Synthesis and Characterization of Glycosides
Synthesis and Characterization of Glycosides
Marco Brito-Arias Biotechn...
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Synthesis and Characterization of Glycosides
Synthesis and Characterization of Glycosides
Marco Brito-Arias Biotechnology Unit National Polytechnic Institute of Mexico (UPIBI-IPN)
Marco Brito-Arias Biotechnology Unit National Polytechnic Institute, Mexico la Laguna Ticomˆa Mexico
Library of Congress Control Number: 2006927420 ISBN 10: 0-387-26251-2 ISBN 13: 978-0-387-26251-2 C 2007 Springer Science+Business Media, LLC All rights reserved. This work may not be translated or copied in whole or in part without the written permission of the publisher (Springer Science+Business Media, LLC, 233 Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with reviews or scholarly analysis. Use in connection with any form of information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed is forbidden. The use in this publication of trade names, trademarks, service marks, and similar terms, even if they are not identified as such, is not to be taken as an expression of opinion as to whether or not they are subject to proprietary rights.
9 8 7 6 5 4 3 2 1 springer.com
To Carmina Daniela
Contents
Preface ...................................................................................
xii
1. Glycosides, Synthesis, and Characterization ............................... 1.1. Introduction .................................................................. 1.2. Reactions of Monosaccharides ........................................... 1.3. Chemical Modifications ................................................... 1.3.1. Oxidations ........................................................... 1.3.2. Periodate Oxidation................................................ 1.3.3. Tollens Reaction .................................................... 1.3.4. Benedict and Fehling Test ........................................ 1.3.5. Nucleophilic Addition............................................. 1.3.6. Enediol Rearrangement ........................................... 1.3.7. KilianiFischer Synthesis .......................................... 1.3.8. The Ruff Degradation ............................................. 1.3.9. Conversion of Pentose to Furfural............................... 1.4. Biosynthesis of Sugars..................................................... 1.4.1. Sugars as Energy Sources......................................... 1.5. Synthesis of Carbohydrates ............................................... 1.5.1. Chemical Synthesis ................................................ 1.5.2. C-Glycosyl Amino Acids ......................................... 1.5.3. Enzymatic Synthesis............................................... 1.5.4. Chemoenzymatic Synthesis ...................................... 1.6. Synthesis of Carbohydrates Mimetics................................... 1.6.1. Iminosugars ......................................................... 1.6.2. Aminosugars ........................................................ 1.6.3. Thiopyranoside Monosaccharides............................... 1.6.4. Carbapyranoside-Saccharides.................................... 1.7. Glycoside Reactivity ....................................................... 1.8. The Leaving Groups........................................................ 1.9. Glycosyl Donors ............................................................ 1.10. Protecting Groups...........................................................
1 1 2 2 3 4 5 5 6 9 9 10 10 11 11 12 12 16 21 23 25 25 29 34 34 35 35 39 43
vii
viii
Contents
1.11. Selective Protections ....................................................... 1.12. Selective Deprotections.................................................... References ...........................................................................
52 59 63
2. O-Glycoside Formation .......................................................... 2.1. General Methods ............................................................ 2.1.1. The Michael Reaction .......................................... 2.1.2. The Fischer Reaction ........................................... 2.1.3. The Koenigs-Knorr Reaction ................................. 2.1.4. The Helferich Reaction ........................................ 2.1.5. The Fusion Reaction............................................ 2.1.6. The Imidate Reaction........................................... 2.1.7. The Sulfur Reaction ............................................ 2.1.8. The Armed-Disarmed Method................................ 2.1.9. The Glycal Reaction ............................................ 2.1.10. Miscellaneous Leaving Groups............................... 2.1.10.1 Fluoride Glycosyl Donors ......................... 2.1.10.2 Silyl Glycosyl Donors .............................. 2.1.10.3 Heterogenous Catalysis ............................ 2.1.10.4 The Pool Strategy.................................... 2.1.10.5 Phosphate Glycosyl Donors ....................... 2.1.11. Enzymatic Approach ........................................... 2.1.11.1 Enzymatic Synthesis of Oligosaccharides ...... 2.1.12. The Solid-Phase Methodology................................ 2.2. Cyclic Oligosaccharides ................................................... 2.2.1. Chemoenzymatic and Enzymatic Synthesis................ References ...........................................................................
68 68 68 70 73 76 78 80 88 95 98 104 104 105 110 112 112 113 117 117 124 127 134
3. N-Glycosides........................................................................ 3.1. Nucleoside Formation...................................................... 3.2. Protecting Groups........................................................... 3.2.1. Ribofuranoside Protecting Groups ........................... 3.3. General Methods ............................................................ 3.3.1. The Michael Reaction .......................................... 3.3.1.1 General Figure and Conditions ................... 3.3.2. The Fischer-Helferich Reaction .............................. 3.3.2.1 General Figure and Conditions ................... 3.3.3. The Davol-Lowy Reaction..................................... 3.3.3.1 General Figure and Conditions ................... 3.3.4. Silyl Coupling Reaction........................................ 3.3.4.1 General Figure and Conditions ................... 3.3.5. Sulfur-mediated Reaction...................................... 3.3.5.1 General Figure and Conditions ................... 3.3.6. Mitsunobu Reaction ............................................ 3.3.7. Palladium-mediated Reaction.................................
138 139 140 142 151 153 153 156 156 157 157 159 159 163 163 163 164
Contents
ix
3.3.8. Microbial/Enzymatic Approach .............................. Oligonucleotide Synthesis................................................. 3.4.1. Phosphoramidite Method ...................................... 3.4.2. Phosphonate Method ........................................... 3.4.3. Modified Oligonucleotides .................................... References ...........................................................................
166 167 170 172 172 176
4. Nucleoside Mimetics.............................................................. 4.1. Modified Nucleosides ...................................................... 4.1.1. Heterocycle Modifications..................................... 4.1.1.1 C-5 Substituted Pyrimidines....................... 4.1.1.2 C-6 Substituted Pyrimidines....................... 4.1.1.3 Purine Formation .................................... 4.1.2. Sugar Modifications ............................................ 4.1.2.1 2 3 -Dideoxysugars.................................. 4.1.2.2 2 Deoxynucleosides................................. 4.1.2.3 3 -Deoxynucleosides................................ 4.1.2.4 4 -Substituted Nucleosides......................... 4.1.3. Complex Nucleosides .......................................... 4.1.3.1 Fused Heterocyclic Nucleosides.................. 4.2. C-Nucleosides ............................................................... 4.3. Carbocyclic Nucleosides .................................................. 4.3.1. Cyclopropane Carbocyclic Nucleosides .................... 4.3.2. Cyclobutane Carbocyclic Nucleosides ...................... 4.3.3. Cyclopentane Carbocyclic Nucleosides..................... 4.3.4. Palladium Mediated............................................. 4.3.5. Enzymatic Synthesis............................................ 4.3.5.1 Base Ring Formation ............................... 4.3.6. Carbocyclic C-Nucleosides.................................... 4.4. Acyclic Nucleosides........................................................ 4.5. Thionucleosides ............................................................. 4.5.1. Preparation of Thioribofuranosyl Intermediates........... 4.5.2. Glycosidic Bond Formation ................................... 4.5.3. Chloromercuration Promoted Coupling Reactions........ 4.5.3.1 Silylmediated Coupling Reactions ............... References ...........................................................................
179 180 181 181 183 184 185 185 190 192 193 195 199 200 209 211 212 212 214 220 220 223 223 228 230 236 237 237 241
5. C-Glycosides........................................................................ 5.1. Synthetic Approaches for the Preparation of C-Glycosides......... 5.1.1. Electrophilic Glycosyl Donors................................ 5.1.1.1 Glycosyl Donors Bearing Good Leaving Groups ...................................... 5.1.1.2 Other Electrophilic Glycosyl Donors ............ 5.1.2. Concerted Reaction and Ring Formation ................... 5.1.3. Palladium-Mediated Reactions ...............................
247 247 250
3.4.
250 251 255 256
x
Contents
5.1.4. Mitsunobu Reaction ............................................ 5.1.5. Nucleophilic Sugars ............................................ 5.1.6. Cross-Metathesis Reaction .................................... 5.1.7. Samarium Promoted Reaction ................................ 5.1.8. The Ramberg-B¨acklund Reaction............................ 5.1.9. Free Radical Approach......................................... 5.1.10. Exoglycals ........................................................ 5.1.11. The Tether Approach ........................................... References..........................................................................
256 257 260 260 262 263 265 267 270
6. Glycoconjugates.................................................................. 6.1. Biological Function and Structural Information ..................... 6.1.1. Classification of Glycocoproteins ............................ 6.1.2. Recognition Sites................................................ 6.1.3. Structural Information of Glycoproteins.................... 6.2. Carbohydrate Binding Proteins ......................................... 6.2.1. Combining Sites................................................. 6.3. Glycopeptide Synthesis .................................................. 6.4. Glycoprotein Synthesis................................................... 6.4.1. Indiscriminate Glycosylation ................................. 6.4.2. Chemoselective and Site-Specific Glycosylation.......... 6.4.3. Site-Selective Glycosylation .................................. 6.4.4. Enzymatic Synthesis............................................ 6.5. Synthesis of Antigenic Glycoconjugates.............................. References..........................................................................
272 272 273 275 276 277 279 281 285 286 289 289 289 292 301
7. Hydrolysis of Glycosides ....................................................... 7.1. Acidic Hydrolysis ......................................................... 7.2. Basic Hydrolysis........................................................... 7.2.1. Phenolic Glycosides ............................................ 7.2.2. Enolic Glycosides ............................................... 7.2.3. β-Susbstituted Alcohol Glycosides.......................... 7.3. Enzymatic Hydrolysis .................................................... 7.3.1. β-Glucosidases .................................................. 7.3.2. β-Glucanasas, β-Quitinases................................... 7.3.3. β-Cellulase ....................................................... 7.3.4. β-Glucuronidase ................................................ 7.3.5. Glycosidase Enzymatic Activity Detection................. 7.3.6. Regarding β-1,4-Glucanases (EG)........................... 7.3.7. Fluorescent O-Glycosides..................................... 7.3.8. O-Glycosides Measured by Absorption .................... 7.3.9. Histochemical O-Glycosides ................................. References..........................................................................
304 304 306 306 306 306 308 308 308 308 308 309 309 310 311 311 313
8. Nuclear Magnetic Resonance of Glycosides .............................. 8.1. NMR of O-Glycosides ...................................................
314 314
Contents
xi
8.2. N-Glycosides ............................................................... 325 References.......................................................................... 328 9. X-Ray Diffraction of Glycosides ............................................. 9.1. X-Ray Diffraction of O-Glycosides.................................... 9.2. X-Ray Diffraction of Nucleosides...................................... References..........................................................................
330 331 337 340
10. Mass Spectrometry of Glycosides ........................................... 342 References.......................................................................... 348 Index...................................................................................... 349
Preface
There is no doubt that glycoside chemistry continues to be a dynamic and exciting field related to organic chemistry. Within sugar chemistry, glycosides are of special interest not only because of the challenges represented by their synthesis and structural characterization, but also due to their important biochemical relevance, and hence their applications in a number of essential disciplines, such as pharmaceuticals, food, and biotechnology. Important biomolecules such as DNA and RNA, or cofactors such as ATP and NAD, are some of the natural glycosidic structures playing key rules at a biochemical level. Also, a considerable number and variety of natural and synthetic glycosides are being extensively used as antibiotics, antiviral, and antineoplasic agents. There are also a significant number of chromophoric glycosides being used in molecular biology as substrates for detection of enzymatic activity of gene markers. Solid-phase oligosaccharide synthesis, despite the great progress recently reported by different groups, continues to be a challenging task considering the diversity and complexity of glycosides, especially those present in cellular membranes. However, based on the satisfactory evolution of this approach, it is expected that many complex molecules will be prepared in just in the same way that solidphase chemistry is currently used to prepare oligopeptides and oligonucleotides. The aims of this book are to prepare methods and strategies for the formation of glycosides, illustrated by the synthesis of important biologically active glycosides, and also to present an overview of the basic tools needed for the characterization of glycosides through NMR spectroscopy, X-ray diffraction, and mass spectrometry. From the overwhelming number of excellent articles related to glycoside chemistry, it hasn’t been an easy task to select those that are biologically important, and perhaps most importantly serve as didactic models for understanding more about the process of glycoside bond formation. The text should also serve as a helpful guide to those professionals interested in sugar chemistry, especially the design of synthetic routes, by evaluating suitable protecting and leaving groups, and the best reaction conditions needed for the preparation of glycosides. The author would like to thank COFAA and SIP-IPN for financial support. MBA June 2004 xii
1 Glycosides, Synthesis, and Characterization
1.1 Introduction Monosaccharides are generally defined as aldoses and ketoses connected to a poly hydroxylated skeleton.1 In an aqueous solution, the monosaccharides are subject to internal nucleophilic addition to form cyclic hemiacetal structures. When the addition occurs between -OH at C(4) or -OH at C(5) with the carbonyl group, a fiveor a six-member ring is formed known as a furanose or a pyranose, respectively. It is also known that equilibrium exists between the open and the cyclic form, being displaced to the latter by more than 90%. Therefore, in aqueous solutions, it is more accurate to consider that most of the sugars are present as cyclic molecules and behave chemically as hemiacetals. The Haworth structure is a useful way to represent sugars. However, as it is known that for any 6-membered rings, a nonplanar conformation is assumed. The conformation exclusively preferred is called chair and the two possible conformations are 4 C1 and 4 C1 . The first conformation is used for the D enantiomeric form and the second for the L form (Figure 1.1). On a chair conformation type 4 C1 , an α anomeric hydroxyl group is positioned in the axial orientation while a β hydroxyl lies equatorial (Figure 1.2). As a result of this reversible ring formation process, a diastereomer mixture of anomers α and β is produced, as indicated in Table 1.1 for some of the most common monosaccharides.1,2 The pioneering work in 1890 by Fischer3 allowed him to determine the relative configuration and the synthesis of the most known aldohexoses. Based on the assumption that in D-glyceraldehyde, the hydroxyl group was placed to the right, he was able to propose correctly the structure of tetroses, pentoses, and aldohexoses (Figure 1.3). The relative configuration of D-glyceraldehyde was later confirmed by X-ray diffraction by Bijvoet in 1951. Consequently, all the resulting biologically active distereoisomeric aldoses derived from D-glyceraldehyde conserve always the secondary alcohol next to the primary one to the right side in the Fischer projection. Ketoses with three to six carbons are naturally produced from 1,3Dihydroxyacetone, according to the tree shown in Figure 1.4.
1
2
1. Glycosides, Synthesis, and Characterization FIGURE 1.1. α-D-glucopyranose-4 C1 and α-L-glucopyranose-1 C4 .
CH2OH O HO HO OH
OH
mirror plane
OH HOH2C
O
HO
OH
HO
TABLE 1.1. Distribution of αβ of some D-monosaccharides in solution at 31◦ C. Carbohydrate
Glucose Galactose Mannose Rhamnose Fructose Ribose Xylose
% Pyranose
% Furanose
α
β
α
β
38 30 65.5 65.5 2.5 21.5 36.5
62 64 34.5 34.5 65.0 58.5 63.0
0.1 3 0.6 0.6 6.5 6.4 0.3
<0.2 4 0.3 0.3 25 13.5 0.3
1.2 Reactions of Monosaccharides Carbohydrates own their reactivity to the hemiacetalic centre and to the hydroxyl groups, being primarily more reactive than the secondary. Aldoses and ketoses are susceptible to nucleophilic addition and the latter is less reactive due to steric hindrance. The cyclic forms are adopted when the hydroxyl group positioned at C-5 verifies an intramolecular nucleophilic addition to the carbonyl group producing an anomeric mixture of pyranosides (Figure 1.5).
1.3 Chemical Modifications The classical reactions on monosaccharides were used initially for identification or sugars or to distinguish between aldoses and ketoses. They have been also very useful for preparing key intermediates in the construction of glycosides. Some of the common reactions used to identify monosaccharides are
1.3. Chemical Modifications
3
OH
H
OH
OH
H
OH
H
OH
H
OH
O
HO
CHO
OH
O
OH OH
OH OH
OH OH OH
O
HO
CH2OH
OH
OH
D-Allose
OH OH OH O HO
CHO HO
OH
H
H
OH
H
OH
H
OH
OH
O OH
OH
OH OH
OH
OHO
OH
HO
CH2OH
OH D-Altrose
OH OH O HO HO
CHO H HO H H
OH
OH H OH OH
OH OH
O OH
OH OH
OH OH
CH2OH D-Glucose
O HO HO
OH OH
FIGURE 1.2. Fischer projections, Haworth structures, and 4 C1 chair conformation of Daldohexoses.
1.3.1 Oxidations The oxidation of nonprotected aldoses may undergo carboxylic acids formation depending on the reaction conditions. Thus, with aqueous bromine the monocarboxylic acid (aldonic acid) is formed, whereas with nitric acid the dicarboxylic acid is favored (aldaric acid) (Figure 1.6).
