of the group and no rank distinctions are made among the subordinates. detritus feeders (detritivores): An array of small and often unnoticed animals and protists that live off the refuse of other living beings, such as molted shells and skeletons, fallen leaves, wastes, and dead bodies. 697
Glossary diapause: A resting phase in which metabolic activity is low and adverse conditions can be tolerated; also, an interruption in embryonic development. diatom: Microscopic algae that produce a frustule (a kind of shell) made of silica glass that is highly resistant to weathering. A major type of phytoplankton. differentiation: The process during development by which cells obtain their unique structure and function. digestion: The process by which larger organic nutrients are broken down to smaller molecules in the lumen of the gut. dilution effects: The reduction in per capita probability of death from a predator due to the presence of other group members. dimorphism: Existence of two distinct forms within a species. dinoflagellates: A unicellular, mobile type of phytoplankton responsible for deadly algal blooms called red tides. dioecious: Having two separate sexes, namely male and female. diploid: Having two sets of chromosomes, usually one derived from the father and one derived from the mother; the normal condition of all cells except reproductive ones. See also haploid. discrete growth: Growth in a population that undergoes reproduction at specific time intervals. discrete signals: Signals that are always given in the same way and indicate only the presence or absence of a particular condition or state. disease ecology: Ecological factors influencing, and influenced by, the emergence and spread of infectious diseases, including both plant and animal populations. Considers such questions as how biodiversity affects the spread of disease, patterns of disease spread through populations, and the roles of evolution and genetics. disharmonic: Ecologically unbalanced. disjunct: Pertaining to the geographic distribution pattern in which two closely related groups are widely separated by areas that are devoid of either group. dispersal: The movement of organisms from one geographic area to another; movements may be the result of an animal’s own efforts (active dispersal) or the consequence of being transported by natural or human-mediated means (passive dispersal) and can be limited by physical barriers. dispersion: The pattern or arrangement of members of a population in a habitat; also, the transport or movement of seeds across a substrate such as soil prior to germination.
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Glossary disphotic marine zone: A transitional marine region between the photic and aphotic zones that may extend to depths of one thousand meters; also called the mesopelagic zone. display: A social signal, particularly a visual signal, exchanged between animals. disruptive coloration: Use of stripes, spots, or blotches to break up the body outline and blend into a complex background. diurnal: Awake and functional during the daylight hours. divergence: The evolution of increasing morphological differences between an ancestral species and offshoot species caused by differing adaptive pressures. diversity: The number of taxa (classification groups) associated with a particular place and time. See also biodiversity. DNA: See deoxyribonucleic acid. domestication: A process by which animals are adapted biologically and behaviorally to a domestic (human) environment in order to tame and manipulate them for the benefit of humans. dominance: The physical control of some members of a group by other members, initiated and sustained by hostile behavior of a direct, subtle, or indirect nature. dominance hierarchy: A social system, usually determined by aggressive interactions, in which individuals can be ranked in terms of their access to resources or mates. dominant species: A species in a community that acts to control the abundance of its competitors because of its large size, extended life span, or ability to acquire and hold resources. dormancy: A period of inactivity that allows a plant or animal to survive unfavorable cold or dryness (hypernation, estivation). drone: A fertile male social insect. drumming: Type of nonvocal communication that a bird produces by banging its bill on a hollow tree trunk or other noise-producing object. dry tropical biomes: The savanna and deciduous tropic forest biomes, which often occur where the annual rainfall is less than that of savannas, most often found in Africa, South America, and Australia. dynamic equilibrium: Characterizing a community in equilibrium that is always responding to the last disturbance. dynamically fragile: Characterizing a community that exhibits resilience only within a narrow range of conditions. dynamically robust: Characterizing a communitiy that exhibits resilience over a wide range of conditions and scales of disturbance.
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Glossary eclipse plumage: The drab plumage of male birds following the postbreeding molt, in which their bright courtship feathers are replaced by dull earthy feathers that provide inconspicuous coloring. ecocentrism: A philosophy that emphasizes the value of nature as a whole and an identification of the self with the natural world. ecoenergetics: The flow of energy through ecological systems at all levels, from individual organisms, populations, and communities to ecosystems and the global environment. Includes abiotic factors (such as geochemical cycles) as well as biotic factors. ecofeminism: A consideration of gender differences in the experience of the self and nature, which includes an analysis of the tie between the oppression of women and nature. ecological niche: See niche. ecology: The study of the interactions between organisms and the living (biotic) and nonliving (abiotic) components of their environment, including the distribution and abundance of organisms. ecomorph: Species of different phyletic origins (at most distantly related) with similar structural and behavioral adaptations to similar niches. ecophysiology: See physiological ecology. ecosystem: A biological community and the physical environment contained in it. ecosystem diversity: Variety of biomes and habitats occuring in the biosphere. ecosystem ecology: The study of the flow of energy into, through, and out of large-scale systems, and how that flow influences all abiotic factors and living organisms in the ecosystem. ecotone: The meeting place between the two biomes, a transition zone. ecotourism: Tourism based on the promotion of ecologically important sites, such as national parks, wildlife refuges, endangered ecosystems, and the organisms for which they form the habitat. ecotoxicology: The study of natural and man-made pollutants and their toxic effects on organisms, populations, communities, and ecosystems, as well as the ways these pollutants impact ecological processes to change ecosystems and their components. ectoparasite: A parasitic organism that attaches to the host on the exterior of the body. edge species: Certain species of wildlife that exploit edge habitat, which is the transition habitat zone between two distinct habitats. elfin forest: A stunted forest growing at high elevations in warm, moist climates. emergent vegetation: Vegetation that grows tall enough to be visible at 700
Glossary the highest level of a rain forest or, in aquatic systems, above the water line. emigration: The movement of animals out of an area; one-way movement from a habitat type. encounter effects: The reduction in the probability of death from a predator due to a single group of N members being more difficult to locate than an equal number of solitary individuals. endangered species: A species of animal or plant, as designated by bodies such as the U.S. Fish and Wildlife Service, that is threatened with extinction. endemic: Belonging to or native to a particular place; often referring to species that have evolved in a given area and are found nowhere else in the world. endosymbiosis: A symbiotic relationship in which one member lives inside the other’s body. endocannibalism: A form of human cannibalism in which members of a related group eat their own dead. endoparasite: A parasitic organism that attaches to an interior portion of the host’s body. endophyte: An organism living within a plant, such as a fungus living in a root. endosymbiotic theory: Theory that chloroplasts and mitochondria developed from bacteria that moved into and became essential to the survival of early eukaryotic cells. endotherm: An animal that, by its own metabolism, maintains a constant body temperature (warm-blooded); birds and mammals are endotherms. energy: The ability to do work. Energy takes several forms, such as chemical energy in the bonds of a compound, light energy, and kinetic energy, the energy of movement. energy budget: The amount of resources available to an organism, which is accepted to be limited or finite. Energy acquired from food (animals) or sunlight (plants) must be partitioned among growth, maintenance, and reproduction. The greater the energy allocated to the care of offspring, for example, the fewer the offspring that can be produced. energy flow: The capture of radiant energy, its transformation into chemical energy by producers via photosynthesis, and its translocation through all biological systems via consumers and decomposers. All organisms are considered as potential sources of energy. See also food chain. energy pyramid: A graphical representation of the energy contained in 701
Glossary succeeding trophic levels, with maximum energy at the base (producers) and steadily diminishing amounts at higher levels. entrainment: The synchronization of one biological rhythm to another rhythm, such as the twenty-four-hour rhythm of a light-dark cycle. entropy: The tendency of complex molecules and other structures to lose energy and become degraded into simpler forms. environment: All the external conditions that affect an organism or other specified system during its lifetime. environmental constraints: The physical demands placed upon any species by its surroundings that ultimately determine the success or failure of its adaptations and consequently its success as a species; also called pressures. epifauna: Animals that live on the sea floor. epiphyte: A plant that lives nonparasitically on another plant. Usually, epiphytes are not rooted in the ground and are typically found in habitats with high humidity. Spanish moss is an epiphyte. epizoites: Commensals that live on the skin, fur, scales, or feathers of their hosts. estivation: Similar to hibernation, a period of reduced activity or dormancy triggered by dry or hot environmental conditions. See also hibernation. estuarine ecosystem: An aquatic ecosystem that occurs where a freshwater river meets a saltwater or ocean environment. ethology: The study of an animal’s behavior in its natural habitat. euphotic zone: Also called the photic zone, the region of a body of water that is penetrated by sunlight. eusocial: Characterizing a social system with a single breeding female; other members of the colony are organized into specialized classes (exemplified by bees, ants, and termites). eutrophication: The overenrichment of water by nutrients, causing excessive plant growth and stagnation, which in turn leads to the death of fish and other aquatic life. evapotranspiration: The loss of water by means of both evaporation from soil and transpiration from plants. evergreen: Plant that keeps its leaves during adverse climatic conditions, such as cold temperatures. Examples are pine trees and rhododendrons. evolution: A process, guided by natural selection, that changes a population’s genetic composition and results in adaptations. evolutionarily stable strategy: A behavioral strategy that will persist in a population because alternative strategies, in the context of that population, will be less successful. 702
Glossary evolutionary ecology: The study of how evolutionary processes such as selection and adaptation influence the interactions of organisms with their environments and shape species and ecosystems. exogenous: Originating outside an ecosystem, community, population or organism. exotic species: Organisms that are not naturally found in a place but have been artificially introduced, whether by accident or intentionally. See also invasive species. exponential growth: A pattern of population growth in which the rate of increase becomes progressively larger over time. extant: Alive and reproducing, as opposed to extinct species. external fertilization: The union of eggs and sperm in the environment, rather than in the female’s body. extinct: No longer living on earth. F1 generation: First filial generation; offspring produced from a mating of P generation individuals. F2 generation: Second filial generation; offspring produced from a mating of F1 generation individuals. facultative anaerobe: Organism that can survive in an oxygen-poor environment when necessary, using the small amount of energy available from fermentation. fecundity: The number of offspring produced by an individual. female: An organism that produces eggs, the larger of two different types of gametes. fermentation: Set of reactions that change glucose into alcohol and carbon dioxide. A small amount of energy is produced, some of which is captured as ATP. fertilization (agriculture): Addition of minerals or decayed organic matter to soil that has been depleted of nutrients by farming or other means. fertilization (sexual reproduction): The fusion of sperm and egg to form a fertilized egg (zygote). field capacity: Water remaining in soil following rain or irrigation after excess water has been drained off by gravity. fire climax ecosystem: An ecosystem that depends on periodic fires to clear underbrush; the seeds of many plants in such an ecosystem require fire in order to germinate. fire ecology: The study of how both natural and planned fires impact ecosystems such as forests. fitness: The ability of an organism to produce offspring that, in turn, can 703
Glossary reproduce successfully; the fitness of organisms increases as a result of natural selection. fixation: Process by which a gas has been converted to another type of molecule, usually organic. fledgling period: Period after hatching, during which a nestling grows flight feathers and learns to fly. food chain: A paradigm representing the links between organisms, each of which eats and is eaten by another. food pyramid: A diagram representing organisms of a particular type that can be supported at each trophic level from a given input of solar energy in food chains and food webs. food web: A network of interconnecting food chains representing the food relationships in a community. foraging: See active or wide foraging; sit-and-wait foraging. fossil: A remnant, impression, or trace of an animal or plant of a past geological age that has been preserved in the earth’s crust. fossil fuel: A fuel product originating from the partial or complete decomposition of carbon-based life-forms (plant and animal remains and fossils) exposed to heat and pressure in the earth’s crust over thousands and millions of years. Fossil fuels include crude oil, coal, natural gas, and gasoline. fossil record: The evolutionary information contained in the fossils found in the earth’s crust when compared with the geologic record. frequency-dependent predation: Predation on whichever species is most common in a community; a frequency-dependent predator will switch prey if necessary. frozen zoo: A frozen tissue bank, maintained at many zoos, that contains wild animal tissue and reproductive samples for use in future breeding programs. functional response: The rate at which an individual predator consumes prey, dependent upon the abundance of that prey in a habitat. fusion-fission community: A society whose members are of both sexes and all ages, which can form and dissolve subgroupings. gamete: A haploid reproductive cell, usually a sperm or egg. Gause’s principle: See competitive exclusion, principle of. gene: A portion of a DNA molecule containing the genetic information necessary to produce a molecule of messenger RNA (via the process of transcription) that can then be used to produce a protein (via the process of translation). gene flow: The movement of genes from one population to another through 704
Glossary migration and hybridization between individuals belonging to adjacent populations. gene frequency: The occurrence of a particular allele present in a population, expressed as a percentage of the total number of alleles present. gene (point) mutation: A change within the hereditary material of a single gene. These tiny mutations cannot be observed by inspecting pictures of chromosomes. gene pool: All the alleles of all the genes present in a population. There is no limit to the number of alleles in a gene pool; however, an individual may not possess more than two different alleles. generalized: Not specifically adapted to any given environment. genetic diversity: The total number and distribution of alleles and genotypes in a population; a population with a very high genetic diversity would have many alleles and genotypes, all evenly distributed or with approximately equal frequency. genetic drift: Change in gene frequencies in a population owing to chance. genetic modification: Alteration of a organism’s genetic material by manipulation in the laboratory. The addition of new genes or the removal of genes are examples. genome: The complete amount of DNA found in the nucleus of a normal cell, expressed as a particular number of chromosomes; for example, a human cell has a genome of forty-six chromosomes. genotype: The complete genetic makeup of an organism, regardless of whether these genes are expressed. See also phenotype. genotype frequency: The relative abundance of a genotype in a population; to calculate, count the number of individuals with a given genotype in the population and divide by the total number of individuals in the population. genus (pl. genera): A group of closely related species having many traits in common and descended from a common ancestor; for example, Felis is the genus of cats, and it includes the species Felis catus (the domestic cat) and Felis couguar (the cougar or mountain lion). geochemical cycles: See biogeochemical cycles. global ecology: The study of the impacts of such factors as global warming, pollution, and disease on organisms and ecosystems worldwide. Much of global ecology considers the ecological impacts of humandriven influences such as international travel, trade, the built environment, and the use of petrochemicals. global extinction: The loss of all members of a species; that is, extinction whereby all populations of a species disappear or are eliminated. See also local extinction. 705
Glossary global warming: The theory that the atmosphere is becoming warmer over time as a result of an increase in greenhouse gases, resulting in climate change, melting ice caps, rising sea levels, severe weather events, and their impacts on the world’s living organisms. glycosides: Compounds produced by plants that combine a sugar, usually glucose, with an active component. Potentially poisonous glycosides include the cyanogenic, cardioactive, anthraquinone, coumarin, and saponin glycosides. gradient analysis: A method for studying the distribution of species along an environmental gradient. gradualism: A model of evolution in which transformation from ancestor to descendant species is a slow, gradual process spanning millions of years. grassland: A biome in which the dominant plants are grasses. grazer: An organism that feeds primarily on grasses. Green Revolution: Several decades of dramatic advances in yield and quality of crop species. This was the outcome of attempts to increase food production begun in the 1940’s. greenhouse effect: The process whereby the infrared radiation from the earth is absorbed by the atmosphere, keeping it from escaping into space. Because it was once believed that the glass panes of greenhouses acted similarly, this phenomenon was termed the “greenhouse” effect, although it has subsequently been shown that greenhouses work differently (by trapping heated air and not allowing it to blow away). greenhouse gases: gases, including carbon dioxide, water vapor, and methane, store heat more efficiently than others and contribute to the magnification of the so-called greenhouse effect. gregarious: Forming groups temporarily or permanently. gross primary productivity: The amount of the sun’s energy actually assimilated by autotrophs. See also net primary productivity; secondary productivity. habitat: The physical environment, usually that of soil and vegetation as well as space, in which an animal lives. habitat fragmentation: Conversion of a natural, contiguous landscape into smaller patches usually due to human activity. Grids of roads, gas lines, cluster housing, and power lines all contribute to habitat fragmentation. habitat selection: Process of choosing a home range, territory, nesting site, or feeding site on the basis of specific features of the habitat that an organism is best adapted to exploit. habituation: The process of learning to ignore irrelevant stimuli that previously produced a reaction. 706
Glossary haploid: Having one set of chromosomes and one of each kind of gene. Gametes (eggs or sperm) are usually haploid. See also diploid. Hardy-Weinberg law: A concept in population genetics stating that, given an infinitely large population that experiences random mating without mutation or any other such affecting factor, the frequency of particular alleles will reach a state of equilibrium, after which their frequency will not change from one generation to the next. hazardous waste: Any waste product that is toxic to living beings or threatens life. hemiparasite: A plant (such as mistletoe) with some chlorophyll which lives as a partial parasite. herbicide: Chemical that is lethal to plants. herbivore: An animal that eats living plants, usually specialized to digest cellulose. heritability: The extent to which variation in some trait among individuals in a population is a result of genetic differences. heterochrony: Any phenomenon in which there is a difference between the ancestral and descendant rate or timing of development. heteroecious: Describes fungi that spend parts of their life cycle on entirely different species of plants. Black stem rust of wheat spends part of its life cycle on wheat and part on American barberry. heterotrophs: Organisms that cannot make their own food from simpler materials but must ingest and digest complex molecules made by other organisms. Animals are heterotrophs, but so are nongreen plants such as Indian pipes. See also consumer. heterozygous: Having two different alleles at a particular gene locus. hibernation: A sustained period of torpor (lack of activity) triggered by cold environmental conditions, achieved when an animal reduces its metabolic rate. See also estivation. hierarchy: A social structure in which animals are dominated by those higher on the linear ladder. home range: Geographic area used by an individual, pair, or group for their daily, seasonal, and sometimes their yearly activities; the defended portion of the home range is called a territory. homeostasis: The dynamic balance between body functions, needs, and environmental factors which results in internal constancy. homologous: Referring to chromosomes that are identical in terms of types of genes present and the location of the centromere; because of their high degree of similarity, homologous chromosomes can synapse and recombine during prophase I of meiosis. homozygote: A diploid organism that has two identical alleles for a partic707