4
1. Glycosides, Synthesis, and Characterization OH OHO HO HO
CHO HO
H
HO
H
H
OH
H
OH
OH
OH
O OH
OH OH
OH
OH
OHO HO HO
CH2OH
OH
D-Mannose
OH OH O CHO H H
OH
OH OH
OH
OH
O
OH OH
OH HO H
H OH
OH OH O
OH OH
CH2OH
OH D-Gulose
OH OH OH OH OHO
CHO HO
OH
H OH
H
OH
O
OH
OH
OH HO H
H OH
OH
OH OH OHO
OH
CH2OH
OH D-Idose
OH
FIGURE 1.2. (continued)
1.3.2 Periodate Oxidation Periodic acid is a strong oxidating agent and is capable of breaking 1,2-cis diols to generate after cleavage of the C-C bond carbonyl fragments (Figure 1.7).
1.3. Chemical Modifications
5
OH OH O CHO H
OH HO
H
HO
H
OH OH
O OH
OH H
HO
OH
OH
OH OH
OH
O
OH
CH2OH
OH
HO OH
D-Galactose
OH OH OH O CHO HO
H
HO
H
HO
H
H
HO
OH OH
OH
O OH OH
OH OH OH
OH
OHO
CH2OH
HO
OH
D-Talose
FIGURE 1.2. (continued)
1.3.3 Tollens Reaction This classical reaction has been very useful for aldose identification and consists of the oxidation of the aldehyde function with a moderate oxidative agent (a silver ammonium salt) to afford the glucuronide ammonium salt and metallic silver, which produce the silver mirror effect (Figure 1.8).
1.3.4 Benedict and Fehling Test The test consists in the use of a cooper citrate (Benedict reagent) or cooper tartrate complex (Fehling reagent), which upon treatment with the sugar under study produces the glucuronide ion along with cooper (I) oxide which is detected as brick-red precipitate (Figure 1.9). Based on the Tollens, Benedict or Fehling test, the sugars are classified into reducing when positive or non-reducing sugars if negative. Reducing sugars are hemiacetals in equilibrium with small amounts of the open forms. Under basic conditions, the aldoses and ketoses give positive the Tollens test and/or Benedict/Fehling test as result of equilibrium aldose-ketoses via enediol intermediates.
6
1. Glycosides, Synthesis, and Characterization O
H
C H
OH CH2OH
D-Glyceraldehyde
O
O C
O
H
C
C
H
OH
HO
H
OH
H
D-Erythrose
D-Threose
O HO H H
OH OH OH
H H H H
H
O C
OH HO OH H OH H OH H CH2OH
D-Allose
O
H
C
H OH OH
H HO H
O C
H H OH HO OH H OH H CH2OH
D-Altrose
H
O
OH HO H HO OH H OH H CH2OH
D-Glucose
C
C
H H OH CH2OH D-Lyxose
D-Xylose
O
H
C
H H H H OH HO H OH CH2OH D-Mannose
H
O
OH HO OH H H HO OH H CH2OH
D-Gulose
H
HO HO H
OH H OH CH2OH
D-Arabinose
H
O
H
C
CH2OH
D-Ribose
C
OH CH2OH
CH2OH
O
H
CH2OH
H
H H H
H
C
H H H OH HO H HO OH H
CH2OH D-Idose
O C
H
O C
OH HO H HO H HO OH H CH2OH
H H H H OH
CH2OH
D-Galactose D-Talose
FIGURE 1.3. The Fischer projections of D-aldoses.
1.3.5 Nucleophilic Addition Aldose and ketone may react with a variety of nucleophiles, giving as results addition/elimination products such as osazones and oximes, or addition products such as reduced derivatives when reacted with hydrides.
1.3. Chemical Modifications
7
CH2OH C O CH2OH 1,3-Dihydroxyacetone
CH2OH C O H C OH CH2OH D-Erythrulose
CH2OH C
CH2OH
O
C O
H C OH
HO C H
H C OH
H C OH
CH2OH
CH2OH
D-Ribulose
D-Xylulose
CH2OH
CH2OH
CH2OH
CH2OH
C O
C O
C O
C O
H C OH
HO C H
H C OH
H C OH
H C OH
H C OH
CH2OH D-Psicose
CH2OH D-Fructose
H C OH HO C H H C OH CH2OH D-Sorbose
HO C H HO C H H C OH CH2OH D-Tagatose
FIGURE 1.4. Fischer projections of the 2-ketoses.
The reaction that allowed E. Fischer to determine the structure of the common aldoses was the osazone formation and consisted in the reaction between hydrazine with aldoses (Figure 1.10) to yield crystalline derivatives that can be identified through their melting points values. The carbonyl group can be reduced by hydrogenation or hydride addition to produce the corresponding alditols (Figure 1.11). These reduced sugars are present
8
1. Glycosides, Synthesis, and Characterization OH
OH O
HO HO
OH OH
HO HO
O
HO HO
O
OH
OH
OH
OH H
OH
intramolecular nucleophilic attack
Anomer α
Anomer β
FIGURE 1.5. The pyranose ring formation. O
O
C H
HNO3
C OH
(CHOH)n
(CHOH)n C
O
H2C
OH
Br2
C OH
H 2O
(CHOH)n
OH
H2C
OH
O
FIGURE 1.6. Oxidative aldose transformation into mono- and dicarboxylic acids.
HC OH HC
H5IO6
HC O
OH
HC
+ H3IO4
O
FIGURE 1.7. Oxidative cleavage of diol by periodic acid. O
O
C H
Ag(NH3)2OH
C O NH4
(CHOH)n H2C
(CHOH)n
OH
H2C
+
OH
o Ag mirror effect
FIGURE 1.8. Tollens reaction.
HO HO
non-reducing end
OH O OH
reducing end
OH O
O HO
OH OH
O C
O H
(CHOH)n H2C
OH
2−
2+
−
HOC(CO2H)(CH2CO2H)2 Cu /4 OH
C OH (CHOH)n H2C
OH
FIGURE 1.9. Benedict and Fehling test.
+ Cu2O red pp
+ 2 H 2O
1.3. Chemical Modifications HC NNHPh
CHO H
NNHPh
OH
HO
9
H
HO
2 PhNHNH2
H + NH3 + PhNH2
H
OH
H
OH
H
OH
H
OH CH2OH
CH2OH
FIGURE 1.10. Osazone formation. O C
H
H2-Ni or NaBH4
(CHOH)n H2C
H2C OH (CHOH)n
OH
H2C
OH
FIGURE 1.11. Carbonyl reduction for the preparation of sorbitols.
in various fruits such as cherries, pies, apples, etc,, and are used as sugar substitute for diabetics.
1.3.6 Enediol Rearrangement This transformation occurs at basic medium and allows the conversion of epimers, defined as isomeric forms that differ in the position of the hydroxyl group at C-2. In this way it is possible to transform through the enediol intermediate glucose to mannose and vice versa (Figure 1.12). Another important isomerization process through the enediol rearrangement is the interconversion of glucose and fructose. Thus, the enolization proceeds by migration of proton at position 2, to carbon at 1 (Figure 1.13).
1.3.7 KilianiFischer Synthesis This sequence was used to increase the number of carbons in a sugar. The reaction involves cyanohydrin formation by nucleofilic addition of cyanide to the aldehyde.
CHO H
OH
CHOH −
OH OH, H2O
CHO −
OH, H2O
HO
H
(CHOH)n
(CHOH)n
(CHOH)n
CH2OH
CH2OH
CH2OH
FIGURE 1.12. The enediol rearrangement.
10
1. Glycosides, Synthesis, and Characterization
CHOH OH
FIGURE 1.13. The enediol rearrangement.
CH2OH −
OH, H2O
O
(CHOH)3
(CHOH)3
CH2OH
CH2OH
The diastereoisomeric mixture of cyanohydrins obtained was partially reduced to produce the epimeric forms (Figure 1.14).
1.3.8 The Ruff Degradation The process of reducing the monosaccharide skeleton in one carbon is known as Ruff degradation and consists in the oxidation of the aldehyde to the carboxylic acid through the use of calcium salt and subsequent peroxide treatment in the presence of ferric salts to produce the aldose reduced in one carbon (Figure 1.15).
1.3.9 Conversion of Pentose to Furfural Pentoses subjected to high acid concentrations can be transformed to furfural in quantitative yields. The sequence involves a tautomeric keto-enol equilibrium, dehydration and intramolecular nucleophilic addition of the primarily alcohol to the aldehyde to generate furfural (Figure 1.16). CN CHO H
OH
HO H
H OH
−
CN
CN
H
OH
HO
H
H
OH
H
OH
HO H
H OH
HO H
H OH
CH2OH
+
CH2OH
CH2OH
H2, H2O Pd, BaSO4
CHO H HO
H
H H
CHO
OH OH OH CH2OH
D-Glucose
+
HO
H
HO
H
H H
OH OH CH2OH D-Mannose
FIGURE 1.14. The Kiliani-Fischer synthesis.
1.4. Biosynthesis of Sugars CHO H
OH
HO
H Br2, H2O
H
H H
(COO−)2Ca2+
COOH
OH OH
HO H H
CH2OH
H
OH CaCO3
H
HO H H
OH OH
CHO
OH H2O2, Fe3+
H
HO H H
OH OH
H OH + CO32+ OH CH2OH
CH2OH
CH2OH
11
Aldopentose
Aldohexose
FIGURE 1.15. Ruff degradation. CHO H
OH
HO H
H OH
CHO
CHO
O
OH
H2SO4 conc
H
CH2OH
H H
H OH
O
O
H OH
−H 2 O
CH2OH
CH2OH OH
CHO
CH2OH
−H2O
CHO
O
CHO
FIGURE 1.16. Conversion of pentoses to furfural.
1.4 Biosynthesis of Sugars The synthesis of carbohydrates in plants occurs through a mechanism of carbon dioxide fixation, and was understood through the use of long-lived radioactive isotope of carbon 14 C. After considerable investigations it was founded that the initial CO2 acceptor was the five-carbon compound ribulose 1,5-bis-phosphate (RuBP) which after incorporation of carbon dioxide produce a six-carbon molecule. The resulting molecule is fragmented into two molecules of 3-phosphoglycerate (PGA) that is one of the intermediates of glycolysis. This transformations takes place in the chloroplast by a large multisubunit enzyme, ribulose biphosphate carboxylase “Rubisco”. The following reaction sequence is cyclic and constitutes what is known as the Calvin cycle which consists after formation of PGA in reduction to glyceraldehydes 3-phosphate (GAP), and regeneration of RuBP. The overall process requires 6 CO2 molecules fixed, 12 molecules of GAP produced which rearrange to regenerate 6 molecules of the five-carbon CO2 acceptor RuBP (Figure 1.17).
1.4.1 Sugars as Energy Sources Metabolically the main monosaccharide useful for the production of energy is glucose. During the glycolysis process glucose is enzymatically transformed and degraded to piruvate and is a preamble which is further introduced into the Krebs cycle.
12
1. Glycosides, Synthesis, and Characterization
CH2 OPO 32− O C OH + C C OH O HC OH
RuBP Carboxylase
O CH 2OPO3 2−
CH2 OPO 3 2− HC OH + − O C O
C C OH O−C O HC OH
−
O C O HC OH
3-PGA
CH 2OPO3 2−
CH2 OPO 32−
CH2OPO3 2−
RuBP Enediol form
ATP
ADP +Pi
O C
NADPH
NADP
+
OPO3 2−
CH OH CH 2 OPO3 2− BPG
CH 2OPO3 2−
O C
ATP
ADP + Pi
H
CH OH CH 2 OPO3 2− GAP
C O HC OH HC OH CH2OPO3 2− RuBP
FIGURE 1.17. Carbohydrate synthesis from CO2 fixation.
Carbohydrates are responsible of several biological events mainly related with the storage and production of energy, as metabolic intermediates and signal molecules. They are also constitutive structural units of essential biomolecules such as polysaccharides (starch, glucogen, and cellulose), glycoproteins, glycolipids, and nucleotides. The process by which glucose is used as energy source, to produce ATP and pyruvate is known as glycolysis and consist in series of events represented in Figure 1.18. The second cycle of glycolysis is divided in four steps.
1.5 Synthesis of Carbohydrates The chemical synthesis of carbohydrates can be accomplished by chemical, enzymatic or the combined approach (chemoenzymatic). Their preparation by either of the mentioned methods has received considerable attention especially because they can be used as starting materials for the synthesis of biologically active carbohydrate derivatives known as mimetics or the synthesis of complex molecules such as oligosaccharides or glycopeptides.
1.5.1 Chemical Synthesis Access to potentially useful sugar or congeners can be obtained from natural sugars such as arabinose and mannose.4 Thus, convenient routes have been implemented for the preparation of KDN from D-mannose,5 3-deoxy-D-manno-
1.5. Synthesis of Carbohydrates OH O
HO HO
OPO32− Hexokinase
+ ATP
OH OH
2−
O3POH2C
+ ADP + H+
OH OH glucose-6-phosphate
D-Glucose
phosphoglucose isomerase
O
HO HO
O OH
2−O POH C 3 2
CH2OH
CH2OPO32−
O OH
phosphofructokinase
OH
OH
fructose-6-biphosphate
fructose-6-phosphate
CH 2OPO 3 2−
aldolase
O
CHO H
+
OH CH2OPO 3 2−
CH 2OH
glyceraldehyde 3-phosphat e
dihydroxy acetone phosphate
glyceraldehyde-3phosphate deshydrogenase
CHO H
O C
+ NAD + Pi+
OH
H
CH2OPO32−
OPO32− OH
+ NADH + H+
CH2OPO32− 1,3-bisphosphoglycerate
glyceraldehyde 3-phosphate
O phosphoglycerate kinase
C
O−
H
O phosphoglycerate mutase
OH CH2OPO3
ADP
+ ADP + H+
OH
OH
C
CH2OH
3-phosphoglycerate
enolase
C
O− OPO32−
H2O
OPO32−
H 2-
ATP
O
O−
CH2
2-phosphoglycerate
O piruvate kinase
C
O− O
ADP + H+
ATP
phosphoenolpyruvate
FIGURE 1.18. The glycolysis pathway.
CH2OH
13
14
1. Glycosides, Synthesis, and Characterization OH
OH
OH
HO
i
CHO
OH
OH ii
HO CO2Me
OH
OH
OH
OH
OH
OH
OH
iii
HO
OH
HO HO
CO2Me OH
OH
HO
O
O
CO2R
HO
OH iv
R = Me R=H
i) methyl 2-(bromomethyl)acrylate, H 2O. ii) O 3, MeOH, −78o C, then Na2SO 3. iii) spontaneous ciclization. iv) KOH, MeOH.
CO2Et
O
CO2Et
CHO HO
O i
ii
O
O
HO OH
HO
O O
iii
O
OH O
CO2− NH4+
HO
O
O
O
O
O
O
OH
i) ethyl α-(bromomethyl)acrylate,10% formic acid, aq. MeCN. ii) O3, MeOH, −78oC, then Me2S, MeOH, −78oC to r.t.. iii) aq. TFA, then NH4OH.
O
EtO
OEt
CHO OAc
HO OH
i
ii
AcO
iii
AcO
AcO
OH
OAc
OAc
OH
OAc
OAc
OAc
OAc
OAc OAc OAc
FIGURE 1.19. Chemical synthesis of sugar congeners from natural sugars.
2-octulosonic acid (KDO) from 2,3:4,5-di-O-isopropylidene-D-arabinose,6 D-glycero-D-galacto-heptose from D-arabinose,7 and KDN from D-mannose8 (Figure 1.19). Different approximations for the preparation of monosaccharides from other sources have been reported. One method consists in the asymmetric synthesis of D-galactose via an iterative syn-glycolate aldol strategy. The general method is shown in Figure 1.20.9
1.5. Synthesis of Carbohydrates
15
OEt
EtO
OAc AcO AcO
OH OH
HO v
iv
O
OAc
HO
OH OH
OAc OAc
i) allyl bromide, ultrasonication, then Ac2O, Py, DMAP. ii) OsO4, KIO4, then TBAF. iii) H3O +, (HC(OEt)3. iv) OsO4, NMO, then Ac2O, Py, DMAP. v) NaOMe, MeOH, then H3O+.
O
OH
OH
OH
i
OH
OH
OH
O2N
OH
ii
H OH
HO HO
OH
OH
OH
OH
OBn
OBn
OH
OBn
iii
iv
OBn
O
OHC OH
HO
OBn
OH NHCbz OBn
OBn
OBn O
OBn
OBn
OBn
OBn
v
OBn OBn
OBn MeO2C
MeO2C
OBn
OBn
HO
OH
OBn
OH
vi
HO HO
O
CO2Me
HO
i) MeNO2, DBU. ii) Nef oxidation iii) EtSH, HCl, then NaH, BnBr, DMF, then MeI, Na2CO3. iv) (Et)2P(O)CH(NHCBz)CO2Me, NaH, CH2Cl2. v) H2, Pd-C. vi) H2, Pd(OH)2, then Dowex H+, MeOH.
FIGURE 1.19. (continued)
A promising and simple concept based on a two-step reaction sequence for preparing monosaccharides via the enantioselective organocatalytic direct aldol reaction of α-oxyaldehydes is recently described. The summarized sequence is illustrated in Figure 1.21.10 An interesting strategy for preparing KDO and 2-deoxy-KDO from 2,3-Oisopropylidene-D-glyceraldehyde was reported, based on a hetero Diels-Alder
16
1. Glycosides, Synthesis, and Characterization O
O
O i
NH
O
OP
O ii
N
O
H OR
R
OP
OR
OR
R O
O
OP
OH
O
iii
OR O
iv
N OR
OH
HO HO
OR
OH
R
OH
i) a) glycolate aldol. b) protect. ii) DIBAL-H cleavage. iii) iterative glycolate aldol. iv) cleavage and deprotection.
FIGURE 1.20. Asymmetric synthesis of D-galactose.
reaction, followed by pyranoside ring formation. Diol formation and double inversion at C-4 and C-5 produced the target molecules (Figure 1.22).11 C-methyl heptoses were suitable prepared from nonracemic butenolide as starting material. Asymmetric conjugate addition provided protected lactone which by methylation afforded α-methyl lactone. Each of them under DIBALH treatment, produced C-methylheptoses (Figure 1.23).12 Naturally occurring sugar amino acids are another class of interesting modified carbohydrates found as structural components in nucleoside antibiotics. Most of them consist of N- and O-acyl derivatives of neuraminic acids, while other presents a ipso-hidantoin furanosides (Figure 1.24).13 Some of these sugars amino acids have been synthesized via azide furanosides,14,15 as it was the case for β-sugar amino acids shown in Figure 1.25.13
1.5.2 C-Glycosyl Amino Acids It has been mentioned that natural glycopeptides are classified into O-glycopeptides when the sugar residue establishes an O-glycosyl linkage with L-Serine or L-Threonine and N -glycopeptides if the linkage is with Asparagine. There has been an increasing interest for preparing unnatural C-glycol amino acids O O
O O
OX
OH OY
H
H
O
OH
XO
X
X
aldol 2
aldol 1
OX
OX
OX
XO
OY OH
FIGURE 1.21. Two-step carbohydrate synthesis.
1.5. Synthesis of Carbohydrates
O
BnO
O
BnO
OBn
BnO
i
ii
O
HO
O
OBn
CO2Me
OH
CO2Me
OBn
BnO BzO
+
BnO BzO
O
O CO2Me
BzO
iii
BnO
BnO
CHO
17
BzO CO2Me
i) HCOCO 2Bu, 130oC, then MeOH, TsOH. ii) OsO4, NMO. iii) Tf2O, Py, then PhCO 2NBu4.
FIGURE 1.22. Synthesis of protected KDO and 2-deoxy-KDO.
as a potential building block in the assembling of modified glycopeptides that may serve in preparing therapeutically useful mimetics, with higher resistance to hydrolytic enzymes and also displaying superior properties than the natural ones. O
O
OTMS
H3 C i
O
OTMS O O
OTMS
H 3C ii
O H3 C
O
O
O
O
O
O iii
iii
OH
OH HO HO
HO HO
O
O H3 C
H3 C OH
CH3
i) Me2CuLi, CH2Cl2. ii) LiHDMS, THF, then MeI. DIBAlH, CH2Cl2, then 3N HCl, THF.
FIGURE 1.23. Synthesis of-methyl heptoses.
OH
18
1. Glycosides, Synthesis, and Characterization
R4
R5 CO2H R2 O OH
R3 R1 R1
R2
R3
R4
R5
glucosaminuronic acid
NH 2
H
OH
OH
H
galactosaminuronic acid
NH 2
H
OH
H
OH
monnosaminuronic acid
H
NH2
OH
OH
H
H
OH
NH 2
H
OH
4-amino-4-deoxy-glucuronic acid
O OH
HO
COOH
OH
HO
O
H 2N
O
HN
OH CO 2H
NH
OH
HO
HO
OH OH
NH NHAc
O
Hydantocidin
Neuraminic acid
Siastatin B
FIGURE 1.24. Naturally occurring sugar amino acids. OH O
O OH
O
O
i
H
O
O
ii
H
O
O
N3
HO O
O
O O
iv
O
O
O
NH
O
N3
O
O
N3
iii
H
O
O
HO
O
HO
Fmoc HO O HO iv
HO
H
H
O NH
Fmoc
O
v
O
HO
O
O NH
O
Fmoc
i) a) Tf2O, Py. b) NaN 3, Bu4NCl (cat.), 69%. ii) 77% AcOH, quant. iii) a) NaIO 4. b) KMnO 4, 50% AcOH, 90%. iv) H2, Pd/C, FmocCl, NaHCO 3. v) NaOCl, TEMPO (cat.), KBr, NaHCO 3, Bu4NCl, 62%.
FIGURE 1.25. Synthesis of protected sugar amino acids.
1.5. Synthesis of Carbohydrates Ph N BnO
CONH2 BnO
O
i
N Ph
OBn OBn
O
BnO
CHO
O
OH OH
OH
OBn OBn
OBn OBn
HO
O
ii
CONH2 iii,iv
19
CONH2
NH2
HO +
O
NH2
OH OH
i) TsOH. ii) a) NaCN, K2CO3, H2O. b) H2O2. 91%. iii) a) MsCl. b) LiN3. iv) a) aq. HCl. b) H2, Pd/C.
FIGURE 1.26. Synthesis of anomeric ribofuranosyl glycines.
A recent review describes methods for the preparation of C-glyosyl glycines, alanines, serines, asparagines tyrosines, and tryptophans.16 For instance the synthesis of ribofuranosyl glycine was described under Strecker conditions, starting from 2-(2,3,5-tri-O-benzyl-β-D-ribofuranosyl)-1,3diphenylimidazolidine, which was after hydrolysis tosylated and reacted with cyanide and peroxide to give the α-hydroxy amide as racemic mixture. The anomers were separated as O-mesyl derivatives which were transformed to the azide and further reduced to the corresponding ribofuranosyl glycines (Figure 1.26).17 A method reported for the preparation of C-glycosyl alanines involves the use of (R)-methyleneoxazolidinone, which was linked to the peracetylated iodosugars under promoted radical additions. The α-linked C-glycoside was subjected to hydrogenolysis to give α-D-galactosyl D-alanine and the α-D-glucosyl isomer (Figure 1.27).18 C-analogues of glycosyl serines have been prepared by a number of methods and among them Strecker, Witting, and Sharpless asymmetric aminohydroxylation reactions19 . One of them describes their synthesis via coupling of anomeric pyridyl sulfone with an electrophiles center under samarium catalysis. The resulting Cglycosylation proceeded with α-selectivity (3.3:1). Final deprotection produced the C-glycosyl serine analogue in good yield (Figure 1.28).20 More recently, the stereoselective synthesis of a C-glycoside analogue N-fmocserine β-N-acetylglucosaminide was described employing the Ramberg-B¨acklung (RB) rearrangement. This procedure involves the coupling reaction between isothiourea and protected iodide to produce thioglycoside in good yield. Oxidation to the sulfone was followed by the RB conditions (KOH/Al2 O3 in tBuOH/(CBrF2 )2
20
1. Glycosides, Synthesis, and Characterization R1 OAc
R1
NCbz
O
R2 AcO
O
OAc
OAc NCbz
t-Bu
O
I
O
R2 AcO
i
+
OAc
O
R1 = OAc, R2 = H
t-Bu
O
R1 = H, R2 = OAc
R1
OAc O
R2 AcO
ii
OAc
CO2H NH2
i) Bu3SnH, NaCNBH3. ii) H2 Pd-C.
FIGURE 1.27. Synthesis of α-D-galactosyl D-alanine and the α-D-glucosyl isomers.
at 50◦ C affording the exoglycal derivative. Final steps which involves hydrogenolysis, deprotection, and oxidation provided the desired C-glycosyl analog (Figure 1.29).21 β-2-Deoxy sugar bearing uridin diphosphate (UDP) is a substrate used by a variety of glycosyltransferases. It is described the chemical synthesis of UDP β-2deoxysugars starting from α-glycosyl chlorides as indicated in Figure 1.30. These
OBn OBn
OHC
O
RN
AcHN
O
i
O
BnO
+
BnO
OBn OBn
O O
AcHN HO
SO2Py R = t-BuMe2Si-
OBn OBn O ii-vi
BnO
NHBoc
AcHN
OH O i) SmI2. 82% ii) deoxygenation. iii) TBA. iv) Boc2O. Cs2CO3, MeOH. vi) Jones.
FIGURE 1.28. Synthesis of C-glycosyl serine analogue.
RN O
1.5. Synthesis of Carbohydrates
21
OAc O
AcO AcO BocN
NH2HCl
S NHAc
O
I
OAc
NH
S
i
NHAc
tBu2
tBu2
Si O S
O
tBu2
iv
BocN
O
O
O S
NHAc
BocN
NHAc
O
Si
O O TBDMSO
iii
O O TBDMSO
ii
O
AcO AcO
O BocN
Si
O O TBDMSO
O
AcO AcO AcO
v
O NHAc
BocN
BocN
O
NHAc
AcO AcO AcO
vi
O
NHFmoc CO2H
O NHAc
i) K2CO3, Na2S2O5/acetone-H2O, 98%. ii) a) Et3N/MeOH-H2O. b) tBu2Si(OTf)2, 2,6-lutidine/DMF, 88%. iii) mCPBA, Na2HPO4/CH2Cl2, 77%. iv) KOH/Al2O3, CBrF2CBrF2/tBuOH, 50oC, 38%. v) a) H2, Pd(OH)2/EtOAc, 78%. b) TBAF/THF. c) Ac2O/Py, 68% (two steps). vi) a) TFA/CHCl3. b) FmocCl/iPrNEt/CH2Cl2-MeOH, 69% (two steps). c) Jones oxidation/acetone, 77%.
FIGURE 1.29. Synthesis of C-glycoside serine analogue by Ramberg-B¨acklung rearrangement.
useful intermediates are essentials for studying glycosyltransferases involved in the synthesis of biologically active natural products.22
1.5.3 Enzymatic Synthesis The enzymatic synthesis of monosaccharides and carbohydrates mimetics by enzyme catalysts is performed mainly by a group of lyases known as aldolases. This O
R1 R2
OH
i,ii
O
R1
NHCbz
R1 = OAc, R2 = H R1 = H , R2 = OAc
R2
OUDP
NHCbz
α/β 1:2
i) TMS-Cl, TMS-I, –78oC. ii) UDP, Bu4N salt, 60%.
FIGURE 1.30. Synthesis of protected UDP epi-vancosamine.
22
1. Glycosides, Synthesis, and Characterization O
O
O X
R
+
H
OH
Aldolase
R
R
R X
Donor
Acceptor
Aldol condensation
X = H, NH 2, OH
FIGURE 1.31. General scheme of enzymatic-mediated aldol condensation.
enzymes effects the conversion of hexoses from their three-carbon components via an aldol condensation.23 There are over 30 aldolases identified and isolated, being classified in two types depending on the mechanism involved: aldolase type 1 and type 2, which is Zn-dependent. The general reaction that they catalyze is the stereospecific addition of a ketone donor to an aldehyde acceptor (Figure 1.31). The aldolases used for synthetic purposes are classified in five groups depending on the ketone donor and the products formed. Dihydroxyacetone phosphate (DHAP) aldolase Pyruvate aldolase 2-Deoxyribose 5-phosphate aldolase Glycine aldolase Other aldolases Examples of each of them are indicated in Table 1.2; Aldolases have been also very useful for the preparation of a variety of common and uncommon monosaccharides. Fructose-1,6-diphosphate (FDP) aldolase effects the conversion of dihydroxyacetone phosphate (DHAP) and glyceraldehyde3-phosphate (G3P) to D-fructose-1,6-diphosphate (FDP). Table 1.2 summarizes the natural substrates, de donors, and the products obtained through this reaction. Broken lines indicates the bond formed or broken.24 DHAP-aldolases catalyze the reversible asymmetrical aldol condensation of DHAP to L-lactaldehyde or to D-glyceraldehyde 3-phosphate (G3P). There are four types of DHAP aldolase, which are classified on the basis of the condensation product formed. D-fructose 1,6-diphosphate (D-FDP) aldolase, which condenses DHP with G3P. D-Tagatose 1,6-diphosphate (TDP) which utilizes the same substrates, Fuculose 1-phosphate, catalyzing the condensation reaction between DHAP and L-lactaldehyde to produce L-fucolose 1-phosphate, and Lrhamnulose 1-phosphate aldolase, which recognizes the same substrates to produce l-rhamnulose 1-phosphate (Figure 1.32).24 Likewise, DHAP-dependend aldolases are involved in the incorporation of dihydroxyacetone phosphate (DHAP) on pentose and hexose phosphate introducing consequently three carbons and two quiral centers (Figure 1.33).25 Another enzymatic aldol type reaction takes place on N-acetylneuraminic acid also known as sialic acid, which after a reversible aldol reaction of N-acetyl-D-
1.5. Synthesis of Carbohydrates
23
TABLE 1.2. Natural substrates for aldolases. O
OH
O CH3
PO
OH OH
O
OH OH OH OH
-O2C
OH NHAc
sialic acid synthetase
O
OH
-O2C
OH NHAc
rhamnulose-1-P aldolase
OH OH OH
sialic acid aldolase
OH
-O2C
OP OH
3-deoxy-2-oxo-6-Pgalactonate aldolase
O
O NH3+
-O2C
-O2C
H
Donor
O
Donor
OH CO2–
-O2C
OH
O
O OH
-O2C
Donor
OH
NH3+
-O2C
OP
OH
OH 3-deoxy-2-oxo -L-arabinoate aldolase
4-hydroxy-2-oxoglutarate aldolase
O HO
CH3
4-hydroxy-4-methyl -2-oxoglutarate aldolase
O
D-Thr aldolase
NH3+
OH
O
CO2–
-O2C
2-deoxyribose -5-P-aldolase
OH
-O2C
OH
L-Thr aldolase
NH3+
O
-O2C
CH3
-O2C
OH 3-deoxy-2-oxo -D-pentanoate aldolase
CO2–
CH3
-O2C
-O2C
OH
-O2C
CH3
OH 3-deoxy-2-oxo -D-glucarate aldolase
hydroxybutyrate aldolase
Ser-hydroxymethyl transferase
mannosamine and pyruvate, produces N-acetyl-5-amino-3,5-dideoxy-D-glyceroD-galacto-2-nonulosonic acid (NeuAc) (Figure 1.34).26 Ketoses can be transformed to aldoses through the use of isomerases.27 In this way glucose derivatives can be obtained from fructose as shown in Figure 1.35.28
1.5.4 Chemoenzymatic Synthesis The chemoenzymatic approach is a combination of the chemical and the enzymatic methodologies and intends to explode the versatility and availability of the chemical reagents with the high stereo- and regioselectivity of the enzymes when they act as catalysts. For instance, the enzymatic synthesis of dihydroxyacetone phosphate (DHAP) is too expensive on large scale, and therefore the combined approach becomes
24
1. Glycosides, Synthesis, and Characterization OPO32−
O PO
OH
-O2C
Donor
O
OH
O
PO
OP OH OH
O
O
OH OH
-O2C
OP
-O2C
OP OH
DAHP synthetase
OH
O CH3
OH
3-deoxy-2-oxo-glutamate aldolase
OH OH
-O2C
O OP
OH OH
OP OH OH KDO aldolase
O
O
O D-FDP
OH
+
OH OH
-O2C
KDO synthetase
fuculose-1-P aldolase
PO
OH
OH
FDP aldolase
PO
Donor
H
PO
OP
OP
OH
OH
O
O D-TDP
PO
OH
+
H
OH
PO
OP
OP
OH DHAP
OH
(S,R) D-fructose 1,6-diphosphate
G3P
DHAP
O
OH
G3P
OH
OH
(S,S) D-tagatose 1,6-diphosphate
FIGURE 1.32. DHAP-dependent aldolases.
the best choice. The reported procedure consists of the phosphorylation of dihydroxyacetone dimmer with (PhO)2 POCl followed by hydrolysis of the dimmer to generate dihydroxyacetone phosphate in 61% yield.29 The chemically prepared DHAP is then used as an important material for the synthesis of natural monosaccharides and carbohydrates mimetics (Figure 1.36).
1.6. Synthesis of Carbohydrates Mimetics O
O
O L-FucP
PO
OH
+
OH
PO
H OH
OH
L-Lac
DHAP
+
OH
O L-FucP
OH
OH
(R,R) L-Fuculose 1-phosphate
O
O PO
25
PO
H OH
OH
L-Lac
DHAP
OH
(R,S) L-Rhamnulose 1-phosphate
FIGURE 1.32. (continued) PO HO HO
PO
OH O
OH
OH
i
OP HO HO
OH
O
OH
HO
i) rabbit muscle aldolase (RAMA), DHAP.
OP PO O
OH OH
i
OH
OH
OH OH O OH
OH
OP
i) rabbit muscle aldolase (RAMA), DHAP.
FIGURE 1.33. Enzymatic preparation pentose and hexose phosphate.