Glossary ular trait; a person with blood type A would be homozygous if he had two A alleles. horizons (soil): Layers of soil with different appearance and different chemical composition. In a forest, the horizon closest to the top will contain more organic matter than will the deeper layers. hormone: Chemical compound produced in small amounts in one part of an organism that has an effect in a different part of the same organism. Auxins, gibberellins, cytokinins, ethylene, estrogen, progesterone, oxytocin, and various pheromones are examples. host: In a parasitic relationship, the organism that is giving up energycontaining molecules to the parasite. hybrid: An organism resulting from the crossing of two species. hybrid vigor: The tendency of hybrids to be larger and more durable than their parent species; also called heterosis. hybrid zone: An area with a population of a species composed of individuals with characteristics of one or more species that have interbred. hybridization: A process of base-pairing involving two single-stranded nucleic acid molecules with complementary sequences; the extent to which two unrelated nucleic acid molecules will hybridize is often used as a way to determine the amount of similarity between the sequences of the two molecules; hybridization is fairly common among wind-pollinated plants, while hybridization is quite uncommon among higher animals. hydrologic cycle: Earth’s cycle of evaporation and condensation of water, which produces rain and maintains oceans, rivers, and lakes. hydrophilic: Loving water, capable of mixing with or growing in water. hydrosphere: The waters of the earth and the regions where they are found, including freshwater lakes and rivers, the oceans, inland seas, and then frozen water of the polar zones. immigration: The movement of organisms into an area; a one-way movement into a habitat type. imprinting: A specialized form of learning characterized by a sensitive period in which an association with an object is formed. inbreeding: Mating between relatives, an extreme form of positive assortative mating. See also outbreeding. inbreeding depression: Weakening, or lowering of the fitness, of offspring as a result of inbreeding, caused when alleles that decrease fitness drift to fixation. indicator species: Any species that is among the first to be degraded when an ecosystem is compromised, indicating the ecological impact of environmental change. 708
Glossary individual ecology: See behavioral ecology; physiological ecology. industrial melanism: The rapid rise in frequency of the melanic form in many moth species downwind of manufacturing sites, associated with the advent of industrial pollution. infauna: Animals that live in the sea floor. inflorescence: The group of flowers that forms at the top of a flower stalk. Inflorescences may be compact, like that of a daisy, or loose, like that of a mustard. innate: Inborn, possessed from birth, or determined and controlled largely by the genes. insectivore: Any of an order of small, nocturnal mammals, including shrews, moles, and hedgehogs, Insectivora, or generally any animal that feeds on insects. insectivorous plant: Plant that traps insects and digests them for the nitrogen-containing compounds they possess. Plants of this type grow in boggy soil that is typically low in nitrogen. instinct: Any behavior that is completely functional the first time it is performed. integrated pest management (IPM): The practice of integrating insect, animal, or plant management tactics, such as chemical control, cultural control, biological control, and plant resistance, to maintain pest populations below damaging levels in the most economical and environmentally responsible manner. interbreeding: The mating of closely related individuals which tends to increase the appearance of recessive genes. interference: The act of impeding others from using some limited resource. interfertile: Able to breed and produce fertile offspring. intermediate host: An animal species in which nonsexual developmental stages of some commensals and parasites occur. interspecific competition: Competition between species that need the same limited resource. intertidal marine zone: The shallow marine biome that lies at the land’s edge. intraspecific competition: Competition between members of the same species for a limited resource. intrinsic rate of increase: The growth rate of a population under ideal conditions, expressed on a per individual basis. introgression: The assimilation of the genes of one species into the gene pool of another by successful hybridization. invasive species: Nonnative (also termed “exotic”) organisms that can outcompete native species. See also exotic species. 709
Glossary iridescent: Showing the colors of the rainbow depending light reflection. irruption: A sudden increase in the size of a population, usually attributed to a particularly favorable set of environmental conditions. island biogeography: a distinct subdiscipline of biogeography that considers biodiversity and island size, ecological heterogeneity, proximity to continents, isolation and endemism, island size and location and rates of immigration, colonization, and extinction. Island biogeographers frequently have debates arguing the relevance of dispersal versus vicariance. isolation: See reproductive isolation. isotherm: A line or boundary imagined on the earth’s surface that connects points having the same temperature at a given time. K strategy [selection]: A reproductive strategy typified by low reproductive output; common in species living in areas having limited critical resources. keystone species: A species that determines the structure of a community, usually by predation on the dominant competitor in the community. kin selection: A phenomenon by which acts of altruism can help pass on genes for altruism by improving the survival of kin and their offspring. landscape ecology: A relatively new field of ecology, the study of how ecosystems, including the built environment, are arranged and how their arrangements affect the wildlife and environmental conditions that form them. Landscape ecologists examine land patterns (topography, water, forest cover, and human uses) and how these affect wildlife populations. lichen: An organism formed by the symbiotic relationship between a fungus and an alga. The alga is protected from drying by the fungus, while the fungus receives food molecules from the alga. life cycle: The sequence of development beginning with a certain event in a organism’s life (such as the fertilization of a gamete), and ending with the same event in the next generation. life expectancy: The probable length of life remaining to an organism based upon the average life span of the population to which it belongs. life span: The maximum time between birth and death for the members of a species as a whole. life table: A chart that summarizes the survivorship and reproduction of a cohort throughout its life span. 710
Glossary limnology: The study of the physical, chemical, climatological, biological, and ecological aspects of lakes. litter: The offspring produced in a single birth; also referred to as a clutch. littoral zone: The shore zone of a lake, where macrovegetation grows. local extinction: The loss of one or more populations of a species, but with at least one population of the species remaining. See also global extinction. logistic growth: A pattern of population growth that involves a rapid increase in numbers when the density is low but slows as the density approaches the carrying capacity. macroevolution: Large-scale evolutionary processes that result in major changes in organisms and allow them to occupy new adaptive niches or develop novel body plans. marine ecology: A branch of both ecology and oceanography that investigates the ocean zones and the interactions of their biotic and abiotic components, including all components impinging on the oceans such as seabirds and coastal zones. mark-capture-release methods: Methods of studying populations by capturing and marking some members, then releasing them into the wild and periodically recapturing them, or capturing successive samples, in order to track their status at different points in time. mass extinction: An event in which a large number of organisms in many different taxa are eliminated; there have been five such events in the history of life that resulted in the disappearance of more than 75 percent of all species. mate competition: Competition among members of one sex for mating opportunities with members of the opposite sex. maximum sustainable yield (MSY): The rate of harvest of natural resources such as fisheries and timber that can be maintained indefinitely through active human management of those resources. mediterranean scrub: Type of vegetation found in certain places, such as Southern California, which experience wet winters and long, dry summers. metabolites: Compounds formed as the result of biochemical pathways in an organism. metamorphosis: An abrupt change from one life-form to another, such as from a larval body form, accompanied by many physiological changes in the determination, differentiation, and distribution of cells, into an adult body form. microbivores: Organisms that eat microbes. 711
Glossary microevolution: Small-scale evolutionary processes resulting from gradual substitution of genes and resulting in very subtle changes in organisms. microphages: Animals that feed on small microscopic particles suspended in water or deposited on bottom sediments. migration: The movement of individuals resulting in gene flow, changing the proportions of genotypes in a population. mimicry: The resemblance of one species (the model) by one or more other species (mimics), such that a predator cannot distinguish among them. molecular clock: Accumulation of genetic changes that develops when two species diverge. The longer two species have been separate, the more changes will be evident. The clock does not tick at the same rate in every species or every molecule. molecular ecology: The study of natural and introduced microbial populations and their environments and ecological implications of the release of recombinant organisms. The development of molecular genetic techniques has led to this relatively new field for addressing ecological questions and issues. monoclimax theory: The theory, promulgated by Frederic A. Clements, that all communities within a given climatic region, despite initial differences, eventually develop into the same climax community. See also polyclimax theory. monocropping: The common agricultural practice of planting and growing single crops, usually on a large tract of land, requiring the use of chemical fertilizers and pest controls. monoculture: A single crop used in monocropping. monohybrid: An organism that is hybrid with respect to a single gene. monsoon forest: Forest type found in tropical regions of the world where there are annual periods of high rainfall. mortality rate: The number of organisms in a population that die during a given time interval. Müllerian mimicry: Mimicry in which the mimic is toxic. multiple use: Resource use in which land supports several concurrent managed uses rather than single uses over time and space. mutation: A change in the genetic sequence of an organism, sometimes leading to an altered phenotype. mutualism: A type of commensalism or symbiosis in which both symbiotes benefit from the association in terms of food, shelter, or protection. mycobiont: The fungal part of a lichen. 712
Glossary mycorrhiza (pl. mycorrhizae): A symbiotic relationship between a root and a fungus in which the fungus lives either in or on the root and gains food from it. The fungus increases absorption of water and minerals for the root. N: A standard abbreviation for the size of an actual population; if n ˆ , it is an estimated value. natality rate: Birthrate: the number of individuals that are born into a population during a given time interval. natural selection: The process of differential survival and reproduction that leads to heritable characteristics that are best suited for a particular environment. necroparasite: A parasite that consumes or lives in dead tissue. nekton: An aquatic organism that has the ability to swim. neoteny: Either the retention of immature characteristics in the adult form or the sexual maturation of larval stages; it results in new kinds of adult body plans. neritic zone: The marine zone that begins at a depth of about 600 feet (180 meters), where the gradual slant of the continental shelf becomes a sharp tilt toward the ocean floor, and extends to the ocean bottom. nest parasite: Also called brood parasite; an individual (or species) that lays its eggs in the nest of another individual (or species) and does no parenting at all. net primary productivity: The amount of energy, after plant respiration, that is potentially available to primary consumers. See also gross primary productivity; secondary productivity. neutral mutation: A mutation with no observable effect on the phenotype of the cell or organism in which it occurs. neutralism: A mutualism in which the two species are neither helped nor harmed. niche: An organism’s role in its habitat environment, such as food producer, decomposer, parasite, plant eater (herbivore), meat-eater (carnivore). The sum of environmental conditions necessary for the survival of a population of any species, including food, shelter, habitat, and all other essential resources. nitrogen cycle: The biogeochemical cycle of the element nitrogen. nitrogen fixation: Process by which bacteria convert atmospheric nitrogen to nitrogen-containing compounds, such as amino acids. nocturnal: Active at night. nomadic: Moving about from place to place according to the state of the habitat and food supply. 713
Glossary nonrandom mating: Mating that occurs whenever every individual does not have an equal chance of mating with any other member of the population. nonrenewable resource: A natural resource, such as copper, coal, aluminum, and oil, that exists in a fixed amount and cannot be naturally replenished at the rate it is being mined or removed. nonruminating: Digesting grasses without chewing cud. numerical response: The abundance of predators dependent upon the abundance of prey in a habitat. nutrient cycles, nutrient cycling: Large-scale movements of elements (such as carbon, nitrogen, and water) through the living and nonliving portions of an ecosystem. old-growth forest: Ancient forests in which many trees are hundreds of years old and which are among the richest ecosystems on earth. Considered nonrenewable. omnivore: An animal that eats both plant material and animal material. ontogeny: The successive stages during the development of an animal, primarily embryonic but also postnatal. opportunistic species: An invasive species that drives out native species by competing with them for resources. ordination: A method for collapsing community data for many species in many communities along several environmental gradients onto a single graph that summarizes their relationships and patterns. organic: Living. At the molecular level, containing carbon atoms as a primary component. organism: Any individual, self-contained life form, whether unicellular or multicellular, whether protist, fungal, algal, plant, or animal. orientation: An inherent sense of geographical location or place in time. outbreeding: Interbreeding of stocks of a species that are unrelated to each other. See also inbreeding. outgroup: A group of organisms only distantly related to the groups being examined in a cladistic study. overfishing: Harvesting so many fish, including sexually immature fish, that fishing becomes commercially inviable and ultimately leading to the species’ extinction. overgrazing: Destruction of vegetation by allowing too many grazing animals to graze beyond the carrying capacity of an area of rangeland. overhunting: Harvesting so many terrestrial species (usually mammals or reptiles), including sexually immature individuals, that the species is ultimately threatened with extinction. 714
Glossary ozone layer: The ozone-enriched layer of the stratosphere that filters out some of the sun’s ultraviolet radiation, which causes skin and other types of cancer. P generation: Parental generation; the original individuals mated in a genetic cross. pair-bonding: Prolonged and repeated mutual courtship display by a monogamous pair, serving to cement the pair bond and to synchronize reproductive hormones. paleoecology: The study of past ecosystems and environments. parasite: Any organism that lives on or in another living organism, the host, and obtains its food from that host. parasite-mix: All the individuals and species of symbiotes living concurrently in a host. parasitism: The state and activities of being a parasite. parasitoid: An insect, especially a wasp, that spends its larval stage in the body of another insect and eats it, eventually emerging as a free-living adult. patch: A habitat fragment within a landscape, often occuring in a patchwork of artificial and natural habitats strewn across a landscape in haphazard and unplanned fashion. pecking order: A dominance hierarchy in which the top individual can threaten and force into submission any individual below it, the number two individual can threaten anyone except number one, and the lowestranked individual can threaten no one and must submit to everyone. pelagic: The area of open water in the oceans; organisms that occur in the water column. per capita rate of increase: The difference between per capita births and per capita deaths, defined as r. Also called the per capita rate of growth. periodicity hypothesis: The proposal that mass extinctions have occurred approximately every 26 million years over the past 250 million years. permafrost: Permanently frozen layer of soil underlying tundra vegetation. perturbation: Factors such as diseases, parasites, fire, and deforestation, that disrupt ecosystems from within. pesticide: Chemical or biological substances designed to kill unwanted plants, fungi, or animals that interfere, directly or indirectly, with human activities. See also biopesticides. phenology: The science that examines the relationships between climates and climatic conditions and animal behaviors such as migrations or parts of the life cycle such as flowering in plants. 715
Glossary phenotype: The visible or outward expression of the genetic makeup of an individual. See also genotype. pheromone: A chemical produced by one member of a species that influences the behavior or physiology of another member of the same species. phosphorus cycle: The biogeochemical movement of phosphorus through an ecosystem. photoperiodism: Regulation of a plant process, such as flowering, by the relative length of light and dark periods in a twenty-four-hour day. photorespiration: The process that occurs during photosynthesis when the ratio of carbon dioxide to oxygen becomes too low. It results in the production of less sugar than during regular photosynthesis, and some carbon dioxide is formed. photosynthesis: The process by which green plants and algae, called primary producers, use sunlight as energy to convert carbon dioxide and water into energy-rich compounds such as glucose. phyletic: related by or having a common ancestral line in evolutionary terms. phylogenetics: The study of the developmental history of groups of animals. phylogeny: The evolutionary history of taxa, such as species or groups of species; order of descent and the relationships among the groups are depicted. physiological ecology: Sometimes called “autoecology,” “ecophysiology,” or “comparative physiology,” a type of individual ecology that examines how life-forms function mechanically and physiologically in their environments and how such factors as temperature, seasons, soil, and nutrients affect survival and reproduction of those organisms. Analyzes organismic adaptations from an engineering perspective in an evolutionary context to determine the relationship between individuals’ performance attributes, populations, and communities. physiology: The study of the functions, activities, and processes of living organisms. phytophagous: Animals, also referred to as herbivorous, that feed on plants. phytoplankton: Small plants, often single-celled, that float in water. Phytoplankton in the ocean are responsible for much of the earth’s oxygen production. pioneer species: The earliest, hardy organisms that begin colonizing an area in the first stage of ecological succession. plankton: Small plants and animals that float freely in water; their small size prevents them from having to swim to keep from sinking. 716
Glossary plant ecology: The study of plant life (often including fungal and algal forms) on all levels of ecology, from physiological to population to community to ecosystem ecology. Applications are particularly important in agriculture. poikilotherm: Cold-blooded or ectothermic; any organism having a body temperature that varies with its surroundings; in general, reptiles, amphibians, fish, and invertebrates. pollination: Transfer of pollen to a stigma in angiosperms or an ovule in gymnosperms. pollution ecology: The study of the impacts of water, air, and waste pollution on populations, communities, and ecosystems. polyclimax theory: Within a given climatic region, there can be many climaxes. See also monoclimax theory. polygamy: A mating system in which one male mates with several females (polygyny) or one female mates with several males (polyandry). polygenic inheritance: Expression of a trait depending on the cumulative effect of multiple genes; human traits such as skin color, obesity, and intelligence are thought to be examples of polygenic inheritance. polymorphism: The occurrence of two or more structurally or behaviorally different individuals within a species. polyphyletic: Having similar characteristics but originating from more than one ancestor. polyploidy: Genetic condition in which the hereditary material is present in three or more complete sets. Plants may be triploid (three sets of chromosomes), tetraploid, or have even greater numbers. population: A group of individuals of the same species that live in the same location at the same time. population analysis: The study of factors that influence growth of biological populations. population density: The number of individuals in a population per unit area or volume. population distribution: Variations in the density of a population in a particular area. population dynamics: The patterns of population growth and decline over the population’s existence, influenced by reproductive rates, predatorprey relationships, carrying capacity, and other such factors. population ecology: The study of the growth and decline of groups of individuals of the same species, and how these fluctuations function in relation to other populations in the same ecosystem. Examines such factors as the availability of food and hence predation, herbivory, and mutualisms. Community ecology is closely related to population ecol717
Glossary ogy but focuses on the interactions between populations of different species. population fluctuations: Changes in population size over time. population genetics: Branch of genetics that examines the movement of genes through populations. A population geneticist might study genetic drift, founder effect, or Hardy-Weinberg theorem. population regulation: Stabilization of population size by factors such as predation and competition, the relative impact of which depends on abundance of the population in a habitat. positive feedback loop: Situation in which a change in a certain direction provides information that causes a system to change further in the same direction. This can lead to a runaway or vicious cycle. predation: The act of killing and consuming another organism. The organism that gains its nutrition in this way is the predator; the organism that serves as the source of nutrition is the prey. primary consumer: An organism that get its nourishment from eating primary producers, which are mostly green plants and algae. primary metabolites: Sugar phosphates, amino acids, lipids, proteins, and nucleic acids, all of which comprise the basic molecules necessary for a cell to function. primary producers: In an ecosystem, those organisms that form foods from energy and simple chemical molecules. primary succession: Succession in which the initial seral stage, or pioneer community, begins on a substrate devoid of life or unaltered by living organisms. See also secondary succession. producers: See primary producers. productivity: The rate of accumulation of biomass. See also gross primary productivity; net primary productivity; secondary productivity. promiscuity: A mating system in which sexual partners do not form lasting pair bonds; their relationship does not persist beyond the time needed for copulation and its preliminaries. protective mimicry: Use of both color and form to mimic an inanimate feature of the environment. punctuated equilibrium: The idea that new species form during relatively short speciation events (a few generations) and then persist for millions of years in equilibrium (relatively unchanged) until they go extinct or speciate again. quadrat: A sample plot of a specific size and shape used in one method of determining population size or species diversity.