1.6 Synthesis of Carbohydrates Mimetics 1.6.1 Iminosugars This class of isosteric sugars also recognized as azasugars have been the subject of intense study because their significant activity as α-glycosidase inhibitors, which is a promising strategy in the treatment against diabetes mellitus type II and other glycosidase associated disorders. It is believed that the mechanism for glycosidase inhibition and to some extent for glycosyltransferases involves the binding of the aza sugars to the active site by charge-charge and hydrogen bond interactions.30 A significant variety and diversity of either naturally occurring or
26
1. Glycosides, Synthesis, and Characterization O HO HO HO
OH
NHAc O
CO2H i
HO
CO2H
OH
OH
O
AcHN OH
OH
i) NeuAc aldolase
OH HO
OH CO2H
O
AcHN OH
OH
FIGURE 1.34. Enzymatic preparation of sialic acid analogs. O
OH
R3
OH
OH
R3
i
H
HO R1
R2
O
R1
R2
R1 = OH; R2 = H; OH i) glucose isomerase
R 3 = H; OH; OCH3; F; N3
FIGURE 1.35. Enzymatic isomerization of fructose to glucose derivatives.
synthetic aza sugars with glycosidase and glycosyltransferase inhibition activity have been reported.31−35 The common feature of these derivatives is the replacement by chemical or enzymatic methods of the cyclic oxygen by a nitrogen atom. The representative example is known as deoxynojirimycin (Figure 1.37), which has shown strong inhibition against a variety of α-glycosidases. Representative examples of natural and synthetic aminoglucosides implicated in inflammation, metastasis, and blocking infection processes are depicted in Figure 1.38. Series of 1-N-iminosugars including D-glucose-type, D-galactose-type, Lfucose-type, D-glucuronic acid-type, and D-xylose-type were synthesized and evaluated as glycosidase inhibitors (Figure 1.39). A general procedure for the preparation of 1-N-iminosugars consisted in the azido substitution of a 5-tosyl-1-O-benzoate, followed by aldol reaction, Perlman hydrogenation and cyclization (Figure 1.40). Another chemical approach described for the preparation of iminosugars consisted in the use of protected L-serinal, which was subjected to Wittig elongation, diol formation, and 2-lithiothiazole treatment, to produce a common thiazole
1.6. Synthesis of Carbohydrates Mimetics
O
EtO
OH
O
OP
O
EtO
i
27
ii
HO HO
O
OEt
PO
OP
OEt
O
DHAP i) a) (PhO)2POCl. b) H2/PtO2. ii) H2O, 65oC.
TPI
O HO
OH
OP
O D-Gd-3P
dihydroxyacetone phosphate
Aldolase
DHAP
fructose 1,6-bisphosphate FDP
OP
OP OH O
HO HO
OP H+ (Dowex 50)
fructose 6-phosphate F-6-P
OP OH O
HO HO
Pase 100%
OH
HO HO
OH OH O OH
PGI
OH
OP O
glucose-6-phosphate HO HO G-6-P
OH
Pase
OH 100%
HO HO
O OH
OH
FIGURE 1.36. Chemoenzymatic preparation of glucose. R NH2 HO
HO
OH
FIGURE 1.37. Iminosugar deoxynojirimycin.
derivative. This intermediate under the appropriate conditions will give access to L-(-)-nojirimycin or L-(-)-mannonojirimycin (Figure 1.41).36 Chemoenzymatic preparation of glycosidase inhibitors Deoxynojirimycin and Deoxymannojirimycin was described by using RAMA-aldolase for the aldol
28
1. Glycosides, Synthesis, and Characterization O
HO HO
OH NH
HO HO
N
HO HO
HO
HO OH
HO
NH
N OH
OH
OH castanospermine
deoxymannonojirimycin
O
OH N
kifunensine
swainsonine
OH
HO
OH OH
CO2H
AcHN
OH OH
OH
OH
siastatin B
HO
OH
OH
HO
H3CS mannostatin
O
N
H N
NH2
OCH3 OH
Synthetic sucrase inhibitor
OH
N
NH
HO HO
HO
OH OH Glucosidase inhibitor
Nectricine
FIGURE 1.38. Representative aminosaccharides. OH
OH
OH
NH
HO
NH
OH
HO HO
OH
L-Fuc-type
D-Gal-type
D-Glc-type
CO2H
NH
H3C
HO HO
HO HO
NH D-GlcUA-type
NH D-Xyl-type
FIGURE 1.39. Series of 1-N-iminosugars. OH
OH O HO HO
TsO
i
OH
O O O
ii
N3
OBz
HO HO
OH OH
N
Boc
OH
HO
vi
v
OH
iii,iv
OH
OBz BzO BzO
O O O
HO HO
+
NH.HCl OH
i) a) Me2CO, H2SO4. b) TsCl/Py, 0oC to r.t. c) BzCl/Py. ii) NaN3/DMSO, 100oC. iii) a) NaOMe/MeOH. b) K2CO3/HCHO-MeOH. iv) a) H2 Pd(OH)2/MeOH. b) 1N HCl. v) a) Boc2O/Et3N/MeOH. b) BzCl/Py. vi) a) MeOCOCOCl/DMAP/CH3CN. b) Bu3SnH VAZO/CH3Ph. c) SiO2-iPrOH/H2O/NH2OH.
FIGURE 1.40. Synthesis of 1-N iminosugars.
OH
NH
NH.HCl
1.6. Synthesis of Carbohydrates Mimetics
NBoc O
i
NBoc O
CHO
O
N
CO2Et
O
O
O
iii
NBoc O
NBoc O N
O
iv
S
O
N O
OTBS
OAc v
NBoc O
NBoc O O
CHO O
O
CHO O
OTBS
OAc
vi
H N
HO HO
S
O
v
HO
S
NBoc O
ii
O
29
vi
OH OH
H N
HO HO HO
OH OH
i) a) Ph 3PCHCO 2Et, b) OsO 4, NMO, c) DMP, TsOH. ii) 2-lithiothiazole, Et2O iii) a) NaBH 4. b) TBSCl, imidazole iv) a) Red-Al, toluene, b) Ac 2O, Py, DMAP. v) a) MeI, MeCN. b) NaBH 4 c) HgCl2, MeCN, H 2O. vi) TFA, H 2O.
FIGURE 1.41. Chemical synthesis of L-(-)-nojirimycin and L-(-)mannonojirimycin.
condensation and hydrogenolysis for azide reduction and ring formation (Figure 1.42).37 Significant achievements have been made for the synthesis of aza sugars based on aldolase reactions particulary fructose-1,6-diphosphate,30 2-deoxyribose-5phosphate,38 fuculose-1-phosphate,39 sialic acid aldolase, and Pd/C-mediated reductive amination (Figure 1.43).
1.6.2 Aminosugars Aminosugars are another class of naturally and nonnaturally sugars which might be considered distinct to the previous in that the nitrogen is exocyclic. Their significance is clearly seen in a family of aminoglycoside antibiotics such as neomycin, kanamycin which are widely used against both gram-positive and gram-negative
FIGURE 1.42. Chemoenzymatic synthesis of iminosugar.
O
O PO
OH
+
H
N3 OH
i
OP
OP O OH OH
N3
O OH OH
+
OH
OH
ii
ii
HO
HO NH
HO HO
N3
OH NH
HO HO
OH i) FDP aldolase. ii) a) Pase. b) H2 /Pa
From fructose-1,6-diphosphate aldolase
OH
R NH
HO
HO HO
NH
NH
HO HO
R
OH
OH
R OH NH
HO NHAc
OH
R = OH, H
R = OH, H
R NHAc NH
HO HO
OH
OH
R
CH3
OH
HO
H
NH
R = H, CH3
R
N HO OH
HO
OH
OH
From fuculose-1-phosphate aldolase
From 2-deoxyribose-5-phosphate aldolase
HO
R
H N
NH HO
HO
OH
H N
R HO HO
OH OH NH
OH
R NH
HO OH
R = CH 3, CH2F
FIGURE 1.43. Aza sugars prepared by aldolase reactions.
R = OH, H
1.6. Synthesis of Carbohydrates Mimetics OH From sialic acid aldolase
OH
OH
HO
Me HO
OH
H
N
H N
31
CH3
OH
H N
HO
CO2H
OH
OH HO
OH HO2C
OH
H N
OH OH OH
FIGURE 1.43. (continued)
bacteria. Although there is no unified protocol for the synthesis of aminosugars, they have been roughly classified in (a) non-azido (Figure 1.44) and (b) azido approaches (Figure 1.45).40 (a) The non-azido methodologies usually involves the introduction of an amino group at C-2, and glycals are usually the starting materials.
OR OR RO RO
OR
i
O
O
RO RO BnO
RO RO
N N O
i) BnO2C N
ii
OBn
ref.41 OR
OR O
i
OR' NHAc
O
N CO2Bn, hv. ii) a) R'OH, Lewis acid b) Raney Ni. 3) Ac2O, Py
RO RO
O
O
RO RO
SPh NH
F3C O i) (saltmen)Mn(N)(CF3CO)2O. ii) PhSH/BF3-OEt2
ref.42 FIGURE 1.44. Non-azido methods for the preparation of aminosacharides.
32
1. Glycosides, Synthesis, and Characterization OR
OR
i
O
RO RO
O
RO RO
OR
NH
H3C O
i) a) thianthrene -5-oxide, AcNHSiMe3, Tf2O, Et2NPh. b) Amberlyst -15, HOR. 43
ref.
FIGURE 1.44. (continued)
(b) The azido approach is a more common procedure for amino introduction on sugars due its relative stability, good solubility in organic media, and easy conversion to amines through catalytic hydrogenolysis. Some of the methods reported involves the use of glycals, or protected saccharides containing free primary or secondary alcohols. Epimerization of hydroxyl groups can be achieved by following an oxidationreduction sequence in which a secondary alcohol is converted into a keto group, followed by stereoselective hydride reduction and nucleophilic substitution. It has been observed that epimerization by following the Mitsunobu protocol has not been
OAc
OAc O
AcO AcO
i
O
AcO AcO
OAc
N3
i) ClN3, CH2Cl2 (PhCO2)2
ref.44 OBn
OBn
OBn O
BnO
OBn O
i BnO
N3 i) Me3SiN3, Me3SiONO2
ref.45 FIGURE 1.45. Azido methods for the preparation of aminosacharides.
1.6. Synthesis of Carbohydrates Mimetics OBn
OBn
OBn
OBn O
i
O
33
OR
AcO
AcO
N3
R= NO2
ii
R=H i) CAN, NaN3, CH3CN, –15oC, 45%. PhSH, DIEA, 91%.
ref
64
OTs
OH
HO HO
i
O
ii
O
HO HO
O
HO HO OH
OH
N3
OR
OH
OR
i) TsCl, Py, r.t. ii) NaN3, DMF
ref 1 OBn
N3 i, ii
O
HO BnO
OBn O
BnO
OBn OMe
OBn OMe
i) Tf2O, Py/ CH2Cl2. ii) NaN3, DMF
ref 46 OAc AcO AcO AcO
OTf
i
O OAc
AcO AcO
O OAc N3
i) NaN3, DMF
ref 47,48 FIGURE 1.45. (continued)
OR
34
1. Glycosides, Synthesis, and Characterization OEt
O
SH
i
EtO
O ii
OH HO HO HO
S OH OH
iii
OH AcO S
AcO AcO
SH
HO
H
O
OH
iv
OH OAc
OH
AcO AcO AcO
S OAc
i) a) AcSK, AcSH. b) HCl. ii) a) DHAP FDP A. b) Pase. iii) Ac2O, Py. iv) Et3SiH, BF3.OEt2.
FIGURE 1.46. Synthesis of thiomonosaccharides.
probed satisfactorily due to steric hindrance of the secondary hydroxyl groups on the pyranose ring.40
1.6.3 Thiopyranoside Monosaccharides Thiosugars Sugars are another class of interesting carbohydrate mimetics. The synthesis of these derivatives can be achieved by using aldolases RAMA for the aldol condensation reaction.. The following reaction sequence was used successfully for the preparation of deoxygluco, manno, galacto, and altropyranosides (Figure 1.46).49 Another strategy for the synthesis of thiosugars involves the replacement of one of the oxygen atoms at the anomeric carbon of the glycoside by a sulfur atom leading to two distinctly different thiosugars, namely a 5-thio and 1-thioglycosides.50
1.6.4 Carbapyranoside-Saccharides More recently this type of sugar mimics have received increasing attention since some of them present α-glucosidase activity and therefore considered for therapies for non-insulin-dependent diabetes mellitus. Also they have been found to be active as agricultural antibiotics, and because of their recognition by glycosidases and glycosyltransferases as substrates and stability against enzymatic degradation, they have been used also to study oligosaccharide-chain biosynthesis.51,52 The pseudotetrasaccharide Acarbose (Figure 1.47) has been the first α-glucosidase inhibitor to be explored in humans as an antidiabetic agent along with the amino sugar 1-desoxynojirimycin Miglitol. The pathway in Figure 1.4853 has described the chemical synthesis of carbamaltose, carbacellobiose and related carbadisaccharides of biological interest. Pseudo-N-acetyllactosaminides were found to be acceptors substrates for human-milk α-(1→ 3/4)-fucosyltransferase. A small scale reaction of the
1.8. The Leaving Groups
35
OH HO HO
OH HN HO
CH3
O OH
OH
O HO
O OH OH
acarbose
O HO
O OH
OH
FIGURE 1.47. Pseudotetrasaccharide Acarbose.
mentioned pseudodisaccharides with GDF-fucose resulted in conversion to pseudotrisaccharides (Figure 1.49).51
1.7 Glycoside Reactivity The reactivity for the anomeric carbon C(1) is the typical for acetals, and therefore the nucleophilic addition may occur. On the other hand, the other hydroxyl groups behave typically for alcohols. For coupling reaction with sugars, the anomeric carbon is involved to produce a glycosidic bond, and usually must be activated with a good leaving group in order to form a new linkage (Figure 1.50). A glycoside is formed when the anomeric carbon of a sugar is connected through a heteroatom (except with C-glycosides) with an aliphatic or aromatic fragment known as aglycon. The glycosidic bond is formed when a nucleophile (alcohol, amine, thiol, or carbanion) substitutes the hydroxyl group at the anomeric position, which has been previously substituted by a good leaving group. Therefore, when the nucleophiles are an alcohol, amine, or carbanion, O-, N -, or C-glycosides are generated as result, as can be observed in Figure 1.51.
1.8 The Leaving Groups As mentioned above, the anomeric hydroxyl group can be replaced under suitable conditions with a good leaving group. Initially, the use of halogens such as fluorine, chlorine, and bromine was the strategy of choice, and particulary the last since it presents the best balance between reactivity and stability and this is why it has been extensively used for preparing glycosides. However, halides are in most cases labile and undergo decomposition. Consequently a number of other leaving groups have been designed for glycoside chemistry, and among them, imidates, sulfur, sulfonates, silyl groups, phoshates, and acetates are equally important alternatives.
36
1. Glycosides, Synthesis, and Characterization OBzl
Ph
O
O
O BzlO
Ph
O
+ HO
OR
O O BzlO
i
OBzl
BzlO BzlO
O BzlO
OMe
O BzlO
OMe
iv
Ph
O O BzlO
ii
iii
OBzl O O BzlO
Ph
BzlO
BzlO O
O BzlO
O
v
BzlO
O
O
OMe
O OBzl
OMe v
v
Ph
O O BzlO
OBzl OR O
Ph
O BzlO
BzlO O
O BzlO
BzlO
OMe
BzlO O
O OR
OR
OMe
Ph
OR
O O BzlO
iv
BzlO O
OMe
O OBzl
iv
AcO AcO AcO AcO
AcO AcO OAc AcO AcO
BzlO
79%
AcO 72%
iv
O OAc
OAc
O
O AcO
AcO O
OAc
OAc
AcO AcO AcO
AcO
OAc
AcO O
OAc
O OAc
60%
i) DMF, NaH, 15-crown-5 ether, 50oC, 60% ii) DMSO, Ac2O, r.t., 72% iii) DBU, PhCH3, 70oC, 56%. iv) a) FeCl3, Ac2O, – 20oC b) H2, Pd/C, EtOH. c) Ac2O, Py. v) NaBH4, CH2Cl2/MeOH, OoC.
FIGURE 1.48. Synthesis of carbapyranoside-disaccharides.
1.8. The Leaving Groups
FIGURE 1.49. Chemoenzymatic synthesis of pseudotrisaccharides.
OH HO
O
X HO
O(CH2)7CH3
OH
OH
37
NHAc i
OH HO
X
O O
O(CH2)7CH3
OH
OH
NHAc O
OH
H3 C X=O X = NH
HO OH
i) fucosyltransferase, GDP-Fuc.
The use of iodide has been restricted due to its low reactivity and fluoride although limitedly has been more used for preparation of some α-glycosides.54,55 It has been found that in the absence of selective conditions, a leaving group can be found as a mixture of anomers, as in the case of the acetates. However, some others such as bromide and imidate can be introduced preferentially at the α-position (Figure 1.52). A well-accepted hypothesis that explains the α-stereoselective preference assumed by the leaving group (halogens and imidate) is based on the anomeric effect, consisting in the electronic effect produced by the ring oxygen, which gives rise to a repulsive effect between one of the oxygen lone pairs and the leaving group, forcing the later to assume such position56 (Figure 1.53).