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Glossary r strategy (r selection): A reproductive strategy involving high reproductive output; found often in unstable or previously unoccupied areas. rain forest: Biome found in regions of the world where rainfall is high and there are no dry periods. Rain forests occur in the tropics and along the northwest coast of the United States. random genetic drift: The random change of gene frequencies because of chance, especially in small populations. random mating: The assumption that any two individuals in a population are equally likely to mate, independent of the genotype of either individual; this is equivalent to saying that all the gametes of all the individuals in a population are placed into a large pool, from which gametes are paired at random. rangeland: Open land of a wide variety of types, including grasslands, shrublands, marshes, and meadows as well as some desert and alpine land. recapture: See mark-capture-release methods. reciprocal cross: A mating that is the reverse of another with respect to the sex of the organisms that possess certain traits; for example, if a particular cross were tall male X short female, then the reciprocal cross would be short male X tall female. reciprocal relationship: Any type of coevolved, highly interdependent relationship between two or more species. reciprocal sacrifice: One explanation for acts of altruism among unrelated animals; an individual sacrifice is made under the assumption that a similar sacrifice may in turn aid the individual in the future. recombinant DNA: DNA molecules that are the products of artificial recombination between DNA molecules from two different sources; important as a foundation of genetic engineering. recombination: An exchange of genetic material, usually between two homologous chromosomes; provides one of the foundations for the genetic reassortment observed during sexual reproduction. red tide: An algal bloom that can be red, orange, brown, bright-green, or even blooms that do not discolor the water in which they grow, usually caused by dinoflagellates and often toxic. reef: A carbonate structure that possess an internal framework that traps sediment and provides resistance to wave action, thus forming habitat for a rich and diverse marine community. Types of reefs include atoll, barrier, fringing, and patch reefs. reforestation: The growth of new trees in an area that has been cleared for human activities, either occurring naturally or initiated by people. relict population: A remnant population of otherwise extinct organisms. replication: Copying of a DNA molecule, so that the two molecules formed 719
Glossary are identical to each other and to the original molecule. The two molecules formed are each composed of one strand from the original DNA molecule and one newly synthesized strand. reproductive (genetic) isolation: Describes any of many mechanisms that prevent one organism from sexually reproducing with a second. reproductive strategy: A set of traits that characterizes the successful reproductive habits of a group of organisms. reservoir host: A host species other than the one of primary interest in a given research study. resilience stability: Stability exhibited by a community that changes its structure when disturbed but returns to its original structure when the disturbance ends. resistance: The ability of an organism, population, or community to survive in the face of natural or human-made threats. resource: A requirement for life, such as space for living, food (for animals), or light (for plants), not including conditions such as temperature or salinity. resource-holding potential: The ability of an individual to control a needed resource relative to other members of the same species. respiration: The utilization of oxygen; in air-breathing vertebrates, the inhalation of oxygen and the exhalation of carbon dioxide. restoration ecology: Restoration ecology is the study and implementation of ways to return degraded or deteriorating communities and ecosystems to their original condition. Restoration ecologists work to restore habitat and return endangered species to viable numbers; they do not seek to restore extinct species or re-create ancient habitats. See also conservation biology. riparian ecosystem: An ecosystem in and around a river. ritualization: An evolutionary process that formalizes the context and performance of a display so that its meaning is clear and straightforward. runoff: Surface water effluent from precipitation, irrigation, or other human activity and the chemicals and other materials it ultimately carries into aquatic systems. salinization: The accumulation of salts in soil. saprophyte: Type of fungus or plant that gets its nutrition by digesting dead plants. Many mushrooms grow as saprophytes. saprovore: An organism that consumes dead or decaying plant or animal matter. savanna: Biome type characterized by widely spaced trees separated by open, grassy regions. 720
Glossary scale of being: An arrangement of life-forms in a single linear sequence from lower to higher; also called a chain of being. scavenger: An animal that feeds on the carcasses of other animals. scrub community: Plant community characterized by stunted trees and shrubs that may be widely spaced. Typical of poor soils. secondary consumers: Carnivorous animals that eat herbivorous animals (primary consumers). secondary metabolite: A biochemical that is not involved in basic metabolism, often of unique chemical structure and capable of serving a defensive role for an organism. secondary productivity: The rate at which animals produce their organic matter by feeding on other organisms. See also gross primary productivity; net primary productivity. secondary succession: Succession that starts in areas where an established community has been disturbed or destroyed by natural forces or by human activities. See also primary succession. seed dispersal: Process by which the seeds of a plant are distributed over a wide area, away from the parent plant. Many seeds are adapted for dispersal by wind or animals. selection: A process that prevents some individuals from surviving and propagating while allowing others to do so. See also natural selection. selective pressure: Evolutionary factors that favor or disfavor the genetic inheritance of various characteristics of a species. self-pollination: When pollen from the anther of a flower lands on the stigma of the same flower. semelparous species: Species, such as the Chinook salmon, that reproduce only once before dying. semiochemical: A chemical messenger that carries information between individual organisms of the same species or of different species; pheromones and allelochemics are semiochemicals, but hormones are not. sensitization: An arousal or an alerting reaction which increases the likelihood that an organism will react; also, a synonym for loss of habituation with increased intensity of response. sequester: To store a material derived from elsewhere. In defenses, some predators sequester defensive properties from their prey to defend themselves from their own predators. sex-role reversal: Generally used to refer to species in which the male does most of the parenting. sexual dimorphism: A difference in structure or behavior between males and females. sexual reproduction: Reproduction of cells or organisms involving the 721
Glossary transfer and reassortment of genetic information, resulting in offspring that can be phenotypically and genotypically distinct from either of the parents. sexual selection: The process that occurs when inherited physical or behavioral differences among individuals cause some individuals to obtain more matings than others. signal: Information transmitted through sound, such as bird calls, or through sight, such as body posture. signal pheromone: Nearly synonymous with releaser pheromone, but used with mammals to remove the suggestion of a programmed response and to indicate a more complex response. sit-and-wait foraging: Sitting in one place, waiting, and attacking prey as they move. slash-and-burn (swidden) agriculture: An agricultural practice in which forestland is cleared and burned for use in crop and livestock production. SLOSS: An acronym for single large or several small preserves. This mirrors and reflects the current discussion as to how best preserve, protect, and manage wildlife by use of one large park or preserve or several smaller parcels. social ecology: A branch of ecology, related to sociology, that critiques the relationship between environmental destruction and social structure or political ideology. social grooming: An activity maintaining social interaction, whereby debris is removed from a primate’s hair. sociality: The tendency to form and maintain stable groups. sociobiology: The study of the biological basis of the social behavior of animals. soil ecology: The study of soil as an ecosystem, including the interactions of both abiotic and biotic components of soil: bacterial, fungal, plant (humus, living roots), and animal (from protozoa and nematodes to insects and earthworms). Soil ecology extends beyond the physical borders of soil to include the impact of soil on aboveground life-forms such as larger plants and animals, as well as processes (geochemical cycles, erosion, human agricultural practices) that impact soil. See also agricultural ecology. soil erosion: Loss of topsoil because of erosion due to runoff, winds, and other forces. soldiers: In insect societies, large workers that defend the colony and often raid other colonies. somatic hybrids: Plants that result from the fusion of two somatic (nonreproductive) cells. 722
Glossary specialists: Species with narrow niches that are not well generalized, often able to live in only one habitat. speciation: The evolution of new species as a result of geographic, physiological, anatomical, or behavioral factors that prevent previously interbreeding natural populations from breeding with each other any longer. species: A group of animals capable of interbreeding under normal natural conditions; the smallest major taxonomic category. species diversity: The variety of different organisms at the species taxonomic level, a value that combines measures of both species richness and species evenness. species loss: Extinction. species selection: The idea that species are independent entities with their own properties, such as birth (speciation) and death (extinction); a higher level of selection above that of natural selection is postulated to take place on the species level. species-specific: Innate and exclusive to a single species. status badge: A visual feature that, based on its size or color or some other variation, indicates the social status of the bearer. stereotyped behavior: An unlearned and unchanging behavior pattern that is unique to a species. stimulus: Any environmental cue that is detected by a sensory receptor and can potentially modify an animal’s behavior. strategy: A behavioral action that exists because natural selection favored it in the past (rather than because an individual has consciously decided to do it). stratification: Division of a community into layers, such as canopy, shrub, and herb layers of a forest. stress: A pressure on an organism, population, or community as a result of ecosystem disturbance or an inadequate resource such as water or nutrients. stromatolite: Fossilized masses of cyanobacteria that represent some of the first evidence of photosynthetic life on earth. subspecies: A group or groups of interbreeding organisms within a single species that are distinct and separated from similar related groups but not reproductively isolated. substrate: The substance, such as soil or bark, on which a plant grows. Also, in biochemical reactions, the chemical compound upon which an enzyme acts. succession: Change in a plant or animal community over time, with one kind of organism or plant being replaced by other organisms or plants 723
Glossary in a more or less predictable pattern. See also primary succession; secondary succession. superorganism concept: An “organism” composed of more than one member, such as an insect society, reflecting the remarkable degree of coordination between individuals. survivorship: The pattern of survival exhibited by a cohort throughout its life span. sustainable development: The study and implementation of methods of agriculture, mining, timber harvesting, and other human interactions with the natural environment in a way that ensures minimal or no impact on the original ecosystems, to the end of conserving natural resources and minimizing impact on the organisms that occupy the habitats involved. The term “sustainable” is often coupled with more specific disciplines: “sustainable agriculture,” “sustainable forestry,” and so on. See also restoration ecology. swidden agriculture: See slash-and-burn agriculture. switching: The phenomenon that occurs when a predator has a choice of several prey species and learns to prefer one of them over a previous prey; if the preferred prey is sufficiently abundant, the predator will begin to concentrate on the preferred prey and may change its searching and other prey-related behaviors. symbiont: A member of a symbiotic relationship. symbiosis: A type of coevolved relationship between two species in which both participants benefit; a type of mutualism. sympatric: Living in the same place, not separated by a barrier that would prevent interbreeding. sympatric speciation: Evolution of two groups into separate species while living in overlapping geographic locations. synergism: The result of the interactions of a number of agents, operations, organisms, and other factors such that the final effect is greater than the sum of the individual effects. systematics: The subdivision of biology that deals with the identification, naming, and classification of organisms and with understanding the evolutionary relationships among them. See also classification; taxonomy. taiga: Biome located across Canada, northern Europe, and northern Asia that consists of forests of spruces, firs, and birches. See also boreal forest. taxonomy: A classification scheme for organisms based primarily on structural similarities; taxonomic groups consist of genetically related animals. See also classification; systematics. 724
Glossary temperate deciduous forest: Biome located in eastern North America south of the taiga, central Europe, and eastern China, characterized by forests of tree species, most of which lose their leaves every autumn. temperate mixed forest: A subdivision of the temperate deciduous forest in which pines share importance with deciduous trees. These forests are usually found on sandy soils in the southeastern United States. temporal variation: Variation across time. terrestrial: Living on land. territorial behavior: The combination of methods and actions through which an animal or group of animals protects its territory from invasion by other species. threat display: A territorial behavior exhibited by animals during defense of a territory, such as charging, showing bright colors, and exaggerating body size. threatened species: Animals or plants, as designated by official bodies such as the U.S. Fish and Wildlife Service, whose members are so few in number that they may soon become endangered and then extinct. topography: The structure and configuration of the earth’s surface, including its natural and human-made features. toxin: Any substance, such as the venom in snakes or spiders, that is toxic to an animal. trace element: Chemical element required in very small quantities for nutrition. transgenic: Possessing one or more genes from another organism, a concept important for the study of genetic mutations. transpiration: Evaporation of water from the leaves and stems of plants. Most transpiration occurs through open stomata. trophic levels: Positions at which specific organisms obtain their nutrition within a food chain. Plants and photosynthetic algae, which are primary producers, occupy the first trophic level, followed by primary and secondary consumers, scavengers, and decomposers. tropical rain forest: Biome found in tropical regions throughout the world that experience rainfall year-round. These are the most biodiverse ecosystems, often containing thousands of species of plants in a single acre. tropism: Plant growth response to an external stimulus. The plant may grow toward or away from the stimulus. Includes geotropism, gravitropism, heliotropism, phototropism, and thigmotropism. tundra: Regions where no trees grow because of frozen soil or extreme water runoff due to steep grades (at high altitudes) are known as tundra. See also alpine tundra; Arctic tundra.
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Glossary understory: In a rain forest, the shorter trees and shrubs that grow under and live in the shade of the canopy formed by the crowns of the tallest trees. uniformitarianism: The belief that the earth and its features are the result of gradual biological and geological processes similar to the processes that exist today. urban ecology: The study of the ecology of cities and human settlements, including energy and water flows, resource use, and how and where humans build. See also landscape ecology. urban heat island: A relatively hot area in the atmosphere above an urban area produced by a concentration of cars, factories, reflective surfaces, and other heat-producing factors. urbanization: The process of converting natural habitats into urban complexes. vector: An organism, such as a baterium, a mosquito, a virus, or a rodent or other mammal, that transmits pathogens from one host to another. veld: A grassland ecosystem, especially in southern Africa. venom: A toxic substance that must be injected (instead of ingested) to immobilize or kill prey. virion: A virus particle consisting of genetic material surrounded by a protein coat. viroid: Small, viruslike infectious molecules of RNA without protein coats. virus: A microscopic infectious particle composed primarily of protein and nucleic acid; bacterial viruses, or bacteriophages, have been important tools of study in the history of molecular genetics. visual predation: Catching prey (such as insects) by sighting them visually, judging their exact position and distance, and pouncing on them. warm-blooded: Referring to animals whose body temperatures are maintained at a constant level by their own metabolisms. warning coloration: The bright colors seen on many dangerous and unpalatable organisms that warn predators to stay away. weeds: hardy plants, usually invasive species, that successfully compete with native plants to the latter’s eventual weakening and extinction. wetlands: Transitional areas between aquatic and terrestrial habitats, home to a variety of flood-tolerant and salt-tolerant species. wildlife: All living organisms; traditionally, the term included only mammals and birds that were hunted or considered economically important. workers: Sterile, wingless female social insects.
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Glossary zonation: The distribution of organisms and other elements of ecosystems into regular or distinct biogeographical zones. zoogeography: The study of the distribution of animals over the earth. zoology: The study of the classification, anatomy, and physiology of animal life. zooplankton: Small animals, often single-celled, that float or swim weakly. zygote: A diploid cell produced by the union of a male gamete (sperm) with a female gamete (egg); through successive cell divisions, the zygote will eventually give rise to the adult form of the organism.
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WEB SITES NOTE: The Web sites listed below offer an entry into the many resources available on the Internet. These are simply some of the better known and more reliable sites. The editors accessed these URLs in April, 2003. Biodiversity and Ecosystem Function Online http://www.abdn.ac.uk/ecosystem/bioecofunc An “informal collaboration between several research institutes within the United Kingdom that share similar research interests. Hosted by the University of Aberdeen, Scotland, the site aims to be a resource for researchers specifically concerned with how the richness of species (or functional groups) affects ecosystem function. A list of the participants and a link to their respective research interests can be accessed through the ‘Project Partners’ page.” Offers a bibliography on ecosystem ecology. British Ecological Society http://www.britishecologicalsociety.org The BES “is an active and thriving organisation with something to offer anyone with an interest in ecology. Academic journals, teaching resources, meetings for scientists and policy makers, career advice and grants for ecologists” are among its activities. The Web site offers pages for general interest, students, teachers (including access to curriculumdriven publications), ecological issues, and career information. Earth’s 911 http://www.earth911.org/master.asp Aimed at children, students, and the general public, this site offers information on recycling and waste management options, including links to state-by-state listings of recycling centers, businesses, and regulations. Ecological Society of America http://www.esa.org A nonpartisan, nonprofit organization of scientists founded in 1915 to “promote ecological science by improving communication among ecologists; raise the public’s level of awareness of the importance of ecological science; increase the resources available for the conduct of ecological science; and ensure the appropriate use of ecological science in environ729
Web Sites mental decision making by enhancing communication between the ecological community and policy-makers.” Sponsors the Sustainable Biosphere Initiative. Offers an Education Section as well as resources for career placement, publications, and links to other ecology sites. Ecology WWW Page http://www.botany.net/Ecology Maintained by Anthony R. Brach of the Missouri Botanical Garden and Harvard University Herbaria, this list of links is maintained as a volunteer service to students, teachers, researchers, and others interested in the science of ecology. Envirolink http://www.envirolink.org This nonprofit organization has been providing access to online environmental resources since 1991, organized by categories such as Ecosystems, Environmental Disasters, Forests, and many more. The Ecology subsection files sites under such subcategories as Actions You Can Take, Educational Resources, General Info, Government Resources, Organizations, Jobs and Volunteer Opportunities, and Publications. Environmental Protection Agency http://www.epa.gov This U.S. government agency offers information and Web links organized by ecosystems such as the following: aquatic ecosystems, coasts, coral reefs, deserts, ecological assessment, ecological monitoring, ecological restoration, endangered species, environmental indicators, estuaries, exotic species, forests, freshwater ecosystems, lakes, landscape ecology, marine ecosystems, oceans, species, terrestrial ecosystems, urban ecosystems, watersheds, and wetlands. National Academy of Sciences http://www4.nationalacademies.org/nas/nashome.nsf A “private, nonprofit, self-perpetuating society of distinguished scholars engaged in scientific and engineering research, dedicated to the furtherance of science and technology and to their use for the general welfare. Upon the authority of the charter granted to it by the Congress in 1863, the Academy has a mandate that requires it to advise the federal government on scientific and technical matters.”
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Web Sites National Council for Science and the Environment http://www.ncseonline.org A U.S. government-sponsored Web site which links to the National Library for the Environment. From here, students can search more than 1,200 congressional reports on topics in agriculture, biodiversity, climate change, energy, forests, pesticides, pollution, public lands, stratospheric ozone, wetlands, and a host of other environmental topics. National Oceanic and Atmospheric Administration http://www.noaa.gov NOAA maintains pages on oceans, satellites, fisheries, weather, climate, coasts, and current events broken down by type of environmental impact: dust, fires, floods, ice, oil spills, snow, severe weather, tropical, and volcanic. In addition, NOAA’s library, photo library, other pages on topics of ecological interest (such as coral reefs and El Niño), and organized lists of links provide access to other sites and research. National Resources Conservation Service http://www.nrcs.usda.gov The mission of this division of the U.S. Department of Agriculture is to “assist owners of America’s private land with conserving their soil, water, and other natural resources.” The NRCS maintains two pages of interest: “Ecological Sciences” for agribusiness professionals and a page for teachers and kids with educational materials on soils, conservation biology, composting, and the like. The Need to Know Library: Ecology and Environment Page http://www.peak.org/~mageet/tkm/ecolenv.htm Lists topics “under three headings: Ecology, Conservation Biology, and Botany and Systematics. Links to home pages of botanical and ecological societies are provided in the Journals and Societies List. The Ecological Software List offers links to sites describing software applications for analyzing or organizing ecological data. The Natural Resource Agencies List provides links to home pages of government agencies that conduct ecological research or that are responsible for the management of various ecosystems. The Natural Areas and Reserves heading lists links to sites that feature information about natural areas, LTER sites, national parks, and wilderness areas. The Environment List refers to sites dealing with ecosytem conditions and the Environmental Societies List is a catalog of links to home pages of environmental organizations.” 731
Web Sites Sierra Club http://www.sierraclub.org In addition to its outreach programs encouraging public involvement in recycling, conservation, and nature activities, the Sierra Club is active in environmental issues, offering updates on current events in water, energy, global population, and more. Society for Conservation Biology http://conbio.net The Virtual Library of Ecology and Biodiversity is maintained through this site. UNEP-WCMC Protected Areas Information http://www.wcmc.org.uk/data/database/un_combo.html Sponsored by the United Nations Environment Programme and the World Conservation, this page provides access to information on nearly all nations of the world, including basic facts, history, and present policies concerning protected areas. Each essay is lengthy and detailed and includes references. United National Environment Programme http://www.unep.org UNEP’s mission is “to provide leadership and encourage partnership in caring for the environment by inspiring, informing, and enabling nations and peoples to improve their quality of life without compromising that of future generations.” Its Web site offers resources and links on habitats, species, regions, climate change, protected areas, and much more—including a kids’ page that offers facts and educational games on the atmosphere, forests, biodiversity, polar regions, whales, and aquatic ecosystems. U.S. Geological Survey http://www.usgs.gov Not simply a geology resource, the USGS maintains a wealth of data and fact sheets on biological and ecological information as well, searchable by topic or state. Topics include Biological Resources, Earthquakes, Floods, Ground Water, Maps, Streamflow, Water Quality, and more.
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Web Sites USDA Forest Service http://www.fs.fed.us This U.S. government site offers information on public lands in national forests and grasslands, organized state by state, as well as a photo gallery, maps, and information on the programs overseen by the agency. World Conservation Union http://www.iucn.org Known also by its former initials IUCN, the World Conservation Union “seeks to influence, encourage and assist societies throughout the world to conserve the integrity and diversity of nature and to ensure that any use of natural resources is equitable and ecologically sustainable.” Provides access to library catalog, publications, programs, contacts. World Resources Institute http://www.wri.org A nonprofit environmental research and policy organization that works with governments, the private sector, and civil society groups in more than one hundred countries around the world. Offers updates on global environmental and ecological issues. Maintains a section called “EarthTrends” in which maps, data tables, searchable databases, and country profiles can be accessed by topic: Coastal and Marine Ecosystems; Water Resources and Freshwater Ecosystems; Climate and Atmosphere; Population; Health and Human Well-being; Economics; Business and the Environment; Energy and Resources; Biodiversity and Protected Areas; Agriculture and Food; Forests, Grasslands and Drylands.
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CATEGORIZED INDEX Agricultural ecology Biopesticides, 65 Erosion and erosion control, 211 Genetically modified foods, 284 Grazing and overgrazing, 304 Integrated pest management, 351 Multiple-use approach, 422 Pesticides, 470 Rangeland, 560 Slash-and-burn agriculture, 590 Soil, 594 Aquatic and marine ecology Acid deposition, 1 Lakes and limnology, 364 Marine biomes, 391 Ocean pollution and oil spills, 444 Reefs, 564 Behavioral ecology Altruism, 18 Communication, 95 Competition, 111 Defense mechanisms, 125 Displays, 167 Ethology, 215 Habituation and sensitization, 319 Herbivores, 326 Hierarchies, 329 Insect societies, 343 Isolating mechanisms, 358 Mammalian social systems, 385 Migration, 407 Mimicry, 415 Omnivores, 455 Pheromones, 476 Poisonous animals, 486 Predation, 536
Reproductive strategies, 576 Territoriality and aggression, 633 Biomes Biomes: determinants, 55 Biomes: types, 59 Chaparral, 76 Deserts, 154 Forests, 269 Grasslands and prairies, 298 Habitats and biomes, 313 Lakes and limnology, 364 Marine biomes, 391 Mediterranean scrub, 399 Mountains, 419 Old-growth forests, 452 Rain forests, 549 Rain forests and the atmosphere, 554 Rangeland, 560 Reefs, 564 Savannas and deciduous tropical forests, 586 Taiga, 629 Tundra and high-altitude biomes, 655 Wetlands, 672 Chemical ecology Allelopathy, 15 Bioluminescence, 43 Communication, 95 Defense mechanisms, 125 Genetically modified foods, 284 Metabolites, 402 Pheromones, 476 Poisonous animals, 486 Poisonous plants, 490 735
Categorized Index Community ecology Allelopathy, 15 Animal-plant interactions, 24 Biodiversity, 32 Biogeography, 37 Biological invasions, 40 Coevolution, 86 Communities: ecosystem interactions, 100 Communities: structure, 104 Competition, 111 Food chains and webs, 255 Gene flow, 274 Genetic diversity, 278 Lichens, 381 Mycorrhizae, 425 Pollination, 495 Speciation, 604 Succession, 612 Symbiosis, 621 Trophic levels and ecological niches, 641 Ecoenergetics Balance of nature, 28 Biomass related to energy, 50 Food chains and webs, 255 Geochemical cycles, 288 Herbivores, 326 Hydrologic cycle, 338 Nutrient cycles, 440 Omnivores, 455 Phytoplankton, 482 Rain forests and the atmosphere, 554 Trophic levels and ecological niches, 641 Ecosystem ecology Biodiversity, 32 Biological invasions, 40 736
Biomes: determinants, 55 Biomes: types, 59 Chaparral, 76 Communities: ecosystem interactions, 100 Desertification, 149 Deserts, 154 Ecosystems: definition and history, 184 Ecosystems: studies, 191 Erosion and erosion control, 211 Forest fires, 258 Forests, 269 Genetic diversity, 278 Geochemical cycles, 288 Grasslands and prairies, 298 Habitats and biomes, 313 Hydrologic cycle, 338 Invasive plants, 354 Isolating mechanisms, 358 Lakes and limnology, 364 Marine biomes, 391 Mediterranean scrub, 399 Mountains, 419 Nutrient cycles, 440 Old-growth forests, 452 Rain forests, 549 Rain forests and the atmosphere, 554 Rangeland, 560 Reefs, 564 Savannas and deciduous tropical forests, 586 Soil, 594 Taiga, 629 Trophic levels and ecological niches, 641 Tundra and high-altitude biomes, 655 Wetlands, 672