O
OH
O
X
X C
C
H
H OH
O C
H
X
X
O C
H
X = Halogen, sulfonyl, imidate, sulfur, acetate, etc.
FIGURE 1.50. Anomeric carbon and activation to a good leaving group.
38
1. Glycosides, Synthesis, and Characterization OR
OR
O
OR
O
OR OR
X
O
Nu
OR
OR
OR
X
Nu
OR
OR
+
OR
OR
Nu = R-OH, R-NH2, R-SH, RCH2X = halogen, acetate, imidate, sulfur, etc.
O
O
O
N
O
O
O
S
R
O
N
R
R
C
R
R
R
O
O
S
O
C R
R
FIGURE 1.51. Nucleophile displacement on the anomeric carbon and general types of glycosides.
OAc
OAc
O
OAc
O
X
OAc
OAc
OAc OAc
OAc
+
AcO
X OAc
FIGURE 1.52. Stereoselectivity of halides at the anomeric position.
OAc
OAc O
O
AcO AcO
AcO AcO OAc
X OAc
X
FIGURE 1.53. Anomeric effect on halogens.
1.9. Glycosyl Donors
39
1.9 Glycosyl Donors This term is used to define a glycosidic moiety that contains a leaving group at the anomeric position. When a glycosyl donor is reacted in the presence of a catalyst (also known as promoter) with a free alcohol called glycosyl acceptor, it will produce an O-glycosidic linkage. The first glycosyl donors developed and used specifically for glycoside formation were the glycoyl halides. As mentioned above, glycosyl bromide and chloride are the most widely used halides, and are the glycosyl donors used for the preparation of O-glycosides according to the methods reported by Michael, Koenigs-Knorr and Helferich (see O-glycoside formation). 2,3,4,6-Tetraacetyl-α-D-glucopyranosyl bromide also known as acetobromoglucose is one of the most extensively used sugar intermediates for preparing glycosides derived from glucose.57 The preparation involves in the initial peracetylation of glucose with acetic anhydride in the presence of a catalyst, commonly pyridine, triethylamine and dimethylaminopyridine, or sodium acetate and zinc chloride, in dichloromethane as solvent. The resulting 1,2,3,4,6-Pentaacetyl-α,β-D-glucopyranoside (as mixture of anomers) is treated with a 33% solution of HBr-acetic acid in dichlorometane at 5◦ C during 12 h. The final product is obtained after crystallization from isopropyl ether to yield acetobromoglucose as a white solid. The chloro derivative could be obtained similarly by using a controlled stream of HCl gas until saturation, or SOCl2 in DMF (Figure 1.54). When the sugar contains acid sensitive groups such as azide (Figure 1.55) or acid-sensitive protecting groups such as acetonide, or benzylidine (Figure 1.56), alternative milder conditions have been developed. Such is the case of fosgene in DMF and bromotrimethylsilane (TMS-Br) for chlorination and bromination, respectively.22 OAc O OH
OAc
O
O
ii OH
i OH
OAc
OAc OAc
OAc iii
OH
OH
OAc
Br OAc OAc
OAc
O OAc i) Ac2O, DMAP, Et3N, CH2Cl2. ii) HBr/AcOH 33% iii) HCl (g), CH2Cl2.
OAc
Cl OAc
FIGURE 1.54. Standard conditions for preparation of acetobromo and acetochloroglucose.
40
1. Glycosides, Synthesis, and Characterization Cl O
AcO
OH
i
AcO
N3
O N3
i) (COCl)2, DMF, CH2-CH2
FIGURE 1.55. Preparation of azide glycosyl donors.
Ph
O O AcO
i
O OAc
OAc
Ph
O O AcO
O OAc Br
i) TMS-Br, CH2Cl2.
FIGURE 1.56. Anomeric bromination in acid sensitive sugars.
The 1 H NMR spectrum of acetobromoglucose shows signals for each of the ring protons, as well as for the primarily alcohol and acetates. The well-defined spectrum allows the net identification of each proton, starting from the anomeric proton at δ 6.60 shifted downfield due to the presence of the halogen, with coupling constant of 4 Hz indicating an equatorial-axial interaction with H-2. Diaxial interactions are evident as triplets for H-3 and H-4, and axial-equatorial as double of double for H-2 (Figure 1.57). Besides their extensive use in the preparation of glycosides, glycosyl bromide can also be useful for conversion to other suitable glycosyl donors (Figure 1.58),
FIGURE 1.57. 1 H NMR spectrum of acetobromoglucose in CDCl3 .
1.9. Glycosyl Donors OAc
41
OAc O
AcO
Zn/AcOH
AcO
O AcO AcO
OAc Br
OAc
OAc
O
O
i
AcO AcO
AcO AcO
50oC, 12 h, 85%
OAc
O
Br
O
H 3C
OR
i) EtOH, sym-collidine, Tetra-n-butyl-ammonium bromide OAc O
HO
OAc
O
O AcO AcO
+
HO HO
OAc
i
AcO AcO
OH
O
O
H3C
O
OMe
Br
O HO HO
OH
i) AgOTf, Lutidine, DMF, r.t.
OMe
OAc
OAc AcO AcO
O
PhSNa
OAc
EtOH-H2O
O AcO AcO
SPh OAc
Br
OAc
OAc
Bu4NSAc
O AcO AcO
OAc OAc
O AcO AcO
SAc OAc
Br OAc O
Acetone, H2O
AcO AcO
Ag2CO3
OAc Br
75-80%
O AcO AcO OAc OH
FIGURE 1.58. Some glycosyl donors obtained from acetobromoglucose.
42
1. Glycosides, Synthesis, and Characterization OAc
OAc O
NaN3
AcO AcO
O AcO AcO
OAc
N3 OAc
Br
OAc
OAc
HO
O
O
AcO AcO OAc
AcO AcO
i
O OAc
Br i) Hg(CN)2, HgBr2, CH3CN, 4 MS, 12h, 60%
FIGURE 1.58. (continued)
such as glycals,58 othoesthers,59 ad thiols.60 Also, the glycosyl halides can be transformed to glycosyl imidate through the anomeric hydroxyl formation,61 or to amines via a reaction with azide salt and hydrogenolysis.52 More recently a “disarmed” glycosyl iodide derived from glucuronolactone was designed for O-glycosidation. The iodosugar has proved to be a flexible donor, reacting under mild conditions (Figure 1.59).62 Glycosyl acetates are also important glycosyl donors and can be used directly under the fusion strategy for the preparation of O- and N -glycosides. The fusion method consists of the reaction between the glycosyl acetate as glycosyl donor with the glycosyl acceptor in the presence of a Lewis acid as a promoter to generate the corresponding glycoside. Likewise, acetates can also be suitable precursors for the preparation of glycosyl donors such halides, thiols.63 and to imidates, the latter by a two-step process. The first step involves the removal of the anomeric acetate with base, among them hydrazine, benzylamine, ammonia, and piperidine, which are the most preferred. The resulting hydroxyl group is obtained as a mixture of anomers and is subsequently used for the preparation of the glycosyl imidate (see Imidate
CO2Me O
Me3CCO2 Me3CCO2
CO2Me R-OH
i
Me3CCO2
Me3CCO2 Me3CCO2 Me3CCO2
I i) NIS/I2, then TMSOTf.
FIGURE 1.59. Glucuronyl iodide as a glycosyl donor.
O OR
1.10. Protecting Groups
43
Method). Another use of glycosyl acetates is the transformation into anomeric amines, through the introduction of the azide group with trimethylsilyl azide under a Lewis acid catalyst, and further hydrogenolysis.64 This reaction is useful for the preparation of some glycopeptides. Likewise 2-thiophenyl glycosides of Neu5Ac are suitably obtained by treatment of 2-O-acetyl, 2-chloro, or 2-chloro Neu5Ac glycosyl donors with PhSH in the presence of NIS/TfOH as promoter system (Figure 1.60). Other activated agents for preparing S-alkyl and S-aryl glycosyl donors are methyl trifluoromethanesulfonate (MeOTf), dimethyl(methylthio)sulfonium trifluoromethanesulfonate (DMTST), iodo dicollidine perchlorate (IDCP), and phenyl selenyl trifluoromethanesulfonate (PhSeOTf)65. Thioglycosides are stable glycosyl donors widely used for the preparation of glycosides. The usual conditions for achieving this goal are the glycosyl acceptor and N-iodosuccinimide (NIS), or NIS-TfOH as promoter. Thioglycosides are also important starting material for the preparation of other glycosyl donors such as acetates, fluorine,63 chlorine,68 sulfoxides,69 or anomeric alcohols (Figure 1.61). Glycals are becoming potentially useful glycosyl donors, and an increasing number of simple and complex glycosides have been reported. For this purpose the glycal is usually transformed to the oxirane. and immediately coupled with the glycosyl acceptor in the presence of a Lewis acid (see The Glycal Method). Moreover, glycals are also suitable intermediates for the preparation of a variety of glycosyl donors (Figure 1.62) such as phosphates and thiophosphates,70 deoxysugars,71 Diels-Alder adducts,72 allyl glycosyl donors,73 and imidates.74
1.10 Protecting Groups An important additional requirement for achieving glycosidic coupling reactions, besides the fact that a good leaving group should be present, is the appropriate use of protecting groups. Their function is to shield those groups (particularly heteroatoms) that are wanted to keep unaltered during the coupling reaction and then release them under mild conditions that do not affect the glycosidic bond (Figure 1.63). A significant number of protecting groups75 have been used and combined for pursuing the synthesis of complex natural products including glycosides. Due to its acetal character, the glycosidic bond is hydrolyzed under acidic conditions, and is significantly more resistant to base, hydride reduction or hydrogenolysis. The use of ethers such as methyl ether (-O-CH3 ), methoxymethyl ether (-O-CH2 OCH3 , MOM), 2-methoxyethoxymethyl ether (-O-CH2 OCH2 CH2 OCH3 , MEM), and tetrahydropyranyl ether (-O-2-c-C5 H9 O, THP) have been widely used for protection of alcohols. However, in glycoside synthesis attention has to be paid since deprotection is carry out under acidic conditions, which might be hazardous for the glycosidic bond. Silyl derivatives are also another important choice for protection of hydroxyl group.65 Some of the most accepted silyl derivatives for carbohydrate hydroxyl protection are tert-butyl dimethylsilyl (TBDMS),
44
1. Glycosides, Synthesis, and Characterization OAc i
O AcO AcO
OAc
SPh OAc
O AcO AcO
OAc OAc
OAc
O
ii
AcO AcO
SMe OAc
i) PhSH (1.1 eq.), SnCl4 (0.7 eq.), CH2Cl2, 0oC, 4h, 82%. ii) MeSH (excess), SnCl4 (0.7 eq.), CH2Cl2, –20oC, 3h, 85%.
OAc
OAc
R
OAc
AcO
CO2Me
O
i
AcO
AcO
CO2Me
O AcO
OAc OAc
OAc OAc R = Cl, Br
i) TiCl4 or TiBr4
Ref.66 CO2Me
OAc AcO
X
O
AcHN
CO2Me
OAc i
AcO O
AcHN
SPh
OAc OAc
OAc OAc X = OAc, Cl, F.
i) PhSH, NIS/TfOH.
Ref.67 OAc
OAc O
AcO AcO OAc
NH2-NH2
OAc
O AcO AcO OAc
OH
FIGURE 1.60. Preparation of glycosyl donors and precursors from glycosyl acetates.
1.10. Protecting Groups
45
OAc Cl3CCN
O AcO AcO
Cs2CO3, CH2Cl2
OAc
NH
O
CCl3 OAc
OAc
OAc
O
AcO AcO
O
Me3SiN3 AcO
OAc
AcO
OAc
OAc
H2-Ni Raney
O
AcO AcO
N3
OAc
FIGURE 1.60. (continued) OAc
OAc O
AcO AcO
AcOH, NIS
SEt OAc
O AcO AcO
OAc OAc
OR
OR O
RO RO
R2SCl2
SR OR
O RO RO
Cl OR
O OTBDPS
O OTBDPS O
O
DMTST, DAST
SPh
O
F
O
OPiv
OPiv
OR
OR O
RO RO
mCPBA
SPh OR
O RO RO
O S
Ph
OR
FIGURE 1.61. Modifications of thio glycosyl donors.
triisopropylsilyl (TIPS), tert-butyl diphenylsilyl (TBDPS), and triethylsilyl (TES) ethers. Quantitative cleavage is usually achieved upon treatment with tetrabutylammonium fluoride (TBAF) or HF/pyridine. The most suitable protecting groups for the preparation of glycosides are the affordable acetates, benzoates and benzyl protecting groups since they can be
NH2
46
1. Glycosides, Synthesis, and Characterization OR
OR O
RO RO
OR O
RO RO
DMDO
HSP(O)(OEt)2
O
RO RO O
OH
OR
OR NIS
O
RO RO
CH3CN-H2O
OR O
RO RO
X
Y
O
RO RO
Na2S2O4
O X
BnO PMBO
OBn O
i
OH
OR RO RO
OBn
O
RO RO
OH H2O-DMF
I
OR
O S P OEt OEt
Y
OBn O
BnO PMBO
ii
O
BnO PMBO
O OH
O i) DMDO-acetone. ii) ally alcohol, r.t., 16h, 79%.
OBn
OBn BnO BnO
O
i
BnO BnO
O N3 O
i) a) (NH4)2Ce(NO3)6, 53%. b) Cl3CCN, NaH, 98%.
NH CCl3
FIGURE 1.62. Preparation of glycosyl donors and precursors from glycals.
removed under basic and for the later neutral conditions, being the best conditions for preserving the glycosidic bond. The standard conditions for either installing and removing the most common protecting group described are: Acetate (Ac-): The standard procedure involves the use of acetic anhydride in the presence of pyridine or triethylamine as acid scavenger, and 4-(dimethylamino) pyridine (DMAP) that improves the rate of reaction. The cleavage of acetates proceeds smoothly with NaOMe solution also known as Zemplen conditions. Acetates are stable at pH from 1-8 and can be cleaved with lithium aluminium hydride (Figure 1.64).
1.10. Protecting Groups G1P
E X
E
Y
X
1) PG1
Y
X
PG2
Y
1) PG2
2) E
2) E
PG cleavage
PG cleavage
E X
47
E
Y
X
Y
FIGURE 1.63. Schematic representation of protecting group applicability. OH
OAc O
HO HO
i
OH OH
O AcO AcO
OAc OAc
i) Ac2O, CH2Cl2, Et3N, DMAP, r.t.
FIGURE 1.64. Standard protocol for the preparation of peracetylated sugars.
Benzoyl (Bz-): This protecting group is more stable to hydrolysis than acetates and may resist a pH up to 10. The conditions for protection of alcohols are shown in Figure 1.65 and involves the use of benzoyl chloride in pyridine or triethylamine.76 It is stable to hydrogenolysis and borohydrides but not to lithium aluminium hydride. The cleavage is usually achieved in 1% NaOMe-MeOH solution. Pivaloyl (Pv-): This protecting group, which is also known as Trimethylacetyl chloride, is used for protection of primary and secondary alcohols in yield. An example of the use of this group is the protection of the hydroxyl group at position 2 of fucose derivative.77 The standard conditions for protection are pivaloyl chloride in pyridine or DMAP and the cleavage is performed with Bu4 N+− OH at 20◦ C (Figure 1.66). Trityl (Tr-): This bulky protecting group is selective for primary alcohols (Figure 1.67). The protecting reaction proceeds in pyridine or DMAP-DMF.78 The cleavage can be performed under neutral conditions with 1% iodide in methanol, or weakly acidic in formic acid-ether solution. Benzyl (Bn-): This protecting group when attached with alcohol generates an ether (Figure 1.68). However, unlike common ethers, this can be cleaved under neutral condition by hydrogenolysis. The usual conditions for attachment are NaH, THF, and benzyl bromide or chloride.79 The conditions for removing this group are hydrogen, Pd/C 10% or Pd(OH)2 /C 10% in ethanol or ethyl acetate.
48
1. Glycosides, Synthesis, and Characterization O Cl
R-OH
O +
R
Py, OoC
N
Ph
O
H Cl
OTBDMS
OTBDMS
O
BzCl-Py
O HO HO
BzO BzO
O
O NTCP
NTCP
OTBDPS
OTBDPS O
HO
i
SPh
BzO
SPh
HO
O
BzO
OBz
OH
i) PhCOCl (4.0 eq.), Et3N (8.0 eq.), 4-DMAP (0.2 eq), THF, 50oC, 15h, 92%.
FIGURE 1.65. General procedure for the benzoylation of sugars.
p-Methoxybenzyl (PMB-): This benzyl derivative is installed by reacting the free alcohol with PMB-Cl under NaH, DMF conditions at 0◦ C.80 An example of its applications can be seen in the protection at the second position of acetonide thioglycoside shown in Figure 1.69. Deprotection is carried out under neutral
O O
Cl R
R-OH
+
O
Py, OoC to r.t.