Categorized Index Ecotoxicology Acid deposition, 1 Biological invasions, 40 Biomagnification, 47 Biopesticides, 65 Deforestation, 131 Eutrophication, 222 Genetically modified foods, 284 Integrated pest management, 351 Invasive plants, 354 Ocean pollution and oil spills, 444 Ozone depletion and ozone holes, 457 Pesticides, 470 Phytoplankton, 482 Pollution effects, 500 Slash-and-burn agriculture, 590 Soil contamination, 601 Waste management, 667 Evolutionary ecology Adaptations and their mechanisms, 7 Adaptive radiation, 12 Coevolution, 86 Colonization of the land, 90 Convergence and divergence, 120 Dendrochronology, 145 Development and ecological strategies, 161 Evolution: definition and theories, 227 Evolution: history, 236 Evolution of plants and climates, 241 Extinctions and evolutionary explosions, 246 Gene flow, 274 Genetic drift, 281 Genetically modified foods, 284
Isolating mechanisms, 358 Natural selection, 428 Nonrandom mating, genetic drift, and mutation, 435 Paleoecology, 464 Punctuated equilibrium vs. gradualism, 543 Speciation, 604 Species loss, 608 Global ecology Biodiversity, 32 Biomes: determinants, 55 Biomes: types, 59 Biosphere concept, 69 Geochemical cycles, 288 Global warming, 292 Greenhouse effect, 308 Hydrologic cycle, 338 Ozone depletion and ozone holes, 457 Rain forests and the atmosphere, 554 History of ecology Ecology: history, 179 Ecosystems: definition and history, 184 Evolution: history, 236 Landscape ecology Landscape ecology, 374 Urban and suburban wildlife, 659 Paleoecology Colonization of the land, 90 Dendrochronology, 145 Evolution: definition and theories, 227 Evolution of plants and climates, 241 737
Categorized Index Extinctions and evolutionary explosions, 246 Paleoecology, 464 Physiological ecology Adaptations and their mechanisms, 7 Bioluminescence, 43 Camouflage, 72 Defense mechanisms, 125 Mimicry, 415 Pheromones, 476 Poisonous animals, 486 Poisonous plants, 490 Pollination, 495 Tropisms, 650 Population ecology Adaptive radiation, 12 Biodiversity, 32 Biogeography, 37 Clines, hybrid zones, and introgression, 80 Convergence and divergence, 120 Demographics, 137 Extinctions and evolutionary explosions, 246 Gene flow, 274 Genetic diversity, 278 Genetic drift, 281 Human population growth, 333 Insect societies, 343 Nonrandom mating, genetic drift, and mutation, 435 Population analysis, 507 Population fluctuations, 513 Population genetics, 520 Population growth, 528 Punctuated equilibrium vs. gradualism, 543 Reproductive strategies, 576 738
Restoration and conservation ecology Biodiversity, 32 Conservation biology, 119 Deforestation, 131 Endangered animal species, 196 Endangered plant species, 205 Erosion and erosion control, 211 Forest management, 263 Genetic diversity, 278 Grazing and overgrazing, 304 Integrated pest management, 351 Multiple-use approach, 422 Old-growth forests, 452 Reforestation, 572 Restoration ecology, 583 Soil contamination, 601 Species loss, 608 Sustainable development, 618 Urban and suburban wildlife, 659 Waste management, 667 Wildlife management, 677 Zoos, 681 Soil ecology Erosion and erosion control, 211 Soil, 594 Soil contamination, 601 Speciation Adaptive radiation, 12 Clines, hybrid zones, and introgression, 80 Convergence and divergence, 120 Evolution: definition and theories, 227 Evolution of plants and climates, 241 Extinctions and evolutionary explosions, 246 Gene flow, 274
Categorized Index Isolating mechanisms, 358 Natural selection, 428 Punctuated equilibrium vs. gradualism, 543 Speciation, 604 Theoretical ecology Balance of nature, 28
Biomes: determinants, 55 Biomes: types, 59 Biosphere concept, 69 Deep ecology, 123 Ecology: definition, 171 Ecosystems: definition and history, 184 Sustainable development, 618
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SUBJECT INDEX Abiotic components of ecosystems, 186, 191, 314 Abundance, cycles of, 513, 539 Abyssal marine zone, 63, 392 Acacia-ant mutualisms, 87 Acceleration (heterochrony), 163 Acid deposition, 1, 6, 110, 189, 591, 631 Acid rain, 501; and soil generation, 594 Adaptation, 171, 428, 521; behavior as, 217; Darwin on, 238; mechanisms of, 7, 11; migration, 408; ontogeny as, 162; and speciation, 606; Triassic period, 250 Adaptive coloration, 10 Adaptive radiation, 12, 14, 122, 239; and speciation, 606 Adders, 488 Adelgids, 41 Adult survivorship patterns, 139 Africa, habitat loss, 207 Agave lechuguilla (indicator species), 156 Age structures, 140, 508; population analysis, 511 Aggregation pheromones, 476 Aggression, 22, 633, 640; in dominance hierarchies, 329 Aggressive mimicry, 417, 538 Agrichemicals, 500 Agricultural ecology. See Agriculture; Categorized Index Agriculture; uses of allelopathy, 15; and deforestation, 131; genetic diversity, 279; genetically modified crops, 284,
287; and rangelands, 562; slashand-burn, 590, 593; world food supplies, 336 Ailanthus (tree-of-heaven), 659 Air pollution, 591; lichens as bioindicators, 383 Alarm calls, 97 Alarm pheromones, 476 Alerting system, 321 Algae, 315; earliest life on land, 91; eutrophic environments, 223; killer, 357; phytoplankton, 482. See also Phytoplankton; Plankton Algal blooms, 224, 370, 482-483 Aliphatics (hydrocarbons), 444 Alkaloids, 103, 403, 491 Alleles, 12, 274, 281, 435; frequency, 436 Allelochemicals, 15 Allelopathy, 15, 17, 101, 354 Allen’s rule, 81 Alligator River Wildlife Refuge, 116 Alligators, 203 Allochthonous deposition, 465 Allogenic clastic materials, 366 Allomones, 477 Allopatric speciation, 543, 604 Alpha individuals, 330 Alpine tundra, 61, 315, 655 Altruism, 18, 23, 522 Alvarez, Luis, 247 Alvarez, Walter, 247 Amazon basin, 558 Amber, 466 Ambush predation, 539 Amensalisms, 100 741
Subject Index American Acclimitization Society, 662 American pronghorns, 300 American Society of Limnology and Oceanography, 180 Anaerobic bacteria, 369 Anaphylactic shock, 487 Anaximander, 236 Ancient Bristlecone Pine Forest, 146 Anemones, 624 Angiosperm evolution, 86, 244 Anglerfish, 396 Animal-plant interactions, 10, 24, 27, 100, 105; herbivores, 326; pollination, 86 Anoxia, eutrophic environments, 224 Antennae and pheromones, 478 Anthocyanidins, 405 Anthocyanins, 405 Antibiotic resistance, 526 Antibiotics, 15 Antithesis principle, 168 Ants, 343; and aphids, 128; competition among, 115; mutualisms with acacias, 87, 174; pheromones, 477 Aphids, 343; and ants, 128 Aphotic marine zone, 391 Aplysia (sea hare), 321 Aposematic coloration, 128, 167 Aposematism, 538 Aquatic and marine ecology. See Categorized Index Aquatic biomes, 315 Aquatic communities, 173 Aquatic ecosystems, 614; nutrient sources, 440; production in, 188 Aquatic plants; invasive, 357; wetlands, 674 742
Arabian Gulf, 450 Araceae (philodendron), 491 Arbor Day, 575 Arbuscules, 427 Arbutoid mycorrhizae, 426 Archaeocalamites, 242 Archaeocyathids, 567 Arctic terns, migration, 411 Arctic tundra, 61, 314, 655 Argyroxiphium sandwicense (silversword), 13 Arid climates, 149, 153 Aromatics (hydrocarbons), 445 Arrestant pheromones, 476 Artemisia tridentata (indicator species), 156 Arthropods, 487 Artiodactyls, 326 Asexual reproduction, 524, 605 Aspens, quaking, 629 Aspirin, 405 Associational defenses, 128 Aster family, 13, 157 Atlantic Ocean, surface temperatures, 150 Atmosphere, 69; ancient, 556; impact of desertification, 151; Devonian oxygenation, 93; ozone, 556; ozone depletion, 457, 463; rain forests’ impact, 554, 559 Atoll reefs, 564 Atomic Energy Commission, 180, 188 Atropine, 404 Attractants; phenolics, 405; pheromones, 476 Auditory calls; communication, 97; displays, 169 Audubon, John James, 198 Audubon Society, 678
Subject Index Australia, habitat loss, 207 Australian honey eaters, 636 Autochthonous deposition, 465 Autotomy (defense mechanism), 129 Autotrophs, 50, 86, 111. See also Producers Auxins, 650 Baboons; competition among, 114; hierarchies, 330; social systems, 386 Bacillus cereus (biopesticide), 66 Bacillus popilliae (biopesticide), 66 Bacillus thuringiensis (biopesticide), 66, 285 Backcrossing, 83 Background extinctions, 246 Bacteria; anaerobic, 224; bioluminescent, 43; biopesticides, 65; cyanobacteria, 225, 393, 465, 482; as decomposers, 112, 185, 290, 368; in digestion, 102, 305; mutation rates in, 438; nitrogen fixation, 289; oil-eating, 448; phosphorus cycle, 290; in soil, 316, 596; symbiotic, 127; weathering agents, 173 Bacterioplankton, 392-393 Badgers, defense mechanisms of, 126 Baer, Karl Ernst von, 161 Baer’s laws, 161 Balance of nature, 28, 31, 255, 517 Bald eagles, 199 Barnacles, 623 Barrier reefs, 564 Base flow, 341 Batesian mimicry, 128, 416, 538 Bathypelagic marine zone, 392
Bats; desert, 157; as pollinators, 497 Beaded lizards, 486 Beagle, voyage of the, 238 Bears, 13 Beebe, William, 197 Beefalo, 84 Beer, Gavin de, 163 Bees, 344; Africanized, 116; dance language, 215; as pollinators, 496 Beetles; bark, 511; bombardier, 126; as pollinators, 497 Behavior; as camouflage, 74; and communication, 95; ethology, 215; and reproductive strategies, 576 Behavioral adaptations, 10 Behavioral displays, 167 Behavioral ecology, 218. See also Categorized Index Behavioral genetics, 217 Behavioral isolation, 358 Behaviorism, 216 Benthic marine zone, 391, 397 Bergmann’s rule, 80 Beta-carotene, 405 Beta individuals, 330 Bighorn sheep, 157 Bioaccumulation. See Biomagnification Biodiversity, 32, 36, 134, 618; and adaptation, 7; ancient, 251; and biogeography, 37; and pollution, 500; rain forests, 558; urban and suburban wildlife, 660 Biogenetic law, 162 Biogeochemical cycles; hydrologic cycle, 338, 342; nutrient cycles, 440, 443. See also Carbon cycle; 743
Subject Index Geochemical cycles; Hydrologic cycle; Nitrogen Cycle; Nutrient cycles; Oxygen cycle; Phosphorus cycle Biogeography, 37, 39, 179, 233; islands, 33 Bioherms, 564 Biological diversity, 612 Biological invasions, 40, 42 Biological phenomena diversity, 35 Bioluminescence, 43, 46, 96, 392 Biomagnification, 47, 49, 474 Biomass, 50, 54, 174, 186-187, 256, 612; grasslands, 298 Biomes, 313, 318; determinants of, 55, 58; and habitats, 314; studies, 181; table, 56; types, 59, 64. See also Alpine tundra; Arctic tundra; Boreal forests; Chapparal; Deciduous tropical forests; Deserts; Ecosystems; Ecotones; Forests; Grasslands; Lake ecosystems; Marine biomes; Mediterranean scrub; Mountain ecosystems; Oldgrowth forests; Prairies; Rain forests Biopesticides, 65, 68, 355, 470; in integrated pest management, 352 Biosphere, 69, 71, 191, 316 Biostromes, 564 Biotic components of ecosystems, 186, 192 Biotic potential, 530 Birches, 629 Birdcalls and birdsongs, 97; and territoriality, 634 Birds; communication, 96; omnivorous, 456; pollinators, 744
497; population fluctuations, 515; territorial behavior, 633; urban habitats, 660 Birthrates (population analysis), 137, 530 Bison, 300, 609; introgression of, 84; overhunting of, 198 Black-collared lizards, 158 Black-footed ferrets, 109, 203, 300 Black mambas, 488 Black widow spiders, 158, 487 Blackbirds, competition among, 115 Blight, chestnut, 355 Blood flukes, 625 Bobcats, 157 Body size; and clines, 80; and reproduction, 576 Bogs, 673 Bombardier beetles, 126 Boreal forests, 56, 60, 270, 629, 632, 656 Bormann, F. Herbert, 193 Bottleneck effect on population size, 437 Boyce, Mark, 579 Brachiopods, 248 Brachystegia (Central Africa), 586 Brackish marshes, 674 Bradley, Richard, 28 Branching evolution, 228, 237 Breeding cycles, 514 Breeding programs, 480 Bristlecone pines, 146 British Ecological Society, 180 Brown pelicans, 203 Brown tides, 224. See also Algal blooms; Eutrophication; Phytoplankton; Red tides Bryozoans, 567 Buffalo, 609; overhunting of, 198
Subject Index Buffon, Comte de, 29 Bullfrogs, 158 Bureau of Land Management, 677 Burgess Shale, 249 Buri, Peter, 438 Buteo jamaicensis (red-tailed hawk), 663 Butterflies, 203; monarch, 538; as pollinators, 497; viceroy, 538 Caatinga (Amazon basin), 586 Cacti, 156; convergent evolution, 120; endangered, 208 Caffeine, 404 Calcareous algae, 567 California, fire management in, 400 California condors, 203 Calvin cycle, 556 Cambrian explosion, 249 Camouflage, 72, 75, 167; and bioluminescence, 45; vs. mimicry, 415; peppered moth, 10 Canada, acid precipitation in, 631 Canada thistle, 356 Cancer medications, 404 Canopy (rain forests), 269, 551, 558 Captive breeding, 684 Carbamates, 471 Carbon cycle, 288, 441, 483; rain forests, 556 Carbon dioxide; and global warming, 310; rain forests, 554 Carboniferous period, 242 Carew, Thomas J., 322 Carnegiea gigantecus (indicator species), 156 Carnivores, 111, 174, 256, 455, 561, 641; bears, 13; and herbivores,
326; marine, 395; social organization, 389 Carnivorous plants, 208 Carr, Archie, 408 Carrying capacity, 81, 187, 301, 304, 410, 511, 531, 577, 678 Carson, Rachel, 30, 193, 200 Castes and social insects, 345 Castor bean plant, 492 Cat hierarchies, 331 Catastrophism, 238 Cations, 595 Cedar Bog Lake, Minnesota, 186, 191 Cellular respiration, 554 Cellulose, 102 Cenozoic era, 244 Censuses (demographic tool), 142 Central American dry forests, 588 Central Park, New York City, 663 Ceratius, 396 Cerrado (Brazil), 586 CFCs. See Chlorofluorocarbons Challenger, HMS, 182 Chambers, Robert, 237 Channel Islands, California, 206 Chaparral, 62, 76, 79, 399 Character displacement, 644 Charophytes, 91 Chemical ecology. See Categorized Index Chen hyperborea (snow goose), 435 Chenopodiaceae (indicator species), 157 Chestnut trees, 356 Chihuahuan Desert, 156 Chimpanzees, habituation studies, 324 Chlorinated hydrocarbons, 470 Chlorofluorocarbons, 308, 459, 501 Circadian rhythms, 409 745
Subject Index Circumnutation, 652 Clean Water Act (1965), 675 Cleaning symbiosis, 624 Clear-cutting, 53, 266, 334, 552; reforestation, 572 Clements, Frederic E., 30, 182, 615 Cleveland, Grover, 422 Climate change, global warming, 294 Climates; and the biosphere, 70; and tree rings, 145 Climax communities, 612, 617 Climax pattern concept, 615 Climax stage, 173 Clines, 80, 85 Clones, 172 Clotting agents as venoms, 486 Clown fish, 624 Club mosses, 241 Clutch size, 576; and clines, 81 Coal, Age of, 242 Cobras, 488 Cocaine, 404 Codeine, 404 Coenogonium leprieurii (lichen), 381 Coevolution, 10, 24, 86, 89, 174; defense mechanisms, 127; grasses and grazers, 304; pollinators, 495; and symbiosis, 624 Cohorts, 138 Cold-blooded animals, 10 Collier, G., 115 Colonies, ant, 343 Colonization of the land, 90, 94 Coloration; agouti, 72; aposematic, 128, 167, 538; cryptic, 72; marine animals, 396; warning, 415 Colubrids, 487 746
Columella cells, 651 Commensalisms, 87, 100, 622 Communication, 95, 99; bees, 215, 345; and bioluminescence, 44; insects, 343, 345; and pheromones, 480 Communities; ecosystem interactions, 100, 103; and ecosystems, 184; and habitats, 314; isolated, 37; lentic and lotic, 315; structure, 104, 110, 612; succession, 612, 617 Community ecology, defined, 173. See also Categorized Index Compartmentalization, 104 Compass plants, 653 Competition, 100, 106, 111, 118, 173, 621; defense mechanisms, 125; distinguished from allelopathy, 15; and hierarchies, 329; interspecific, 644; and predation, 539; reduction through migration, 409; and speciation, 545; and species loss, 609; and territoriality, 634 Competition exclusion law, 644 Competitive exclusion, 66, 101 Composting, 669 Condensation, 338 Condors, 203 Coniferous forests, 314, 629 Conifers, 269, 629; evolution of, 242 Connectivity, 378 Conservation biology, 35, 119, 433; endangered plants, 209; wildlife management, 677. See also Restoration ecology Conservation easements, 264 Consumers, 24, 52, 104, 174, 187, 191, 557; macroscopic vs.