O
N H Cl
O
Me O
Me
i
O
O O
OH OBn
OPv OBn
i) PvCl, Py, DMAP, 70oC, 80%.
FIGURE 1.66. Conditions and reagents for protection of alcohols with pivaloyl group.
1.10. Protecting Groups
49
TrO
HO
O
O Tr–Cl
OH
OH
OH
OH
Py
OH
OH
OH
OH Tr- = (Ph)3C-
FIGURE 1.67. Protection of primary alcohol with trityl protecting group.
Br
R-OH
NaH, THF
+
R O
OH
OBn
HO
Ph
O
i
HO
Ph
O
70%
O H3CO
NaBr + H2O
Ph
O
O
H3CO
O
i) BnCl, NaH, CuCl2, Bu4N+I–, THF, reflux, 25 h.
FIGURE 1.68. General conditions for benzylation of carbohydrates.
PMBO
HO PhS
O O O
i
PhS
O O O
i) NaH, DMF, 0oC, 30 min., then 1.2 equiv. PMB-Cl, 2 h, 93%.
FIGURE 1.69. General conditions for benzylation of carbohydrates with PMB.
conditions with 2,3-dichhloro,5,6-dicyano-1,4-benzoquinone (DDQ), in CH2 Cl2 H2 O (20:1), 1 h, at 25◦ C, in a 91% deprotection yield. Acetonide ((CH3 )2 C(O)2 -): This protecting group is useful for protection of cis diols (Figure 1.70) and the conditions are acetone, 2,2-dimethoxypropane, and ptoluenesulfonic acid or camphorsulfonic acid as catalyst.81 Acetonides are usually stable at a pH between 4 and 12, and the regeneration of the diol can be achieved by treatment with aqueous acid.
50
1. Glycosides, Synthesis, and Characterization OH
O
H3 C
H3C
O
i
O
O
HO
O
O
OH
OH
i) (CH3)2C(OCH3)2, camphorsulfonic acid, DMF, r.t., 3 h
FIGURE 1.70. Acetonide formation for protection of diols.
Benzylidene (PhCH(O)2 -): This classical protecting group is usually selected for protection of position 6 and 4, allowing the remaining positions to be modified. The benzylidene is attached under mild conditions and are useful for either –OH (4) in axial or equatorial positions (Figure 1.71). Deprotection can be effected under different conditions, such as acid conditions, hydrogenolysis, and hydrides such as BH3 NMe3 , AlCl3 , THF, 60◦ C, 1 h.82 Carbonate (O=C(O)2 -): This group is suitable for protection of cis diols, and it has been used in the synthesis of complex oligosaccharides and also in solidphase oligosaccharide synthesis. The reagents and conditions used for protection are phosgene in pyridine at 0◦ C during 1 h (Figure 1.72), and the yield reported is around 70%.83 Boronate (PhB(O)2 -): This group has been proposed in solid-phase oligosaccharide synthesis84 for simultaneous protection of 4,6-OH groups (Figure 1.73). Deprotection is achieved with IRA-743 resin.85 Tert-butyldimethylsilyl (TBS)More recently introduced for protection of primary and secondary alcohols with reported yield protection around 90% (Figure 1.74). The standard conditions are
HO O HO HO
C6H5CH(OMe)2 SPh TsOH, MeCN, 2h
OH
O
Ph
O O SPh
HO OH BnO
O
Ph
BH3NMe3, AlCl3
O O SPh
AcO OAc
THF
O HO AcO
SPh OAc
FIGURE 1.71. Protection of 4 and 6 hydroxyl groups with benzylidene group and partial removal.
1.10. Protecting Groups
51
SPh SPh O
i
O
HO
HO
O HO
O
OH O o
i) (Cl2)C=O, Py, 0 C, 1h, 69%.
FIGURE 1.72. Standard conditions for protection of diols with carbonate protecting group. Ph B O O
OH
OH
O
i
O
SEt
HO
SEt
HO
OH
OH
i) PhB(OH)2.
FIGURE 1.73. Protection of 4,6-OH groups with boronate. OH
OTBDPS O
OTBS
OTBDPS O
i
HO
TBSO
i) TBSOTf, Py. PMBO PhS
PMBO OH
i
PhS
O
OTBS O
OH
OTBS
i) TBSOTf (4.0 eq.), Et3N (10.0 eq.), CH2Cl2, 0oC, 2h, 97%.
FIGURE 1.74. Protection of secondary alcohols with TBS protecting group.
tert-butyldimethylsilyltriflate in pyridine,86 and deprotection is usually achieved with butyl ammonium fluoride (Bu4 NF) in THF. tert-butyldiphenylsilyl (TBDPS-): This protecting group is specific for primary alcohols and the yields reported are quantitatives (Figure 1.75). This bulky silylated
52
1. Glycosides, Synthesis, and Characterization OH
OTBDPS
HO
HO
O
i
HO
O
SPh
HO
SPh
OH
OH
i) t-BuPh2SiCl, imidazole, DMF, 100%.
FIGURE 1.75. Protection of primary alcohols with TBDPS protecting group.
group has been used for the assembly of oligosaccharide libraries and has been compatible with the use of other highly selective groups.87 The standard protection conditions are TBDPS-Cl, imidazole, DMF or THF. Deprotection is achieved with hydrogen fluoride-pyridine or TBAF, cat. AcOH, THF, and a yield of 87%.
1.11 Selective Protections HO i
O
HO HO
TBDMSO O
BzO BzO
O OH
O NTCP
i) TBDMSCl/Py. ii) BzCl/Py.
Ref.76 HO
HO
O
O
OH
O
O
OAllyl
i
O
O
i) CH2=CHCH2OCO2Et, Pd2(dba)3, THF, 65 oC, 4h, 70%.
Ref.88 FIGURE 1.76. Miscellaneous selective protections
1.11. Selective Protections OBn
OBn ZHN
OH
H3CO
ZHN
i
OH
O
OH
H3CO
OPhOCH3
O
Z = benzyloxycarbonyl i) 4-CH3OC6H5OH, THF, D EAD, Ph3P, 80oC, 82%.
Ref.80 OH
OH HO
H3CO
HO
OH OH
O
OH
i
H3CO
O
OTr
i) Ph3CCl, DMAP, DMF, 25oC, 12h, 88%.
Ref.89 OTMS
OH HO
H3CO
OH
TMSO
i
OH
O
H3CO
OTMS
O
OTMS
i) Me3SiCl, Et3N, THF, 25oC, 8h, 90%.
Ref.90 OH
OH HO
EtS
OH
O
AcO
OH
i
CH3
i) MeC(OCH3) 3, TsOH, DMF, 96%.
Ref.91 FIGURE 1.76. (continued)
EtS
O
CH3
53
54
1. Glycosides, Synthesis, and Characterization Ph
O O HO
Ph
i
O OH
O O AcO
O OH
OCH3
OCH3
i) Lipase AK, vinyl acetate, 92% 92
Ref.
OH
OH
HO
OH
HO
i
OH
OH EtO
OAc
O
EtO
O
i) Pancreatin, vinyl acetate, THF, TEA 95%.
Ref.93 H3C
OH
H3C
i
OH
OH EtO
OBz
O
EtO
O
i) Ph3P, DIAD, PhCO2H, THF, 84%. 94
Ref.
Ph
O O HO
Ph
i
O OH
O O HO
O OBz
OAllyl
OAllyl
i) BzOBt, 92% 95
Ref.
OH
OH HO
O
Ph O
H3CO
O
−
i
O
O3SO
Ph O
H3CO
i) Pyr SO3, Pyr, 69%
Ref.96 FIGURE 1.76. (continued)
O
1.11. Selective Protections
HO HO HO
O
i
O
55
O
O O
OH
O
OCH3
OCH3
O i) DMSO, POCl3, 85%.
Ref.97 OH
OH
HO
OH
HO
i
O
OH HO
O
O
H3CO
O
i) CH2=C(CH3)OCH3, DMF, TsOH. 0oC, 95%
Ref.98 OCH3 i
O
H3 C O
OCH3
OPv
O
H3C
O
OH OBn
Ph
Bn = PhCH2−
OPv
i) NBS, CCl4, 75%.
Ref.99 R O
O HO HO HO
R O
EtO
Z Y
i
OEt
R R
O O HO
O Z Y
i) PPTS, ACN. 90%
Ref.100 FIGURE 1.76. (continued)
56
1. Glycosides, Synthesis, and Characterization OH O
HO HO
O O HO
Ph
i
SPh OH
O SPh OH
i) C6H5CH(OMe)2, TsOH, MeCN, 2h. 82
Ref.
OH O
HO HO
OPiv
OH O
O HO
OH
i
HO HO
SPh
OH
OH
OPiv
O O HO
O SPh OH
i) Pivaloyl chloride, Py, 91%.
Ref.101 O
OH
O
HO
OH
O
i
H3CO
O
CH3
H3CO
OH
O
CH3
i) Cl3CCOCl, Py, rt, 80%
Ref.102
O OTBDPS HO HO
Br
Br
Br
O
OTBDPS
O O
O
O O OH
OH
O
OMe
Br 103
Ref.
FIGURE 1.76. (continued)
OMe
1.11. Selective Protections AcS
NaO3S
OBz
OBz O
i
O
57
BzO
BzO
BzHN
BzHN
OMe
OMe
i) aq. H2O2 (33%), AcOH, NaOAc, 80oC, 8h.
Ref.104 OBn
OBn O
BnO BnO
i
O
BnO BnO O
O
i) DMDO, ZnCl2, acetone.
OH O
HO HO
OTIBS i
OTIBS
O
HO HO
ii
O
HO BnO
i) TIBS-Cl, Imidazole. ii) Bu2SnO, BnBr, TBAI, 67%
Ref.105 OH HO HO
OH
O OH
i
HO HO
NH2.HCl
O OH NHAc
i) a) 1eq. NaOMe/MeOH. b) 1.2 eq. Ac2O, 12h, 91%.
Ref.106 Ph
O O HO
O
i
OMe OAc
Ph
O O ROOC
O OMe OAc
i) TMEDA, ClCO2R, CH2Cl2, 0oC.
Ref.107 FIGURE 1.76. (continued)
58
1. Glycosides, Synthesis, and Characterization HO
OTBDPS
OTBDPS
TBSO i
O
O
HO
TBSO
TBDPS = tert-butyldiphenylsilyl TBS = tert-butyl dimethylsilyl i) TBSOTf, Py.
Ref.
86
OCH3
OH
H3CO OH
HO
OBz
OCH3
C6H4-p-OMe
O
BzO
CH3 H3CO
i
OH O
O
H3CO
O
i) pyridinium p-toluensulfonate, 82-100%.
Ref.108 OH HO HO
OAc
O OH
i,ii
OCH3
HO AcO
O OAc
OCH3
i) (Bn3Sn)2O, PhMe. ii) AcCl, r.t.
Ref.109 FIGURE 1.76. (continued) TABLE 1.3. Summary of common protecting and cleavage conditions. Protecting group
Protection conditions
Acetyl (Ac-) Ac2 O, Et3 N, DMAP, CH2 Cl2 Benzoyl (Bz-) Bz-Cl, Py Pivaloyl (Pv-) Pv-Cl, Py, DMAP Trityl (Tr-) Tr-Cl, DMAP, DMF Benzyl (Bn-) Bn-Br, NaH, THF p-Methoxybenzyl (PMB-) PMB-Cl, NaH, THF Acetonide ((CH3 )2 C(O)2 -) (CH3 )2 CO, 2,2-DMP, p-TSOH PhCH(OCH3 )2 , p-TsOH, CH3 CN Benzylidene (PhCH(O)2 -) tert-butyldimethylsilyl (TBS-) TBS-OTf-Py tert-butyldiphenylsilyl (TBDPS-) TBDPS-Cl-imidazole, DMF
Cleavage conditions NaOMe-MeOH NaOMe-MeOH Bu4 NOH 1% I2 -MeOH H2 -Pd(OH)2 -EtOH DDQ, CH2 Cl2 -H2 O AcOH-H2 O AcOH-H2 O, or H2 -Pd(OH)2 Bu4NF-THF HF-Py
1.12. Selective Deprotections
59
1.12 Selective Deprotections TrO
HO
O OAc
AcO AcO
O
i
AcO AcO
OAc
OAc OAc
i) 1% I2, MeOH.
Ref.110 OAc
OAc ThPhN
OAc
PhThN
i
OAc
OAc
HO
O
MPMO
OAc
O
PhTh = phthalimido. MPM = p-Methoxybenzyl ether p-MeOC6H4CH2OR i) CAN or NBS, CH2Cl2, H 2O.
Ref.111 i
O AcO AcO
O
OCH3
HO AcO
OAc
OCH3
OAc
i) Lipase PS, n-pentyl-OH, 93%
Ref.112 OBn BnO
OH
i
OBn Me BnO
H3CO
O
O
O H3CO
O
Me
O
Ph OBn i
BnO
Ph OBn OH
H3CO
O
i) LiAlH4, AlCl3, Et2O, CH2Cl2, heat
Ref.113 FIGURE 1.77. Miscellaneous selective deprotections.
60
1. Glycosides, Synthesis, and Characterization OAc
OAc O
O
BzO
Me
O
Ph
O
O O
O
Br
O
i) BrCCl3, CCl4, hv, 30 min. 100%
Ref.114 Ph O
OH
O
OH
i
O
O
OMe
OMe
i) H2, Pd(OH)2, EtOH, 92%
Ref.94 Ph O
OBz
O i
TBSO
Me
i
O
TBSO
OMe
i) NBS, BaCO3, CCl4,∆
Ref.115 FIGURE 1.77. (continued)
O OMe
Br
1.12. Selective Deprotections
Si
OH
O
HO
O
Si
O Si
HO
i
O
O
Si RO
OH
O
O
61
RO
O
i) DMF, H+, 82%
Ref.116 t-Bu
Ph O Ph HO
O SiMe3
OH
O
HO HO
i
O
O SiMe3
OH
i) Bu4NF.3 H2O, AcOH, THF.
Ref.117 O
AcO AcO
i
O
AcO AcO
OAc OAc
OH OAc
i) CF3COOH, CH2Cl2.
O O H3C
i
O AcO
OR O
OR OH
OCH3 i) AcOH, 100%. 118
Ref.
OAc AcO AcO
OAc
O OAc
i
OAc
AcO AcO
i) a) BnNH2, THF. b) HCl.
Ref.86 FIGURE 1.77. (continued)
O OAc
OH
62
1. Glycosides, Synthesis, and Characterization OTMS
OTMS OTMS
TMSO
OTMS
H3CO
OTMS
TMSO
i
OH
H3CO
O
O
i) K2CO3 , MeOH, 0oC, 45 min, 100%
Ref.119 Ph
O O BnO
BnO HO BnO
i
O O
(CH2)3
NTCP
O O (CH2)3
NTCP
i) a) NaBH3CN. b) HCl, THF, Et2O
Ref.76 OBz
OBz C6H4-p-OMe
O
BzO
OH
BzO
i
CH3 O
H3CO
OH
H3CO
O
O
i) a) SnCl4, CH2Cl2, −78oC. b) Bu4NOH, 90%.
Ref.108 OBn O
BnO
H3CO
OBn i
OH
BnO
O
BnO +
O O
OBn
H3CO
O O 79%
i) a) NaBH3CN. b) HCl, THF.
Ref.120 FIGURE 1.77. (continued)
H3CO
OH O
References
63
OBn OH
BnO
i
OMPM
H3CO
O
OBn OBn
H3CO
OMPM
BnO ii
C6H4-p-OMe
O
BnO
OH
H3CO
O
O
O OBn OH
BnO
iii
OH
H3CO
O
i) NaBH3CN. b) TFA, DMF. ii) a) NaBH3CN. b) TMSCl, CH3CN. iii) CAN, CH3CN-H2O (9:1), 95%.
Ref.121 OBn
OBn O
BnO BnO
i
BnO
N3 O AllO
OPBB
BnO BnO
OBn OBn
O BnO
N3
OPBB
O HO
PBB = p-bromobenzyl i) Pd(OAc)2, (o-biphenyl)P(tBu)2, PhN(H)Me, NaO tBu, 80oC. ii) SnCl4, 84%.
Ref.122 FIGURE 1.77. (continued)
References 1. 2. 3. 4. 5.
J.F. Robyt, Essentials of Carbohydrate Chemistry, Springer, NY (1998). H.S. Khadem, Carbohydrate Chemistry, Academic Press, NY (1988). E. Fischer, Ber. 23, 2114 (1890). G. Casiraghi, F. Zanardi, G. Rassu, and P. Spanu, Chem. Rev. 95, 1677 (1995) T.-H. Chan, and C-J. Li J. Chem. Soc. Chem. Commun. 747 (1992)
OBn OBn
64
1. Glycosides, Synthesis, and Characterization
6. J. Gao, R. H¨artner, D.M. Gordon, and G.M. Whitesides, J. Org. Chem. 59, 3714 (1994). 7. R.H. Prenner, W.H. Binder, and W. Schmid, Liebigs Ann. Chem. 73 (1994). 8. K.-I. Sato, T. Miyata, I. Tanai., and Y. Yonezawa, Chem. Lett. 129 (1994). 9. S.G. Davies, R.L. Nicholson., and A.D. Smith, Synlett 1637 (2002). 10. A.B. Northrup, I.K. Mangion, F. Hettche, and D.W.C. MacMillan, Angew. Chem. Int. Ed. 43, 2152 (2004). 11. A. Lubineau, J. Aug´e, and N. Lubin, Tetrahedron 49, 4639 (1993). 12. G. Casiraghi, L. Pinna, G. Rassu, P. Spanu., and F. Ulheri, Tetrahedron: Assimetry 3, 681 (1993). 13. S.A.W. Gruner, E. Locardi, E. Lohof, and H. Kessler, Chem Rev. 102, 491 (2002). 14. M.P. Watterson, L. Pickering, M.D. Smith, S.J. Hudson, P.R. Marsh, J.E. Mordaunt, D.J. Watkin, C.J. Newman, and G.W.J. Fleet, Tetrahedron: Asymmetry 10, 1855 (1999). 15. N.L. Hungerford, and G.W.J. Fleet, J. Chem. Soc. Perkin Trans. 1 3680 (2000). 16. A. Dondoni, A. Marra, Chem Rev. 100, 4395 (2000). 17. M.J. Robins, and J.M.R. Parker. Can. J. Chem. 61, 312 (1983). 18. J.R. Axon, and A.L.J. Beckwith, J. Chem. Soc. , Chem. Commun. 549 (1995). 19. G. Li, H.H. Angert, and K.B. Sharpless, Angew. Chem. Int. Ed. Engl. 35, 2813 (1996). 20. O. Jarreton, T. Skrydstrup, J.-F. Espinosa, J. Jim´enez-Barbero, and J.-M. Beau, Chem. Eur. J. 5, 430 (1999). 21. Y. Ohnishi, and Y. Ichikawa, Bioorg. Med. Chem. Lett. 12, 997 (2002). 22. M. Oberthur, C. Leimkuhler, and D. Kahne, Org. Lett. 6, 2873 (2004). 23. O. Meyerhof, and K. Lohmann, Biochem. Z. 271, 89 (1934). 24. H.M. Gijsen, L. Qiao, W. Fitz, and C.-H. Wong, Chem. Rev. 96, 443 (1996). 25. M.D. Bednarski, H.J. Waldmann, and G.M. Whitesides, Tetrahedron Lett. 27, 5807 (1986). 26. W. Baumann, J. Freidenreich, G. Weisshaar, R. Brossmer, and H. Friebolin, Biol. Chem. 370, 141 (1989). 27. G.J. Boguslawski, J. App. Biochem. 5, 186 (1983). 28. J.R. Durrwachter, and C.-H. Wong, J. Org. Chem. 53, 4175 (1988). 29. S.-H. Jung, J.H. Jeong, P. Miller, and C.-H. Wong, J. Org. Chem. 59, 7182 (1994). 30. G.C. Look, Ch.H. Fotsch, and C.-H. Wong, Acc. Chem. Res. 26, 182 (1993). 31. T. Aoyagi, T. Yamamoto, K. Kojiri, H. Morishima, M. Nagai, M. Hamada, T. Takechi, and H. Umezawa, J. Antibiot. 42, 883 (1989). 32. R. Saul, R.J. Moylneux, and A.D. Elbein, Arch. Biochem. Biophys. 230, 668 (1984). 33. H. Kayakiri, K. Nakamura, S. Takase, H. Setoi, I. Uchida, H. Terano, M. Hashimoto, T. Tada, and S. Koda, Chem. Pharm. Bull. 39, 2807 (1991). 34. B.C. Baguley, G. R¨ommele, J. Gruner, and W. Wehrli, Eur. J. Biochem. 97, 345 (1979). 35. a) J. Swenden, C. Borgmann, G. Legler, and E. Bause, Arch. Biochem. Biophys. 248, 335 (1986). b) C. McDonnell, L. Cronin, J.L. O’Brien, P.V. Murphy, J. Org. Chem. 69, 3565 (2004). 36. A. Dondoni, P. Merino, and D. Perrone, Tetrahedron 49, 2939 (1993). 37. T. Ziegler, A. Straub, and F. Effenberger, Angew. Chem. Int. Ed. Engl. 27, 716 (1988). 38. C. Aug´e, and C. Gautheron, Adv. Carbohydr. Chem. 49, 175 (1991). 39. Y.-F. Wang, D.P. Dumas, and C.-H. Wong, Tetrahedron Lett. 34, 403 (1993). 40. R. Rai, I. McAlexander, and Ch.-W.T. Chang, Org. Prep. Proced. Int. (OPPI), 37, 339 (2005).
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41. Y. LeBlanc, B.J. Fitzsimmons, J.P. Springer and J. Rokach, J. Am. Chem. Soc., 111, 2995 (1989). 42. J. Dubois, C.S., Tomooka, and E.M. Carreira, J. Am. Chem. Soc., 119, 3179 (1997). 43. J. Liu and Y.D. Gin, J. Am. Chem. Soc., 124, 9789 (2002). 44. N.V. Bovin, S.E. Zurabyan and A.Y. Khorlii, Carbohydr. Res., 98, 25 (1981). 45. Reddy et al J. Org. Chem. 69, 2630 (2004). 46. B. Elchert, J. Li, J. Wang, Y. Hui, R. Rai, R. Ptak, P. Ward, J.Y. Takemoto, M. Bensaci, and C.-W. Chang, J. Org. Chem., 69, 1513 (2004). 47. V. Pavliak and P. Kovbk, Carbohydr. Res. 210, 333 (1991) 48. F. Dasgupta and P.J. Garegg, Synthesis, 262 (1988) 49. W.-C. Chou, L. Chen, J.-M. Fang, C.-H. Wong, J. Am. Chem. Soc. 116, 6169 (1994). 50. R.V. Stick, K.A. Stubbs, Tetrahedron Asymmetry 16, 321 (2005). 51. S. Ogawa, N. Matsunaga, H. Li, and M.M. Palcic, Eur. J. Org. Chem. 631 (1999). 52. a) T.D. Heingtmann, and A.T. Vassela, Angew. Chem. Int. Ed. 38, 750 (1999). b) A. Bianchi, A. Russo, A. Bernanrdi, Tetrahedron Asymmetry 16, 381 (2005). 53. S. Ogawa, M. Ohmura, S. Hisamatsu, Synthesis 312 (2001). 54. R.M. van Well, K.P. Kartha, and R.A. Field, J. Carbohydr. Chem. 24, 463 (2005). 55. M. Shimizu, H. Togo and M. Yokohama Synthesis 779 (1998). 56. E. Juaristi, and G. Cuevas, The Anomeric Effect, CRC, Boca Raton 4 (1995). 57. W. Koenigs, and E. Knorr, Chem. Ber. 34, 957, (1901). 58. a) W. Roth, and W. Pigman, in Methods in Carbohydrate Chemistry; Whistler R.L. and Wolfrom, M.L., Eds.; Academic Press: New York, 1963, Vol. 2, 405 (1963).; b) B.K. Shull, Z. Wu, and M. Koreeda, J. Carbohydr. Chem. 15(8), 955 (1996).; A. F¨urstner, and H. Weidmann, J. Carbohydr. Chem., 7(4), 773 (1988). 59. R.U. Lemieux, and A.R. Morgan, Can. J. Chem. 43, 2199 (1965).; W. Wang, F. Kong, J. Org. Chem. 63, 5744 (1998). 60. M. Blanc-Muessen, J. Defaye, and H. Driguez, Carbohydr. Res. 67, 305 (1978). 61. Ch. McCloskey, and G.H. Coleman, Org. Synth. 3, 434, (1955). 62. J.A. Perrie, J.H. Harding, C. King, D. Sinnott, and A.V. Stachulski, Org. Lett. 5, 4545 (2003). 63. K.C. Nicolaou, J. Li, and G. Zenke, Helv. Chim. Acta 83, 1977 (2000). 64. Z. Gy¨orgyde´ak, L. Szil´agyi, and H. Paulsen, J. Carbohydr. Chem. 12(2), 139 (1993). 65. G.-J. Boons, and A.V. Demchenko, Chem Rev. 100, 4539 (2000). 66. H. Paulsen, and H. Tietz, Carbohydr. Res. 125, 47 (1984). 67. H. Maeda, K. Ito, H. Ishida, M. Kiso., and A. Hasegawa, J. Carbohydr. Res. 14, 387 (1995). 68. S. Sugiyama, and J.M. Diakur, Organic Lett. 2, 2713 (2000). 69. D. Kahne, S. Walker, Y. Cheng, and D. Van Engen, J. Am. Chem. Soc. 111, 6881 (1989). 70. O.J. Plante, and P. Seeberg, J. Org. Chem. 63, 9150 (1998). 71. V. Constantino, C. Imperatore, E. Fattoruso, and A. Magnoni, Tetrahedron Lett. 41, 9177, (2000). 72. A. Dios, A. Geer, C.H. Marzabadi, and W.R. Franck, J. Org. Chem. 63, 6673 (1998). 73. F. Bosse, L.A. Marcaurelle, and P.H. Seeberger, J. Org. Chem. 67, 6659 (2002). 74. R.R. Schmidt, Angew. Chem. Int. Engl. 25, 213 (1986). 75. P.G.M. Guts, and T.W. Greene, Protecting groups in Organic Synthesis; Wiley, New York, (1991). 76. L. Olsson, Z.J. Jia, and B. Fraser-Reid, J. Org. Chem. 63, 3790 (1998).; K.C. Nicolaou, N. Winssinger, J. Pastor, and F. De Roose, J. Am. Chem. Soc. 119, 449 (1997).
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77. D.P. Larson, and C.H. Heathcock, J. Org. Chem. 62, 8406 (1997). 78. L. Liu, and H. Liu, Tetrahedron Lett. 30, 35 (1989). 79. B. Classon, P.J. Garegg, S. Oscarson, and A.K. Tiden, Carbohydr. Res. 216, 187 (1991). 80. K.C. Nicolaou, T. Ohshima, F.L. van Delft, D. Vourloumis, J.Y. Xu, J.S. Pfefferkorn, and S. Kim, J. Am. Chem. Soc. 120, 8674 (1998). 81. I. Kitagawa, K. Ohashi, N.I. Baek, M. Sakagami, M. Yoshikawa, and H. Shibuya, Chem. Pharm., Bull. 45(5), 786 (1997). 82. V. Ellervik, and G. Magnusson, J. Org. Chem. 63, 9314 (1998). 83. D. Crich, and H. Li, J. Org. Chem. 67, 4640 (2002). 84. J.M. Frech´et, Polymer-supported Reactions in Organic Synthesis; Hodge, P., Sherrington, D.C., Eds.; Wiley. (1980) 85. G.G. Cross, and D.M. Whitfield, Synlett 487 (1999). 86. J.L. Koviak, M.D. Chapell, and R.L. Halcomb, J. Org. Chem. 66, 2318 (2001). 87. C.-H. Wong, X.-S. Ye, and Z. Zhang, J. Am. Chem. Soc. 120, 7173 (1998). 88. R. Lakhmiri, P. Lhoste, and D. Sinou, Tetrahedron Lett. 30, 4669 (1989). 89. S.K. Chaudhary, and O. Hern´andez, Tetrahedron Lett. 95 (1979). 90. T.W. Hart, D.A. Metcalfe, and F. Scheinmann, J. Chem. Soc. Chem. Commun. 156 (1979). 91. M. Oikawa, A. Wada, F. Okazaki, and S. Kusumoto, J. Org. Chem. 61, 4469 (1996). 92. I. Matsuo, M. Isomura, R. Walton, and K. Ajisaka, Tetrahedron Lett. 37, 8795 (1996). 93. F. Theil, and H. Schick, Synthesis 533 (1991). 94. A.B. Smith III, and K.J. Hale, Tetrahedron Lett. 30, 1037 (1989). 95. H. Yamada, T. Harada, and T. Takahashi. J. Am. Chem. Soc. 116, 7919 (1994). 96. L. Leau, N. Goren, Carbohydr. Res. C8, 131, (1984). 97. M. Guiso, C. Procaccio, M.R. Fizzano, and F. Piccioni, Tetrahedron Lett. 38, 4291 (1997). 98. J. Cai, B.E. Davison, C.R. Ganellin, and S. Thaisrivongs, Tetrahedron Lett. 36, 6535 (1995). 99. R.W. Binkley, G.S. Goewey, and J.C. Johnston, J. Org. Chem. 49, 992 (1984). 100. A. Arasappan, and P.L. Fuchs, J. Am. Chem. Soc. 117, 177 (1995). 101. L. Jiang, and T.-H. Chan, J. Org. Chem. 63, 6035 (1998). 102. Tsatsuda et al., Bull. Chem. Soc. Jpn. 58, 1699 (1985). 103. S.V. Ley, and S. Mio, Synlett 789 (1996). 104. J.G. Fernandez-Bola˜nos, J.G. Garc´ıa, J. Fernandez-Bola˜nos, M.J. Di´anez, M.D. Estrada, A. L´opez-Castro, and S. P´erez Garrido, Tetrahedron Assymetry 14, 3761 (2003). 105. J.G.S. Lohman, and P.H. Seeberger, J. Org. Chem. 68, 7541 (2003). 106. H. Liang, and T.B. Grindley J. Carbohydr. Chem. 23, 71 (2004). 107. M. Adinolfi, G. Borone, L. Guariniello, and A. Iadonisi, Tetrahedron Lett. 41, 9305 (2000). 108. S. Fors´en, B. Lindberg, and B.-G. Silvander, Acta Chem. Scand. 19, 359, (1965). 109. K. Koch, and R. J. Chambers, Carbohydr. Res 241, 295 (1993). 110. J.L. Wahlstrom, and R.C. Ronald, J. Org. Chem. 63, 6021 (1998). 111. B. Classon, P.J. Garegg, and B. Samuelson Acta Chem Scan. Ser. B, 38, 419 (1984). 112. R. L´opez, E. Montero, F. Sanchez, J. Ca˜nada, and A. Fernandez-Mayoralas, J. Org. Chem. 59, 7029 (1994). 113. R. Miethchen, J. Holz, H. Prade, and A. Liptak, Tetrahedron 3061 (1992).
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2 O-Glycoside Formation
2.1 General Methods When a monosaccharide (or sugar fragment of any size) is condensed with either an aliphatic or aromatic alcohol, or another sugar moiety through an oxygen, a glycoside bond is formed. General examples of O-glycosides are shown in Figure 2.1. The most common coupling reaction methodologies used for preparing the vast majority of O-glycosides known thus far are1 The Michael reaction The Fischer reaction The Koenigs-Knorr reaction The Helferich reaction The Fusion method The Imidate reaction The Sulfur reaction The armed-disarmed approach The Glycal reaction The Miscellaneous leaving groups The solid-phase approach
2.1.1 The Michael Reaction O PO
O
promoter
X
+
ArOH
PO
P = protecting group X = Br, Cl
68
Promoter
Conditions
NaH K2 CO3 , NaOH
THF acetone
OR
2.1. General Methods OH
69
OH O
O
HO HO
HO HO
O OH
O OH
OH OH O HO HO
O
O OH
OH
HO OH
FIGURE 2.1. Examples of O-glycosides.
This pioneering methodology for O-glycosylation consists of the condensation reaction between 2,3,4,6-Tetraacetyl-α-D-glucopyranosyl chloride and potassium phenoxide to generate the acetylated derivate that undergoes basic hydrolysis to give phenyl-β-D-glucopyranoside (Figure 2.2). Since its original methodology, some modifications have been introduced especially for aromatic glycosides. Some of the main features associated with this methodology are Preserves the pyranose or furanose ring Drives the addition of the aromatic aglycon to the anomeric position Uses protecting groups which are easily removed in basic medium Produces exclusively the β-O-glycoside as a result of neighboring group participation OAc
OK
OAc
O OAc OAc
i
+
Cl OAc
OO
NO2
OAc OAc
NO2
OAc OH
ii
OO
NO2
OH OH OH
i) acetone or DMF. ii) MeONa/MeOH.
FIGURE 2.2. Synthesis of paranitrophenyl-β-D-glucopyranosyl tetraacetate.
70
2. O-Glycoside Formation OH
CH3
HO
O
O
NO2
Cl
OH
N
N
OH
Br
N Ac
FIGURE 2.3. O-glycoside chromophores used for enzymatic detection.
This reaction has been employed for the preparation of O-glycosides that are used as substrates for detection and measurement of enzymatic activity of most of the known glycosidases. Using this methodology, several chromophores have been attached to most of the common monosaccharides. After O-glycoside cleavage by the enzyme, the release of the chromophore will indicate the sites and eventually will quantify the enzymatic activity. Some of the chromophores currently used for these purposes are represented in Figure 2.3. The highly fluorescent O-glycoside substrate 7-hydroxy-4-methylcoumarin-βD-glucopyranose is prepared by condensation between acetobromoglucose with 4-methylumbelliferone in the presence of potassium carbonate in acetone. The intermediate is deacetylated under basic conditions to afford umbelliferyl β-Dglucopyranoside (Figure 2.4). Anderson and Leaback2 were able to prepare 5-Bromo indoxyl-β-D- Nacetylglucopyranoside, a hystochemical substrate for enzymatic detection of quitinase by condensing 3,4,6-triacetyl-β-D N-acetylglucopyranoside chloride with 5-bromo-hydroxy-N acetyl indole at 0◦ C under nitrogen atmosphere (Figure 2.5).