Subject Index microscopic, 102. See also Heterotrophs Contact herbicides, 471 Contact zones, 275 Continental shelf, 63 Continental slope, 63 Continuous populations, 507 Convention on International Trade in Endangered Species, 202 Convergence, 120, 122, 157, 615 Cooperative behavior; altruism, 19; and hierarchies, 330; mole rats, 389; social insects, 346 Copepods, 393 Copperhead snakes, 487 Copulation, 577 Coral reefs, 566, 624; territoriality in, 636 Coral snakes, 487 Corals, 566; Devonian period, 248; parasites of, 625; reefs, 127; stingers, 129 Coriolis force, 154 Corollas, 497 Correlational analysis, 580 Correlational selection, 430 Corridors, 378 Costa’s hummingbirds, 158 Coterie (family unit), 388 Cottonmouth snakes, 487 Coumarins, 15 Countershading, 72 Countersinging, 98 Courtship; competition, 113; displays, 167; isolating mechanisms, 361 Cowles, Henry Chandler, 181 Coyotes, 157, 300, 389, 665 Crabs, hermit, 624 Craighead, Frank, 517
Craighead, John, 517 Cranes, 203 Crater Lake, 364 Creep, 212 Cretaceous period, 243; coevolution during, 86 Cretaceous-Tertiary (KT) event, 244, 252 Crickets, communication, 98 Crop plants; allelopathy, 15; diversity, 279; genetically modified, 284 Cross-dating, 146 Cross-pollination, 495 Crossbills, competition among, 115 Crown fires, 260, 267 Crustaceans, 393 Cryoplanation, 655 Cryprochromes, 650 Crypsis, 72 Cryptophytes, 588 Cultural eutrophication, 222 Curare, 492 Cuvier, Georges, 237 Cyanobacteria, 393, 465, 482 Cycads, evolution of, 242 Cycles of abundance, 513, 539 Dance language of bees, 215, 345 Darwin, Charles, 13, 29, 38, 179, 227, 237, 274, 428; description of habituation, 320; ethology, 215 Darwin’s finches, 429. See also Finches Dasyatids, 488 Dating techniques; dendrochronology, 146; radiocarbon dating, 146 Davis, Michael, 323 747
Subject Index Dawkins, Richard, 522 DDT, 256, 470, 473, 503; dependence on, 351; species loss, 199; in zooplankton, 48 Death rates, 138; zoos, 438 Death rates (population analysis), 137, 530 Debt-for-nature swaps, 264 Deciduous forests, 314-315; tropical, 586, 589 Deciduous trees, 269, 629; diseases, 41; savannas, 62; temperate forests, 59, 269 Decomposers, 52, 104, 174, 187, 191, 256, 557, 561, 641; bacteria, 290; lake bottoms, 369; zooplankton, 393 Deep ecology, 123-124 Deevey, Edward S., 139 Defense mechanisms, 102, 125, 130; and bioluminescence, 44; plants, 88; and predation, 537; and territoriality, 634; venoms, 486 Defensive associations, 128 Deforestation, 53, 131, 136, 150, 263, 334; rain forests, 554 Demes, 80, 274 Demographics, 137, 144. See also entries under Population Dendrochronology, 145, 148-149, 464 Density-dependent growth, 511 Density-dependent migration, 410 Density-dependent natural selection, 579 Density-dependent population fluctuations, 513, 577 Density-dependent territoriality, 637 Deoxyribonucleic acid. See DNA 748
Department of the Interior, U.S., 200 Deposition (water erosion), 211, 290 Descent of Man and Selection in Relation to Sex, The (Darwin), 215, 238 Descriptive ecology, 175 Desert coyotes, 157 Desert Storm (military action), 449 Desertification, 149, 153, 306 Deserts, 61, 149, 153-154, 160, 294, 314; adaptations to, 9; cold, 315; hot, 315 Despotism, 330 Detachment (water erosion), 211 Deterrent pheromones, 476 Development; and ethology, 216; and evolution, 161, 166, 428; sustainable, 618, 620 Devonian period, 93, 241 Diagenesis, 370 Diamond, Jared, 33 Diatoms, 366, 482 Dichloro-diphenyl-trichloroethane. See DDT Dieffenbachia (dumb cane plant), 491 Differential growth, 650 Dimictic lakes, 367 Dinoflagellates, 482, 625 Dinosaurs, extinction, 249 Dioxin, 504 Directional selection, 429 Disasters, impact on communities and ecosystems, 106 Discrete displays, 96 Discrete population, 507 Diseases; and biopesticides, 65; insect-borne, 41; urban and
Subject Index suburban wildlife, 665; and wildlife management, 678 Dishabituation, 320 Dispersal, 38; corridors, 378; and landscape fragmentation, 375. See also Seed dispersal Dispersal of populations, 407 Disphotic marine zone, 391 Displays, 95, 113, 167, 170; and territoriality, 634 Disruptive coloration, 72 Disruptive selection, 429 Disturbance in ecosystems, 189 Diterpenes, 404 Divergence, 120, 122 Divergent populations, 12 Diversity. See Biodiversity; Biological phenomena diversity; Ecosystem diversity; Genetic diversity; Species diversity DNA (deoxyribonucleic acid), 229 DNA sequencing, 233 Dobzhansky, Theodosius, 358 Dogs, social organization of, 389 Dominance hierarchies, 114, 329, 637 Dominant species, 104 Douglass, Andrew Ellicott, 145 Dragonfish, 45 Dragonflies, 158 Drift. See Genetic drift Drought, 135, 150; dry tropics, 586; global warming, 294; grasslands, 62 Dry tropical biomes, 586 Dual-process habituationsensitization theory, 320 Dubautia (silversword), 14 Duetting, 98 Dupes (mimicry), 415
Dusky seaside sparrows, 203 Dust Bowl (1930’s), 213, 617 Dutch elm disease, 355 Dwarfing, 62 Eagles; bald, 199; golden, 157 Earth Day (est. 1970), 181 Earth First!, 123 Earth Summit (1992), 312 Echinoderms, 397 Echolocation, 157 Ecocentrism, 123 Ecoenergetics. See Biomass; Energy budgets; Energy flow; Food chain; Trophic levels; Categorized Index Ecofeminism, 124 Ecological isolation, 359 Ecological niches. See Niches; Trophic levels Ecological pyramids, 186 Ecological Society of America, 180 Ecology; defined, 171, 178; history, 179, 183 Economy of Nature, The (Linnaeus), 29, 179 Ecophysiology. See Categorized Index, Physiological ecology Ecosystem diversity, 34 Ecosystem ecology; defined, 174. See Biomes; Communities; Ecosystems; Categorized Index Ecosystems, 32; agricultural, 352; coining of term, 255; and communities, 100, 103; definition and history of the concept, 184, 190; and habitats, 314; invasive plants, 41; and pollution, 500; impact of species loss, 197; studies, 191, 195. See also Alpine tundra; 749
Subject Index Arctic tundra; Biomes; Boreal forests; Chapparal; Deciduous tropical forests; Deserts; Ecotones; Forests; Grasslands; Lake ecosystems; Marine biomes; Mediterranean scrub; Mountain ecosystems; Oldgrowth forests; Prairies; Rain forests Ecotones, 105, 631; tundra-forest, 656; wetlands, 672 Ecotoxicology. See Biomagnification; Pollution; Pesticides; Categorized Index Ectomycorrhizae, 102, 426 Ectoparasites, 624 Ectotherms, 172 Edge habitat, 375 El Capitan reef complex, 568 El Niño, 591 Elapids, 487 Eldredge, Niles, 544 Elephant birds, 200 Elephant grass, 586 Elephant seals, territoriality, 637 Elfin forest, 76 Elicitors, 103 Elm trees, 356 Elton, Charles, 185, 255, 641 Elton’s pyramid, 185, 256 Embryology, 162 Emergent layer (rain forests), 552, 558 Emigration, 508, 528 Empedocles, 236 Endangered species; animals, 196, 204; and ecological niches, 647; inbreeding of, 439; plants, 205, 210 Endangered Species Act (1973), 200, 503, 610 750
Endangered Species Act (1990), 454 Endangered Species Preservation Act (1966), 200, 610 Endemics (desert plants), 156 Endogenic chemical precipitates, 366 Endomycorrhizae, 426 Endotherms, 172 Endothia parasitica (fungus), 65 Energy budgets, 172, 174, 430; carnivores vs. herbivores, 455; and population size, 186; and predation, 539 Energy conversion, 642 Energy expenditure and the food chain, 256 Energy flow, 104, 177, 191; and biomass, 50, 54 English ivy, 41 Ephemerals, 157 Epidemiology, 177 Epilimnion, 367 Epipelagic marine zone, 391 Epiphytes, 102; endangered, 208 Episodic migrations, 410 Epizoites, 622 Equilibrium, and natural selection, 428 Equilibrium models of population dynamics, 517 Ericoid mycorrhizae, 426 Erosion, 211, 214; deserts, 62; firecaused, 259; overgrazing, 306; reforestation, 574; slash-andburn agriculture, 591; soil, 150 Erosion control, 213 Essentialism, 237 Estrogens, environmental, 503 Estuaries, 100, 316, 391; algae in, 482, 592; tidal, 105
Subject Index Ethograms, 219 Ethological isolation, 358 Ethology, 215, 221. See also Behavioral ecology Eucalyptus, 59, 271 Euphorbs, 120, 492 Eusocial colonies, 385 Eutrophication, 222, 226, 483, 601; cultural, 211; lakes, 225, 371. See also Phytoplankton Evaporation, 338 Evapotranspiration, 338 Evenness of species, 33 Everglades (Florida), 206, 504 Evergreens, 59, 630. See also Coniferous forests; Conifers Evolution, 227, 235; adaptations, 7; and altruism, 19; coevolution, 86, 89; convergent, 120, 122; and development, 161, 166; divergent, 120, 122; history of its study, 236, 240; isolating mechanisms, 358, 363; natural selection, 428; of plants, 241, 245; puncutated equilibrium vs. gradualism, 543, 548; and speciation, 605. See also Colonization of the land; Selection Evolutionary ecology. See Evolution; Categorized Index Evolutionary explosions, 246, 254 Exhaustible resources, 618 Exotic species, 40, 110, 177, 648, 662; and species loss, 196 Experimental ecology, 175 Explosions, evolutionary, 249 Exponential population growth, 531 Expression of the Emotions of Man and Animals (Darwin), 215
Extinctions, 35, 109, 232, 246, 254, 518, 608, 611; causes, 513; role of competition, 179; and endangered species, 196; caused by exotics, 177; inbreeding depression, 282; and invasive species, 40; mass, 244, 246; passenger pigeons, 198; plants, 241, 245; and pollution, 500; and punctuated equilibrium, 544. See also Species loss Exxon Valdez oil spill, 446 Falcons, 199 Fallow land, 590 Family units, mammalian. See Mammalian social systems FAO. See United Nations Food and Agriculture Organization Fecundity, 140 Feldspars, 594 Ferguson, Charles, 146 Ferns, 241 Ferrets; black-footed, 203, 300; and prairie dogs, 109 Fertilization, failure, 360 Fertilizers, as soil contaminants, 601 File, Sandra, 323 Finches, adaptations of, 13. See also Darwin’s finches Fire ants, 345 Fire climax ecosystems, 258, 399 Fire management, 400 Fire suppression, 260, 400 Fire worms, 45 Fireflies, 45, 96 Fires; chaparral, 78, 399; Devonian period, 93; forest, 258, 262, 267, 588, 631; in grasslands, 298; 751
Subject Index nutrient loss from, 442; slashand-burn agriculture, 591 Firs, 629 Fish, 394; bioluminescent, 43; clown, 624; defense mechanisms, 125; eutrophic environments, 224; herbivores, 328; omnivorous, 456; poisonous, 488; and pollution, 504 Fish and Wildlife Service, U.S., 196, 610, 677 Fish lice, 622 Fisher, R. A., 522 Fitness, 7; inclusive, 218; natural selection, 428; and reproductive strategies, 577 Fitness variation, 281 Fixation, genetic, 282 Flavonoids, 15 Flavr Savr tomato, 284 Flooding, 135; tolerance of, 672 Food chain, 47, 52, 104, 185, 255, 257, 612; grasslands, 299; and herbivores, 328; and phytoplankton, 482 Food pyramid (Elton’s), 641 Food webs, 53, 104, 174, 185, 255, 257, 612; and predation, 539 Foods, genetic modification of, 284, 287 Forbes, Stephen A., 29, 184, 189, 255 Forel, François A., 182 Forest fires, 258, 262, 267, 588, 631 Forest Service, U.S., 265, 454, 677 Forest zones, 551 Forestry; multiple-use approach, 422, 424; sustainable, 572 Forests, 269, 273; boreal, 60, 629, 632; coniferous, 314; deciduous, 314; Douglas fir, 109; as 752
ecosystems, 557; management, 263, 268, 422, 424; multiple use, 422, 424; nutrient cycles in, 442; old-growth, 452, 454; rain forests, 549, 553; temperate, 5859; tropical, 59 Fossil fuels, 501; global warming, 295; greenhouse effect, 310; tundra deposits, 657 Fossil record, 90, 232, 465, 546; and theories of evolution, 250 Founder effects, 437 Foxes, 300, 665; defense mechanisms, 126; social organization, 389 Fragmentation, 374 Franklin, Jerry, 452 Freshwater lakes, 315 Freshwater wetlands, 673 Fringing reefs, 564 Frisch, Karl von, 215, 345, 348 Fritts, Harold, 147 Frogs; bullfrogs, 158; clines, 81; poisonous, 489 Fugitive species, 537 Functional response of predators, 537 Fundamentals of Ecology (Odum), 191 Fungal associations, 425, 427 Fungal diseases, 65, 355 Fungi; as biopesticides, 66; lichens, 381; soil generation, 596 Fungicides, 470 Fungus gnats, 44 Fur industry and species loss, 199 Fynbos vegetation, 400 Gaboon vipers, 488 Gaia hypothesis, 30, 123 Galápagos Islands, 121, 238
Subject Index Game management, 677 Game theory, 639 Garstang, Walter, 163 Geese; hierarchies, 331; imprinting, 216; snow, 435 Gene flow, 80, 274, 277, 281; impact of corridors, 378; and landscape fragmentation, 375 Gene pools, 274, 576; defined, 229; and habitats, 313 Genes, 274; regulatory, 164 Genetic diversity, 35, 278 Genetic drift, 281, 283, 428, 435436, 439, 522, 604; and population fluctuations, 518 Genetic engineering, 433. See also Genetic modification Genetic hitchhiking, 281 Genetic modification, food crops, 284, 287 Genetic pollution, 286 Genetics; behavioral, 217; and evolution, 228; Mendelian, 162, 239; populations, 520, 527 Genotypes, 521 Geochemical cycles, 288, 291. See also Carbon cycle; Hydrologic cycle; Nitrogen Cycle; Nutrient cycles; Oxygen cycle; Phosphorus cycle Geoffroyism, 237 Geographic speciation, 604 Gestation, and reproductive strategies, 576 Gila monsters, 486 Gill slits, 162 Glaciers, 295, 310 Glassfish, 623 Gleason, Henry A., 30, 182 Global ecology. See Categorized Index
Global ReLeaf program, 575 Global warming, 292, 297, 309, 504, 574; role of slash-and-burn agriculture, 591; and taiga, 631 Globigerina shells, 465 Gloger’s rule, 81 Glowworms, 44 Glycosides, 491 Golden eagles, 157 Goldschmidt, Richard, 165 Golley, Frank B., 192 Gondwanaland, 247 Goodall, Jane, 324 Goosefoot family, 157 Gould, Stephen Jay, 163, 544 Governing Nature (Linnaeus), 29 Graded displays, 96 Gradualism, 231, 543, 548 Grand Canyon National Park and Game Preserve, Arizona, 301 Grass, elephant, 586 Grass frogs, 81 Grasslands, 57, 62, 149, 298, 303, 314 Grasslands management, 301 Grasslands Project, 192 Graunt, John, 28 Gravitropism, 651 Grazing, 304, 307, 560; forests, 265; effect on grasses, 304; symbiotic characteristics, 299 Great Barrier Reef, 564 Great Basin Desert, 156 Great Lakes, North America, 504 Greenhouse effect, 54, 292, 308, 312; rain forests, 557 Greenhouse gases, 152, 292, 671; and deforestation, 135 Grinnel, Joseph, 641 Grooming, 95 Gross production, 51, 172 753
Subject Index Ground fires, 268 Groundwater, 338, 668 Groundwater pollution, 668 Group dynamics, 18 Group selection, 431 Groups; and cooperation, 346; urban and suburban wildlife, 661 Grouse, competition among, 114 Growth, differential, 650 Growth rates (population analysis), 530 Growth rings. See Dendrochronology Guam rails, 203 Gully erosion, 212 Gymnosperms, evolution of, 241 Gypsy moths, 41, 65 Habitat destruction. See Habitat loss Habitat isolation, 359 Habitat loss, 177, 196, 376, 647; deserts, 159; environmental change, 252; Madagascar, 200; mountains, 420; plant species, 205; through pollution, 500; and population fluctuations, 518; rain forests, 552; wetlands, 675; and wildlife management, 678 Habitats, 313, 318, 659; demographics of, 137; and ethology, 216; landscape ecology, 374, 380; management, 677; marine, 391; protective, 127; and territoriality, 633 Habituation, 319, 325 Hadalpelagic marine zone, 392 Haeckel, Ernst, 161, 179 Hairston, Nelson G., 255 Haldane, J. B. S., 522 754
Hale, Matthew, 28 Hamilton, William D., 349 Hanford Nuclear Reservation, 670 Haplodiploidy, 344 Hardin, Garrett, 302 Hardwoods, 270 Hardy-Weinberg law, 435, 521, 525 Harrison, Benjamin, 422 Hartig nets, 427 Harvesting and nutrient loss, 442 Hatchetfish, 45 Haustoria, 382 Hawaiian silversword alliance, 13 Hawks, 665 Hazardous waste, 667 Heat islands, 296 Heavy metals, 48 Hedera helix (English ivy), 41 Heliotropism, 653 Hemotoxins, 486 Herbicides, 285, 470-471; invasive plant control, 355 Herbivores, 102, 111, 174, 256, 304, 326, 328, 455, 641; as parasites, 174; as pollinators, 86; rangeland animals, 561 Herbivory, 490 Herd behavior, 388 Heredity, laws of, 228 Hermit crabs, 624; defense mechanisms, 125 Heterobasidion annosum (pine pathogen), 67 Heterochrony, 162 Heterogeneity. See Biodiversity Heterotrophs, 52, 86, 111. See also Consumers Heterozygote genotypes, 435 HFCs. See Hydrofluorocarbons Hibernation, 9, 412; desert animals, 158
Subject Index Hierarchies, 19, 329, 332; and territoriality, 637 High-grading, 132 History of ecology, 171, 178; ecosystems, 184, 190 History of evolutionary theory, 227, 235 Hitchhiking, genetic, 281 Homeostasis, 346 Homeotherms, 10 Homing pigeons, 407 Homozygotes, 522 Honest signaling, 167 Hooke, Robert, 28 Hookworms, 625 Hormones; auxins, 650; pheromones, 476, 481 Horses, 301 Horsetails, 241 Host species, 622 Hubbard Brook project, 188, 193, 442 Human ecological impacts, 176 Human population growth, 257, 272, 333, 337, 375; fire suppression, 401 Humboldt, Alexander von, 181 Hummingbirds, Costa’s, 158 Humphrey, G., 322 Hunting, species loss, 196; predation, 389, 539. See also Poaching Hurricane Mitch (1998), 592 Huxley, J. S., 165 Hybrid sterility, 360 Hybrid swarms, 83, 359 Hybrid zones, 80, 85, 275, 604 Hybridization, 275 Hydrofluorocarbons, 308 Hydrologic cycle, 69, 338, 342 Hydrophytes, 672
Hydrosphere, 69 Hydrotropism, 653 Hymenoptera (ants, bees, wasps), 19, 343 Hyperarid climates, 150 Hyperresponsiveness, 321 Hypolimnion, 368 Hypoxia in eutrophic environments, 223 IBP. See International Biological Program Ice ages, 295, 310 Ice-rafting, 366 Iguanas, 158 Immigration, 508, 528 Immutability of species, 236 Imprinting, 216 Inbreeding, 274, 436, 522, 605 Inbreeding depression, 282, 495 Incineration, 669 Inclusive fitness, 218 Indicator species, 155 Industrial Revolution, 1 Infiltration capacity of soil, 340 Inhibition and habituation, 322 Innovation and evolutionary explosions, 252 Inquilinism, 623 Insect communication, 345 Insect societies, 95, 343, 350 Insecticides, 470 Insects; as biopesticides, 67; herbivorous, 326; invasive, 41; omnivorous, 456; pheromones, 478; poisonous, 487; pollinators, 496; stink bugs, 126; symbioses with plants, 326 Instinctive behavior, 217 Integrated pest management, 351 Interbreeding, 358, 543, 604 755
Subject Index Interception (hydrologic cycle), 339 Intergenerational justice, 618 Internal nutrient cycling, 440 International Biological Program, 180, 192 International Council for Bird Preservation, 196 International Panel on Climate Change, 311 International Union for Conservation of Nature and Natural Resources. See World Conservation Union Interspecific competition, 113 Intersterility, 360 Intertidal marine zone, 63, 391 Intraspecific competition, 113, 645 Intrinsic rate of increase, 530 Introduced and exotic species, 583 Introgression, 80, 85, 275 Introgressive demes, 83 Introgressive hybridization, 275 Invasive plants, 354, 357 Invasive species. See Biological invasions; Invasive plants IPCC. See International Panel on Climate Change IPM. See Integrated pest management Iridium, as a cause of extinction, 247 Island biogeography, 33, 38 Isoflavones, 405 Isolating mechanisms, 83, 358, 363; mountains, 419 Isoptera (termites), 343 Isotherms, 61 Iteroparous species, 579 756
IUCN. See World Conservation Union Ixtoc I, 446 Jackrabbits, 158 Jacobson’s organ, and pheromones, 478 Jellyfish, 45; defense mechanisms, 130 Johnson, Roswell, 641 Jurassic period, 243 Juvenile survivorship patterns, 139 K strategy, 81, 578 K/T boundary. See CretaceousTertiary (KT) event Kaibab Plateau (Arizona) deer disaster, 301 Kairomones, 477 Kandell, E. R., 321, 323 Kaufman, Thomas, 163 Kestrels, American, 665 Keystone predators, 106 Keystone species, 104, 647; and predation, 539 Kidneys of desert animals, 159 Killer algae, 357 Kimura, Motoo, 523 Kin selection, 20, 218, 344, 431, 522 King Solomon’s Ring (Lorenz), 216 Krebs, Charles, 111 Krummholz region, 656 Kudzu, 41 Kyoto Accords (1997), 312 “Lake as a Microcosm, The” (Forbes), 29 Lake ecosystems, 185, 315, 364, 373; pollution effects, 189
Subject Index Lake Tahoe, eutrophication in, 222 LaMarche, Valmore, 146 Lamarck, Jean-Baptiste, 29, 179, 227, 236 Land management, 422, 424 Landfills, 668 Landscape ecology, 374, 380 Landscape fragmentation, 374 Lantern fish, 45 Laterization, 572 Layering, 630 Leaching, 441, 601 Leafy spurge, 356 Learning; and ethology, 216; habituation, 319 Lechuguilla, 156 Leeuwenhoek, Antoni van, 28 Leks, 114, 167 Lemmings, 514 Lemurs, 200, 552 Lentic communities, 315 Leonardo da Vinci, 145 Leopard frogs, 82 Leopold, Aldo, 677 Lice, 622 Lichens, 381, 384; soil generation, 596 Life cycles, 513 Life spans, 138; urban and suburban wildlife, 661 Life tables, 143 Lignin, 405 Likens, Gene E., 193 Limnology, 182, 364, 373 Lindeman, Raymond L., 186, 191 Linnaeus, Carolus, 29, 179, 236 Lions, competition among, 114 Lithosphere, 69 Litter size, 576 Littoral lake zone, 371
Lizards, 486; black-collared, 158 Locusts, population fluctuations, 515 Logging; deforestation, 132; national forests, 265; oldgrowth forests, 453; reforestation, 572 Logistic population growth, 531, 577 Longevity, 142 Lorenz, Konrad, 215 Lotic communities, 315 Lotka, A. J., 115 Lotka-Volterra model, 541 Love Canal, 670 Lovelock, James, 30 Luciferin and luciferase, 43 Lucretius, 236 Lycopene, 405 Lycophytes, 241 Lyell, Charles, 29, 179, 238 Lynxes, 514 Lysimeters, 597 Macaque hierarchies, 331 MacArthur, Robert H., 38, 115, 578 Macrohabitats, 313 Macrotermes natalensis (termites), 347 Madagascar, species loss on, 200 Mallee vegetation, 400 Mammalian social systems, 385, 390; hierarchies, 332 Mammals, omnivorous, 456 Mangroves, 674 Man-o’-war, 393 Maquis vegetation, 400 Marbled murrelets, 109 Marcus, Emilie A., 322 Margulis, Lynn, 30 757
Subject Index Marine biomes, 316, 391, 398; phytoplankton, 483. See also Ocean biomes Marine ecology, 182 Marine regression and extinctions, 246 Marine zones, 391 Mark-recapture methods, 109, 116, 516, 533 Marker pheromones, 476 Marshes, 391, 674 Mathematical ecology, 176 Mathematical models; and natural selection, 432; population genetics, 524; population growth, 529; predation, 541; predator-prey relationships, 513 Mating; calls, 359; hybrids, 83; pheromones, 477; systems, 577. See also Reproduction Matorral vegetation, 400 Maupertuis, Pierre-Louis Moreau de, 236 Maximal intrinsic rate of increase, 530 Mayr, Ernst, 543 Mech, David, 517 Mechanical isolation, 359 Meckel, J. F., 161 Medicinal plants; alkaloids, 404; endangered, 209 Mediterranean scrub, 62, 399, 401 Mendel, Gregor, 229, 239 Mendelian genetics, 521 Mercury poisoning, 48 Mesopelagic marine zone, 391 Mesotrophic lakes, 225 Mesozoic era, 243 Metabolic adaptations, 9 Metabolic pathways, 402 758
Metabolism, desert animals, 159 Metabolites, 25, 126-127, 402, 406; coevolution of, 88; secondary, 490. See also Poisonous animals; Poisonous plants Methane, 668; and global warming, 295, 310 Methuselah Tree, 146 Mice, 665 Microcosms, 185 Microhabitats, 313 Migration, 12, 274, 407, 414, 428; and hybrid swarms, 83; invasive species, 40; mammalian social organization, 388; and predation, 537 Migrations, birds, 514 Milkweed plant, 538 Milpa agriculture. See Slash-andburn agriculture Mimicry, 25, 73, 97, 128, 415, 418; aggressive, 538; Batesian, 128, 538; fireflies, 45; Müllerian, 128, 538 Mineralization, 441 Miocene epoch, 244 Missing links, 236 Mistletoe, 102 Möbius, Karl, 182 Models (mimicry), 415 Mollusks, 397 Monimolimnion, 372 Monkeys; communication, 98; hierarchies, 331; social systems, 386 Monoclimax theory, 615 Monoculture, 264, 306 Monogamy, 577 Monotropoid mycorrhizae, 426 Morphine, 404
Subject Index Mortality rates. See Death rates Mother-young relationships, 385 Moths; peppered, 428; pheromones, 478; as pollinators, 497 Mount Tamalpais, California, 78 Mountain ecosystems, 419, 421 Mountain lions, 385 Mousse (oil spill), 444 Müllerian mimicry, 128, 416, 538 Multiple-use approach, 422, 424 Multiple Use-Sustained Yield Act (1960), 423 Murrelets, marbled, 109 Musk, 127 Mutagens, 438 Mutational meltdown, 283 Mutations, 229, 274, 428, 435, 439, 520; and divergence, 12; and natural selection, 7; random, 239 Mutualisms, 24, 87, 100; and coevolution, 174; pollinators, 495; distinguished from symbiosis, 623. See also Symbioses Mycobionts, 381, 425 Mycorrhizae, 101, 425, 427; in oldgrowth forests, 453 Naess, Arne, 123 NASA. See National Aeronautics and Space Administration Natality rate, 138 National Aeronautics and Space Administration, 461 National Environmental Protection Act (1970), 677 National Oceanic and Atmospheric Administration, 449, 460
National Park Service, U.S., 677 National Wildlife Federation, 678 National Wildlife Refuge System, 200 Native plants, 40 Natural selection. See Selection; Selection regimes; Sexual selection Nature preserves, 33. See also Parks; Wildlife refuges; Zoos Navigation, 407 Nectar, 496 Negative assortative mating, 435 Nekton, 393 Nematocides, 470 Nematocysts, 129 Neoteny, 163 Neritic marine zone, 63, 391 Nested hierarchies, 330 Nesting; social insects, 346; territoriality, 635 Net production, 51, 172 Neurobiology, 216 Neurotoxins, 486 Neurotransmitters and habituation, 321 Neutral mutation, 524 Neutralisms, 100 New forestry, 268 Niche generalizations, 645 Niche overlap, 644 Niches, 13, 419, 641, 649; and competition, 113; competition for, 115; defined, 171; and hybridization, 83 Nicotine, 404 Nightshade family, 404 Nimbus meteorological satellites, 461 NIMBY (not in my backyard), 669 759
Subject Index Nitric oxides, 501 Nitrogen, excessive, 222 Nitrogen cycle, 185, 289, 441-442 “No net loss” policy, 584 NOAA. See National Oceanic and Atmospheric Administration Nocturnal animals, 26, 158, 315, 359, 488, 663 Nolen, Thomas G., 322 Nomadic animals, 407 Nonbranching evolution, 228 Nongeographic speciation, 605 Nonrandom mating, 435, 439 Nonsymbiotic mutualism, 25 North American biomes, 314 North American prairies, 299 North American taiga, 629, 632 North American Wetlands Conservation Act (1989), 675 North American Wetlands Conservation Reauthorization Act (2002), 675 Noss, Reed F., 34 Nuclear and radioactive waste, 669 Nuclear weapons, 669 Numerical response of predators, 536 Nutrient cycles, 185, 440, 443; soil generation, 596. See also Geochemical cycles Nutrients, excess, 222, 226 Oak Ridge National Laboratory, 180, 188 Ocean biomes, 63, 391. See also Marine biomes Ocean pollution, 444, 451 Oceanic marine zone, 391 Octopuses, mimicry in, 417 Odum, Eugene P., 191 760
Offspring care; altruism, 19-20; camouflage, 74; territoriality, 635 Oil deposits (tundra), 657 Oil spills, 444, 451 Old-growth forests, 133, 265, 452, 454 Olfactory displays, 169 Oligotrophic lakes, 225 Omnivores, 112, 257, 455-456 On the Origin of Species by Means of Natural Selection (Darwin), 29, 179, 215, 238, 274 Ontogeny, 161 Operation Desert Storm, 449 Operators (mimicry), 415 Opossums, 665 Optimality theory, 639 Opuntia (prickly pear cactus), 120 Orchidaceous mycorrhizae, 426 Orchids; endangered, 208; pollination, 498 Ordovician period, 90 Organismal ecology, defined, 171 Organophosphates, 471 Orians, G. H., 115 Orientation response, 321 Ornithischians, 158 Outcrossing, 286 Overcultivation, 150 Overgrazing, 150, 300, 304, 307, 336, 561; southern Africa, 207 Overland flow, 340 Ovulation, 577 Owls; barn, 665; screech, 665; short-eared, 662; snowy, 662; spotted, 109, 203, 453 Oxygen cycle, 288; rain forests, 555 Oxygen depletion, eutrophic environments, 223
Subject Index Ozone, 556 Ozone depletion, 310, 457, 463, 501 Ozone hole. See Ozone depletion Pack structure (dogs), 389 Paclitaxel, 404 Pair-bonding displays, 168 Paleobotany, evolutionary theories, 543, 548 Paleodiversity, 251 Paleoecology, 37, 464, 469; methods, 188 Paleogene-Neogene period, 244 Paleontology, 232, 543 Paleozoic era, 241 Paley, William, 237 Palos Verdes butterflies, 203 Pampas, South American, 298 Parapatric speciation, 604 Parasites; cowbird, 377; edge species, 377; and predation, 536 ; zooplankton, 393 Parasitism, 87, 125, 174, 621, 624 Parks, 379. See also Nature preserves; Wildlife refuges; Zoos Particulate pollutants, 591 Passenger pigeons, extinction of, 198 Patch reefs, 565 Patches of habitat, 375 Pathogens, 102 Pavlov, Ivan, 322 PCBs, 48, 504, 601 Pearl, Raymond, 139 Pearlfish, 623; sea cucumber associations, 129 Peat, 242 Pecking orders, 113, 331 Pelagial lake zone, 371
Pelagic marine zone, 391 Pelicans, 203 Peniophora gigantea (biopesticide), 67 Peppered moth, 428 Peppered moth adaptations, 10 Per capita rate of growth, 530 Per capita rate of increase, 509-510 Per capita rates, 509 Perception, variations among organisms, 215 Peregrine falcons, 199 Pereskia (cactus), 120 Perfluourocarbons, 308 Permafrost, 61, 629, 655 Permian-Triassic extinction, 242, 252 Persian Gulf, 450 Pest control; pheromones, 478; and pollution, 503 Pesticides, 470, 475; biomagnification of, 47; biopesticides, 65, 68; integrated pest management, 351; resistance to, 351; species loss, 199. See also DDT Petroleum, origins, 234 PFCs. See Perfluourocarbons Phenolics, 15, 405 Phenotypes, 435 Pheromones, 95, 170, 220, 476, 481; mating behavior, 359; social insects, 345 Philodendrons, 491 Philosophical Account of the Works of Nature, A (Bradley), 28 Phoresis, 622 Phosphate runoff, 225 Phosphates, 222 Phosphorus, excessive, 222 Phosphorus cycle, 290 761
Subject Index Photic marine zone, 391, 483 Photinus (firefly), 45 Photobionts, 381; in lichens, 382 Photodissociation, 555 Photophores, 43 Photosynthesis, 50, 69, 104; CAM and C4 , 156; as an oxygen source, 556; as primary productivity, 187 Phototropism, 650 Photuris (firefly), 45 Phylogeny, 161 Physiological adaptations, 9 Physiological ecology. See Categorized Index Phytoalexins, 103 Phytochemicals, 490 Phytoecdysones, 405 Phytoplankton, 392, 482, 485; eutrophic environments, 223. See also Eutrophication Pianka, Eric, 578 Pied wagtails, 636 Pigeons; migration, 407; passenger, 198; urban, 661 Pigments, 405 Pinchot, Gifford, 422 Pine family, 629 Pinnipeds, 396 Plankton, 63, 392; migrations, 409. See also Phytoplankton; Zooplankton Plant-animal interactions. See Animal-plant interactions Plant ecology, 181 Plant Quarantine Act (1912), 356 Plant Succession (Clements), 30 Plants, land vs. sea, 91 Plate tectonics, 419 Poaching, 678. See also Endangered species; Hunting 762
Point-quarter technique, 117 Poison ivy, 493 Poison oak, 493 Poison sumac, 493 Poisonous animals, 486, 489 Poisonous plants, 490, 494 Polar bears, 13 Pollen, 367, 495-496; ancient, 464 Pollination, 10, 101, 495, 499 Pollinators, 26; coevolution of, 86 Pollinia, 498 Pollution; and ecosystems, 189; effects, 500, 506; eutrophication, 222, 226; oceans, 444, 451; soil, 601, 603; and urban and suburban wildlife, 659; and wildlife management, 678 Polychaete worms, 397 Polychlorinated biphenyls. See PCBs Polyclimax theory, 615 Polyculture, 264 Polygamy, 577 Polyploidy, 605 Polyterpenes, 405 Population analysis, 117, 507, 512; demographics, 137; and wildlife management, 678 Population ecology, 172, 317. See also Population analysis; Categorized Index Population fluctuations, 513, 519; and pollution, 501; and predation, 539 Population genetics, 435, 520, 527 Population growth, 138, 172, 528, 535, 577; human, 333, 337 Population regulation, 173, 176 Population size, and genetic drift, 436
Subject Index Populations; and habitats, 313; human, 257, 272, 401 Porcupine defense mechanisms, 125 Positive assortative mating, 435 Post-extinction recoveries, 249 Postmating isolation, 359 Prairie dogs, 300; and ferrets, 109; social organization, 388 Prairie potholes, 673 Prairies, 298, 303; North American, 298, 315 Precipitation, 339; global warming, 294 Predation, 88, 106, 125, 536, 542; balance of nature concept, 255; and bioluminenscence, 44; and camouflage, 74; mammalian social systems, 387; marine animals, 395; mimicry in, 415; relative rarity, 186; and urban and suburban wildlife, 664; venoms, 486; wasps, 344. See also Predator-prey relationships Predator-prey relationships, 25, 174, 609, 621; and population fluctuations, 514. See also Predation Premating isolation, 358 Prescribed burns, 260 Preserves, 379 Prickly pear cactus, 120, 156 Primary producers. See Producers Primary productivity. See Productivity Primary succession, 613 Primates; behavior, 216; social systems, 386 Primer pheromones, 95, 476 Producers, 24, 50, 104, 111, 174, 187, 191, 482, 557, 561, 641. See also Autotrophs
Production biology, 256 Productivity (rate of accumulation of biomass), 50, 187 Profundal lake zone, 371 Programmed migrations, 409 Progymnosperms, 242 Prometheus Tree, 147 Protective species, 128 Protozoa as biopesticides, 67 Psittocosis, 665 Psychology, comparative, 216 Pterophyta (ferns), 241 Pueraria lobata (kudzu), 41 Puff adders, 488 Punctuated equilibrium, 231, 543, 548 Purple loosestrife, 356 Pyramid, Elton’s, 185, 256 Pyrethrins, 67 Quadrat method, 516 Quaternary period, 245 Quiet Crisis, The (Udall), 422 Quills, 125 Quinine, 404 Quinone, 127 r strategy, 81, 578 Rabbits; Australian, 431; as exotics, 110; hierarchies, 331 Raccoons, 665; defense mechanisms, 126 Radioactive fallout, 188 Radiocarbon dating, 146 Raff, Rudolf, 163 Rails, 203 Rain forests, 57, 59, 263, 549, 553; atmospheric interactions, 177, 554, 559; Cenozoic, 244; destruction rates, 336; ecosystems, 557; evolution of, 763
Subject Index 242; slash-and-burn agriculture, 590; subtropical, 314; temperate, 58, 549, 557, 629; tropical, 52, 55, 102, 131, 203, 263, 269, 549, 557, 574, 615. See also Tropics Rain-shadow effect, 154 Rainbow trout, 313 Rangeland, 560, 563 Ranges of species, 313 Rank distinctions, 330 Rankin, Catherine H., 322 Rats, 665; social organization, 385 Rattlesnakes, 158, 487 Ravens, 157 Ray, John, 28 Recapitulation, 161 Reciprocal sacrifice, 20 Reciprocal signaling, 167 Recombinant DNA technology, 284 Recycling, 175, 668 Red Data Book (IUCN), 202 Red-tailed hawks, 663 Red tides, 224, 483. See also Algal blooms; Brown tides; Eutrophication; Phytoplankton Red tree voles, 109 Red wolves, 116 Reefs, 564, 571; protective habitats, 127 Reforestation, 264, 572, 575 Regeneration; defense mechanisms, 129 Releaser pheromones, 476 Remoras, 623 Repellant pheromones, 476 Reproduction; asexual, 282, 524, 605; demography of, 140; isolating mechanims, 358, 363; lichens, 383; migration, 409; 764
patterns, 140; pheromones, 478; and population growth, 529; sexual, 604; strategies, 171, 435, 439, 576, 582; and terrioriality, 636-637 Reservoirs, 365 Residence time (hydrologic cycle), 341 Resilience in ecosystems, 108 Resistance, predicted by population genetics, 526 Resistance to ecosystem disturbance, 108 Resistance to pesticides, 472 Resources, exhaustible, 618 Respiration, 70, 172, 187, 441, 554 Restoration ecology, 583, 585; endangered species, 203; eutrophicatication, 225; tundra biomes, 657. See also Categorized Index Retardation, 163 Reticular network (vertebrates), 321 Rhesus monkey hierarchies, 331 Rhyniophytes (early land plants), 92, 241 Ricin, 492 Rill erosion, 211 Riparian (river) ecosystems, 301 River ecosystems. See Riparian ecosystems rmax , 530 Rocky Mountain National Park, Colorado, 420 Rodenticides, 470 Rodents; behavior, 216; as pollinators, 497; social organizations, 388 Roosevelt, Theodore, 423 Rubber, 405
Subject Index Rubber trees, 552 Rudist reefs, 568 Ruminants, 305, 327, 455 Runoff; agricultural, 213; as a pollutant, 601 Rusts, white pine blister, 41 Sacrifice, reciprocal, 20 Sagebrush, 156 Saguaro cactus, 156 Sahara Desert, 156, 207 Sahel Desert, 150 Saint-Hilaire, Étienne Geoffroy, 237 Salicylic acid, 405 Salt marshes, 674 Saltation (wind erosion), 212 Saltwater wetlands, 673 Sampling effect, 436 Santa Ana winds, 399 Saprotrophs, 112 Saurischians, 158 Savannas, 58, 62, 298, 586, 589 Scale of being, 161, 236 Scavengers, 344, 455, 641; urban, 661 Schistosomes, 625 Schulman, Edmund, 146 Sclerophyllous forests, 587 Scorpaenidae (venemous fish), 489 Scorpions, 158, 487 Scrub. See Mediterranean scrub Sea anemones, 624 Sea cucumbers, evisceration, 129 Sea hares, 321 Sea levels, rising, 295 Sea turtle migration, 408 Sea urchins, 126 Seabirds, 394 Seals; elephant, 637; overhunting of, 199
Seasonal isolation, 359 Secondary metabolites, 25, 127 Secondary succession, 613 Sedimentation; lakes, 211, 365; storm drains, 259 Seed dispersal, coevolution of, 88 Seed germination and fire, 258, 400 Seedless vascular plants, 241 Selection (natural), 7, 12, 171, 217, 227, 238, 344, 428, 434, 521, 576; and altruism, 18; defense mechanisms, 125; and demes, 80; disruptive, 605; genetic drift, 281; isolating mechanisms, 358; sexual, 238, 430; species selection vs., 545 Selection regimes, 514 Selective harvesting, 132 Selective sweeps, 282 Self-pollination, 495 Selfish genes, 522 Semelparous species, 579 Semiarid climates, 149 Semigeographic speciation, 604 Semiochemicals, 476 Sense organs and camouflage, 75 Sensitization, 319, 325 Sequoias, 146 Seres, 612 Serotonin, 322 Serres, E. R., 161 Serres-Meckel law, 162 Sex and territoriality, 636 Sex ratios, 141, 508; population analysis, 511 Sexual reproduction, 172, 604 Sexual selection, 238, 430 Sheep, bighorn, 157 Sheet erosion, 211 Sheet flow, 341 765
Subject Index Shells, as defense mechanisms, 125 Shells, sea, 465 Sherrington, Charles, 323 Sickle-cell disease, 520 Sierra Club, 123, 678 Sierra Nevada, 77 Signal pheromones, 476 Silent Spring (Carson), 30, 193, 200 Silurian period, 90, 92 Silverswords, 13 Similarity (for community classification), 109 Single larger or several smaller (SLOSS) controversy, 33, 379 Siphonophores, 45 Skunks, 665; defense mechanisms, 127 Slash-and-burn agriculture, 264, 272, 590, 593; and deforestation, 132; global warming, 295; reforestation, 572 Sleep, 321 Slobodkin, Lawrence B., 255 SLOSS (single larger or several smaller) controversy, 33, 379 Sludge treatment and disposal, 669 Smell; displays, 169; and pheromones, 478 Smith, Frederick E., 255 Snags, 452 Snail darters, 202 Snakes, venomous, 487 Snow geese, 435 Snowpack, 341 Snowshoe hares, 514 Social Darwinism, 234 Social ecology, 124 Social systems; insects, 95, 343, 350; mammals, 385, 390 766
Society of American Foresters, 268 Sociobiology, 218 Softwoods, 270 Soil, 594, 600; contamination, 601, 603; degradation, 572; erosion, 211, 214, 591; nutrients in, 440; sampling, 597; sterilants, 471; in waste management, 600; wetlands, 672. See also Erosion; Soil chemistry Soil chemistry, 597 Soil conservation, 213 Soil Conservation Service, 677 Soil contamination, 131 Sokolov, E. N., 320, 322 Solar radiation, 69; greenhouse effect, 308 Solar tracking, 653 Solenopsis saevissima (fire ants), 345 Solid waste, 667 Sonoran Desert, 156 Source reduction, 670 South American dry forests, 588 Sparrows, dusky seaside, 203 Speciation, 239, 276, 604, 607; adaptive radiation, 12, 14; and isolating mechanisms, 362; punctuated equilibrium, 543, 548. See also Categorized Index Species; definitions, 228; formation, 543; population fluctuations, 513; and territoriality, 633 Species diversity, 32 Species loss, 376, 608, 611; animals, 196, 204; plants, 205, 210. See also Extinctions Species-removal studies, 609 Species selection, 545 Sphenophyta (horsetails), 241 Sphinctozoans, 568
Subject Index Spiders, 487 Spines (defense mechanisms), 126, 489 Splash erosion, 211 Spotted owls, 109, 203, 453 Springwood, 145 Spruce family, 629 Spurge family, 120 Squid, bioluminescence in, 43 Squirrels, 158 Stability thresholds, 110 Stabilizing selection, 429 Stagnation, 222 Stanley, Steven, 545 Starling, European, 662 Startle response, 319 Status signs, 167, 331 Steppes; Eurasian, 298; shortgrass, 57 Steroids, 405 Stimulant pheromones, 476 Stimulus; generalization, 320; response, 319 Stingrays, 488; defense mechanisms, 126 Stings, 129 Stink bugs, 126 Stonefish, 489 Stratigraphy, 467 Stromatolites, 465, 567 Stromatoporoids, 568 Structural adaptations, 9 Strychnine, 493 Study of Instinct, The (Tinbergen), 216 Substrate preferences of organisms, 316 Succession, 105, 173, 583, 612, 617; wildlife management, 678 Succulents; adaptations, 156; evolution of, 120
Sudbury, Ontario, emissions, 1 Sugars, 50 Sulfur dioxide, 501 Summerwood, 145 Sunflower family, 157 Superfund, 670 Supreme Court, U.S., 202 Surface fires, 267 Survivorship patterns, 138 Suspension (wind erosion), 213 Sustainable agriculture, 593 Sustainable development, 618, 620 Sustainable forestry, 264-265, 572 Sustained yield, 422 Swidden agriculture. See Slashand-burn agriculture Swifts, Vaux’s, 109 Switching, 537 Symbioses, 24, 87, 621, 628; and bioluminescence, 43; lichens, 381; mycorrhizal, 425, 427. See also Mutualisms Sympatric speciation, 605 Symphilism, 623 Systemic herbicides, 471 Tactile communication, 99 Tactile displays, 169 Taiga, 629, 632, 656 Tall-grass prairies, 560 Tannins, 15 Tansley, Arthur G., 186, 255 Tapeworms, 622 Taxus (yew), 492 Teakwood, 552 Tegitecula-yucca interaction, 24 Tellico Dam, Tennessee, 202 Temperate forests, 58-59, 269, 558 Temperature of Earth. See Global warming Temporal isolation, 359 767
Subject Index Tendrils, 652 Tennessee Valley Authority, 202 Termite-protozoan mutualisms, 174 Termites, 344; African, 347 Terns, arctic, 411 Terpenes, 15 Terpenoids, 404 Terracing, 213 Terrestrial communities, 173 Territoriality, 112, 633, 640; mammalian social organization, 388; mice, 117 Tetraterpenoids, 405 Thallus, lichens, 382 Thanatocoenoses, 466 Theophrastus, 15 Theory of Island Biogeography, The (MacArthur and Wilson), 578 Thermocline, 368 Thermoregulation in deserts, 158 Thienemann, August, 256 Thigmotropism, 652 Threat displays, 167 Threatened species, 196 Tillage practices, 213 Tillandsia (epiphyte), 102 Timber industry, 132; national forests, 265; old-growth forests, 452; reforestation, 572 Tinbergen, Nikolaas, 215 Toads, 158; poisonous, 489 Topsoil, 211, 214; erosion, 336, 574 Toxic chemicals, 47 Toxicodendron radicans (poison ivy), 493 Trace fossils, 467 Trail pheromones, 476 Transeau, Nelson, 256 Transgenics, 284 768
Transparency, 74 Transpiration, 338; and deforestation, 135 Transplant experiments, 116 Transport (water erosion), 211 Trebouxia (algae), 381 Tree farming, 572 Tree-of-heaven, 659 Tree rings. See Dendrochronology Trees; endangered, 552; and global warming, 574 Triassic period, 243 Trichoderma (biopesticide), 67 Trimerophytophyta (early land plants), 241 Triterpenoids, 405 Trophallaxis, 99, 345 Trophic levels, 104, 174, 187, 256, 562, 641, 649; and predation, 539 Tropical forests, 57, 59, 586, 589 Tropics, habitat loss, 177. See also Rain forests Tropisms, 650, 654 Trypanosomes, 625 Tundra, 56, 61, 314, 631, 655, 658 Turbidite deposits, 366 Turkeys, 158 Udall, Stewart, 422 Ultraviolet radiation, 457, 462, 501 Umbilicaria esculenta (lichen), 383 Understory (forests), 269, 551, 558 Ungulate social organization, 388 Uniformitarianism, 238 United Nations Environmental Program, 462 United Nations Food and Agriculture Organization, 133, 263
Subject Index Urbanization; global warming, 296; wildlife, 659, 666 Urushiol, 493 Vacant niche theory, 645 Van Dyne, George, 192 Variability in populations, 520 Varves, 372 Vascular tissues, 145, 241 Vaux’s swifts, 109 Vavilov, Nikolai I., 279 Vegetation corridors, 378 Venoms, 486 Verhulst, Pierre-François, 577 Vertical migrations, 409 Vervet monkeys, 98 Vesicular-arbuscular mycorrhizae, 102, 426 Vestiges of the Natural History of Creation (Chambers), 237 Vestigial organs, 228 Vicariance, 38 Vinblastine, 404 Vincristine, 404 Vipers, 487; Gaboon, 488 Viruses as biopesticides, 65 Visual displays, 167, 359 Vocalizations; birds, 97; and ethology, 220 Volcanic activity and extinctions, 247 Volcanoes, 364 Voles, red tree, 109 Volterra, V., 115 Vomeronasal organs, 478 Vries, Hugo de, 239 Vultures, 158 Wallace, Alfred Russel, 38, 238 Warblers, competition among, 115 Warm-blooded animals, 10
Warning coloration, 415 Wasps, 344; as pollinators, 498 Waste management, 667, 671; tundra biomes, 657 Wastewater drainage, 225 Water; circulation in lakes, 367; contamination, 501; in soil ecosystems, 597; wetlands, 672 Water column, 367, 393 Water pollination, 499 Water table, 341 Watersheds, 440 Way, M. J., 115 Weathering and soil generation, 594 Weeds, 356; allelopathy, 15 Wetlands, 391, 672, 676 Whales, overhunting of, 199 White, Gilbert, 98, 255 White pine blister rust, 41 Whittaker, R. H., 57 Whooping cranes, 203 Wildebeests, 388 Wildlife. See Endangered species; Wildlife management; Zoos Wildlife management, 143, 380, 512, 534, 677, 680; grasslands, 301; urban and suburban, 665 Wildlife preservation, 374 Wildlife refuges, 203, 609, 678. See also Nature preserves; Parks; Zoos Wildlife, urban and suburban, 659, 666 Wilson, Edward O., 38, 343, 578 Wind erosion, 212 Wind pollination, 498 Winter, global warming, 293 Wolves, 300; hierarchies, 331; social organization, 389 Worker ants, 343 769
Subject Index World Conservation Union, 196, 202 World Health Organization, 503 Worldwatch Institute, 505 Worms as symbionts, 621 Wright, Sewall, 522 Xylem, 145 Yaks, introgression of, 84 Yellowstone National Park, 316 Yews, 404; toxins, 492 Yucca, 156 Yucca Mountain, Nevada, repository, 670
770
Zebrafish, 489 Zoological Philosophy (Lamarck), 179 Zoology, ethology, 215 Zooplankton, 392, 483; eutrophic environments, 223; migrations, 409 Zoos, 203, 439, 681, 685. See also Nature preserves; Parks; Wildlife refuges Zosterophyllophyta (early land plants), 241 Zygotic inviability, 360