2.1.2 The Fischer Reaction O HO
O
promoter
OH
+
ROH
HO
Promoter
Conditions
HCl gas pTsOH
CH2 Cl2, r.t. CH2 Cl2, r.t.
OR
2.1. General Methods
71 O
OAc O
HO
OAc OAc
O O
OAc
O i
+
OO CH3
OAc
Br OAc
CH3
OAc OAc O O OH OO
ii
CH3
OH OH OH
i) K2CO3/acetone. ii) MeONa/MeOH.
FIGURE 2.4. Michael approach for preparation umbellyferyl-O-glycoside.
This straightforward strategy is used specially for the preparation of simple Oglycosides. The advantage of this methodology is that it does not require the use of protecting groups and simply by combining the free sugar with an alcohol under acidic condition we furnish the corresponding O-glycoside. However, contrary to the previous method, this procedure is not stereo selective and therefore it provides a mixture of anomers. Also, it has been found satisfactory only for small aliphatic alcohols (Figure 2.6). The addition of a controlled stream of dry HCl during a period of around 10 min at room temperature generally are the conditions of choice. However, the use Br OAc
HO Br
O OAc OAc
Cl
OH
i,ii
+
N Ac
NHAc
OO OH OH
i) NaOH/MeOH, OoC, N2. ii) MeONa/MeOH.
NHAc
FIGURE 2.5. Synthesis of indole O-glycoside derivative.
NAc
72
2. O-Glycoside Formation OH
FIGURE 2.6. The Fischer glycoside reaction.
OH O
OH
O
OMe
O-
i
HO
OH
HO
OH
OH
OH
i) MeOH-HCl(g).
of Lewis acid, ion exchange resin, and more recently triflic acid have been also reported providing good yields.3 It is worth mentioning that besides the main product, a mixture of isomers has been detected, suggesting that a rather complex mechanism is involved. It is also seen that the amount of these isomers depends importantly on the condition reactions employed (Figure 2.7). The Fischer methodology has been applied successfully for the synthesis of benzyl O-glycosides. L-Fucose was converted into benzyl fucopyranoside4 by treatment with benzyl alcohol under saturation with HCl at 0◦ C, to furnish the α and β anomers (ratio 5:1) in 80% yield (Figure 2.8). OH
OH HO
HO OH O
OMe
O OH
O OH
i
OMe
OH
OH
OH ii
OH
OH OH
OH OH
O
O OMe OH
OH OMe
OH
OH OH
OH i) MeOH/ 0.7% HCl, 20oC. ii) MeOH/ 4% HCl reflux.
FIGURE 2.7. The Fischer O-glycoside isomers.
O CH3 OH OH OH
O
i
OH
OBn
CH3 OH
O CH3 OH OH
OH 5:1
OH
OBn
OH
o
i) BnOH/HCl (g), 10 min. r.t, and O/N at 4 C.
FIGURE 2.8. Fischer conditions for preparation of Benzyl L-fucose.
2.1. General Methods
73
2.1.3 The Koenigs-Knorr Reaction O
O
promoter
PO
X
+
ROH
PO
OR
X = Br, Cl
Promoter
Conditions
Ag2 CO3 Ag2 O AgNO3 AgClO4 AgOTf
PhH, drierite (drying agent), I2 s-collidine (acid scavender) HgO (acid scavender) Ag2 ClO3 (acid scavender), THF or toluene, r.t. CH2 Cl2 , r.t.
This reaction reported in 1901 is still one of the most useful reactions for preparing a wide variety of O-glycosides.5 It is useful for coupling reactions with either alkyl or aromatic alcohols as well as for coupling between sugars. The methodology requires silver salts as catalyst and among them the oxide, carbonate, nitrate, and triflate silver salts are the most commonly employed (Figure 2.9). Also a drying agent such as calcium sulfate (drierite), calcium chloride, or molecular sieves is recommended. Improved yields are obtained with iodide, vigorous stirring, and protection against light during the course of the reaction. The stereochemistry observed is 1,2 trans type in most of the cases reported, as a consequence of neighboring group participation. When the protecting group is acetate at C (2), there is an intramolecular nucleophilic displacement of the leaving group, generating an orthoester.6 This intermediate is responsible for the incorporation of the alcohol on the β-position (Figure 2.10). Only until recently a method for preparing 1,2-cis glycosides has been developed involving the use of (1S)-phenyl-2-(phenylsulfanyl)ethyl moiety at C-2 of a glycosyl donor to give a quasi-stable anomeric sulfonium ion. The sulfonium ion is formed as a transdecalin ring system. Displacement of the sulfonium ion by a hydroxyl leads to the stereoselective formation of α-glycosides.7 This versatile methodology can be applied for preparation of alky, aryl, and oligosaccharide O-glycosides. A steroidal glycoside cholesterol absorption inhibitor was prepared by condensation between acetobromocellobiose and (3β,5α, OAc
OH
O
HO
OAc OAc
+
O i,ii
Br
OH OH
OAc
OH
i) Ag2O or Ag2CO3/PhH, drierite, I2. ii) MeONa/MeOH.
FIGURE 2.9. The Koenigs-Knorr reaction.
O
74
2. O-Glycoside Formation OAc O OAc OAc
OAc
OAc
O
O
OAc Br
OAc O
OAc
O
OAc
O
O OR +
O
OAc
OR
O CH3
O O
OAc
O
OAc
OAc
R
OAc
H CH3
OAc OAc OAc
ROH/H
FIGURE 2.10. Proposed mechanism for the Koenigs-Knorr glycosidic reaction.
25R)-3-hydroxyspirostan-11-one with anhydrous ZnF2 as catalyst in acetonitrile to provide the steroidal glycoside in 93% yield (Figure 2.11).8 The steroidal glycoside Estrone-β-D-glucuronide was prepared by condensation between Methyl tri-O-glucopyranosylbromide uronate with estrone, employing cadmium instead of silver carbonate (Figure 2.12).9 A comprehensive study about methods for the preparation of diverse O-glucuronides has been described.10 The syntheses of various disaccharides have been reported under Koenigs-Knorr conditions. Gentobiose octaacetate was prepared through condensation of acetobromoglucose with 1,2,3,4-Tetra-O-acetyl-O-Trityl-β-D-glucopyranose in nitromethane using silver perchlorate as catalyst (Figure 2.13).11 B¨achli and Percival12 reported the synthesis of laminaribiose by reacting 1,2,5,6Diisopropylidenglucose with acetobromoglucose in the presence of silver carbonate, iodine, and drierite to produce an acetonide intermediate, which, upon treatment with oxalic acid and sodium methoxide, furnished the 1,3-disaccharide (Figure 2.14). The synthesis of various disaccharides containing N-acetylneuraminic acid (Neu5Ac) was achieved by using acetochloro and acetobromo neuraminic acids as glycosyl donors with active glycosyl acceptors under Ag2 CO3 -promoted reactions conditions (Figure 2.15).13,14 These conditions are also suitable for preparing short oligosaccharides such as the one presented in Figure 2.16. The donor sugar acetobromogentobiose is coupled to the acceptor intermediate using silver triflate as glycosidation catalyst.15 Total synthesis of Bleomycin group antibiotic has been achieved by Katano and Hecht.16 Thus, glycoside coupling reaction of protected disaccharide glycosyl donor with histidine derivative using silver triflate as glycoside promoter provided Bleomycin key intermediate in 21% (Figure 2.17).
2.1. General Methods
75
OAc O
O
O
Br
OAc O
O
+
O
OAc OAc
HO AcO
OAc OAc
O
O O
OH
i,ii
O
O
OH O
O
OH OH
HO
OH OH i) ZnF2, CH3CN. ii) NaOMe
FIGURE 2.11. Synthesis of steroidal glycoside. CO2Me O
COOH OO
i,ii
+
OAc OAc
HO
CH3
OH Br
OH
OAc
CH3 O
OH
i) Cd2CO3. ii) MeONa/MeOH
FIGURE 2.12. Synthesis of a steroidal O-glycoside. OAc O
+
OAc
OH O O
CH2OTr O OAc i,ii
OAc
O OH
OH OH
OAc
Br OAc
OH
OAc OAc
OH
OH OH
i) AgClO4, CH3NO2. ii) MeONa/MeOH
FIGURE 2.13. Synthesis of gentobiose.
O
76
2. O-Glycoside Formation
O
O
OAc
O OAc
O AcO AcO
O
O OH
+
OAc
i
Br
AcO AcO
O
O
O OAc
O
HO HO
O
O
OH
OH ii
O O
HO
O O OH
OH
OH
i) Ag2CO3, drierite, I2. ii) a)MeONa/MeOH. b) oxalic acid 0.001 N, 100oC.
FIGURE 2.14. Synthesis of laminaribiose. O R
OAc AcO
O CO2Me
O
+
O
AcO
O
O O
OH O
O
Ag2CO3 O
OAc OAc
O
O
OAc
67%
AcO
CO2Me
O AcO OAc OAc
R = Cl, Br
Cl
OAc AcO
O
OH CO2Me
OBn
OBn Ag2CO3 AcO
O
+
AcO
BnO
OAc OAc
CO2Me
OAc
20%
O OBn
O AcO
O
OAc OAc
OBn
BnO
OBn
FIGURE 2.15. Silver carbonate promoted synthesis of Neu5Ac(2→6) disaccharides.
2.1.4 The Helferich Reaction O PO
O
promoter
X
+
ROH
PO
X = Br, Cl
Promoter
Conditions
Hg(CN)2 HgBr2 HgI2
CH3 CN CH3 CN CH3 CN
OR
OBn
2.1. General Methods
77
OBn H3C AcO AcO
O
HO BnO
OAc
OBn
+ OAc
O AcO
O BnO O
O OAc
O OBn Br O O
i,ii,iii
Ph H3C HO HO
O OH
OH O
O HO
OH
OH O
O HO OH
HO O O OH OH OH
i) AgOTf, TMU, CH2Cl2. ii) MeONa/MeOH/C6H12. iii)H2, Pd/C, EtOH-H2O.
FIGURE 2.16. Synthesis of tetrasaccharide.
This methodology is considered a modification of the previous one, and the main change being the use of mercury and zinc salts instead of silver. Also, more polar solvents are used such as acetonitrile or nitromethane (Figure 2.18). The yields reported for this reaction are up to 70%, or higher. However, a mixture of anomers is often observed. By following this strategy, Umezawa et al.17 had prepared kanamacin A by condensing 6-O-[2-O-benzyl-3-(benzyloxycarbonylamino)-3-deoxi4,6-O-isopropylidene-α-D-glucopyranosyl]-N,N’-di(benzoyloxycarbonyl)2-deoxyestreptamine, as glycosyl acceptor with 2,3,4-tri-O-benzyl-6-(Nbenzylacetamido)-6-deoxi-α-D-glycopyranosyl chloride, as glycosyl donor. The catalyst employed was mercury (II) cyanide (Figure 2.19). The antitumoral O-glycoside Epirubicine was prepared under Helferich conditions18 using the acetonide form of Adriamicinone and 2,3,6-trideoxi-3trifluoroacetamido-4-O-trifluoroacetyl-α-L-arabinohexopyranosyl chloride, and a mixture of mercury (II) oxide and bromide as shown in Figure 2.20. Other coupling reactions between sugars under Helferich conditions have been as well described.19 For example, the case of trisaccharide Rafinose prepared by
78
2. O-Glycoside Formation O OBn O
AcO
ButOCOHN
Cl O
OBn
OAc O
+
OAc
OBn
HO
O
OAc O
NHAc
N N
i
COOtBu O
ButOCOHN OBn N O OBn O
AcO
N O
OBn
COOtBu OAc O OAc O OAc O NHAc
i) AgOTf, tetramethylurea.
FIGURE 2.17. Glycosilation reaction for preparation of Bleomycin precursor. OAc
OH O OR
O OAc OAc
+
R-OH
i,ii
Br
OH OH
OAc
OH
i) HgCN2, CH3CN. ii) MeONa/MeOH.
FIGURE 2.18. The Helferich general reaction.
condensation between Tetra-O-benzyl-α-D-galactopyranosyl chloride as donor and 2,3,4,1 ,3 ,4 ,6 -hepta-O-acetyl sucrose as acceptor (Figure 2.21). Helferich conditions have been used for preparing disaccharides containing Neu5Ac(2→6)Gal and Glc in good yields, although with low stereocontrol (α:β 3:4) (Figure 2.22).
2.1.5 The Fusion Reaction O PO
O
promoter
X
+
ROH
PO
X = OAc
Promoter
Conditions
ZnCl2 TsOH
120◦ C 120◦ C
OR
2.1. General Methods O
RHN O
OAc
OR
O ZHN
O
O
+
OH
OR
OR
NHR RO Cl ZHN
NHZ i-v
H2N
HO O HO H2N
OH
OH O
OH
O
O OH
NH2 HO H2N
NH2
Z = PhCH2COOR = PhCH2i) Hg(II)CN2, CaSO4/dioxane, PhH. ii) MeONa/MeOH. iii) AcOH. iv) H2, Pd-C.
FIGURE 2.19. Synthesis of a kanamacin A derivative.
O
O
OH MeO
CH3 O
O OH
+
RO RHN R = COF3
Cl OMe
O
O
OH
OH
OH O
MeO O i,ii
OH
OMe
O
OH
O
O
i) HgO-HgBr2. ii) NaOH
FIGURE 2.20. Synthesis of Epirubicine.
CH3 OH NH2
79
80
2. O-Glycoside Formation
BnO
OBn
OH
O
O
OBn
OH OAc O AcO
OAc
+
OO
HO OH
i,ii
OH
O Cl
OAc
OAc
OBn
OAc
OH O HO
O O OH
OAc
OH
OH OH
OH
i) Hg(II)CN2, CaSO4, PhH. ii) MeONa/MeOH. iii) H2, Pd-C.
FIGURE 2.21. Synthesis of Rafinose derivative.
Cl
OAc AcO
O
OH CO2Me
OBn
O
OBn
+
AcO
BnO
OAc OAc
CO2Me
OAc i
AcO
O OBn
O AcO
84%
O
OAc OAc
OBn
BnO
OBn
i) Hg(CN)2/HgBr2 (3:1)
FIGURE 2.22. Helferich conditions for the preparation of sialic disaccharide.
This is a process that is mainly used for preparing aromatic glycosides, and generally consists of the reaction between the sugar, having a leaving group either as acetate or bromide with a phenolic aglycon, under Lewis acid conditions, at temperatures above 100◦ C. This methodology has been useful to synthesize 1-naphthyl 2,3,4,6tetra-O-acetyl-α,β-L-idopyranoside by mixing 1,2,3,4,6-penta-O-acety1-α-Lidopyranose, 1-naphthol, zinc chloride and heating up to 120◦ C during 1h. Also aromatic S-glycosides could be effectively prepared under the fusion method. Thiophenol 2,3,4,6-tetraacetyl glucopyranose was prepared as a mixture of anomers (40:60, α:β) when thiophenol was combined with ZnO or ZnCO3 and then refluxed with acetobromoglucose in CH2 Cl2 (Figure 2.23)20 .
2.1.6 The Imidate Reaction O PO
O
promoter
X X = OC(NH)CCl3
+
ROH
PO
OR
OBn
2.1. General Methods OAc O
AcO OAc
OAc HO i
OAc O
AcO
+
OAc
OAc
81
O OAc
i) ZnCl2, 120oC, 1h.
SH
OAc
OAc
O AcO AcO
+
OAc
Br
O
i
AcO AcO
S
OAc
i) ZnO, CH2Cl2 reflux
FIGURE 2.23. Naphtyl O-glycosides and Phenyl S-glycosides. Promoter
Conditions
AgOTf TMSOTf BF3 -OEt2 NaH
CH2 Cl2 , 0◦ C→r.t. CH2 Cl2 or MeCN 0◦ C CH2 Cl2 or MeCN, −20◦ C CH2 Cl2
This is a more recent procedure attributed to Schmidt and coworkers21a−c who introduced trichloroacetimidate as a good leaving group for preparation of Oglycosides. A significant number of simple and complex O-glycosides involving the imidate coupling reaction have been described. This strategy involves the use of trichloroacetonitrile that in the presence of a base is incorporated on the anomeric hydroxyl group to generate trichloroacetimidate (Figure 2.24). It should be noted that the resulting imidate derivative is air- sensitive and should be used in coupling reactions immediately following preparation. Imidate formation might be spectroscopically detected by 1 H NMR through a signal appearing down field at 6.2 ppm.22 Once the imidate is formed, it can be subjected to nucleophilic attack to provide the corresponding S-, N-, C-, or O-glycoside, depending on the chosen nucleophile. The use of a catalyst such as BF3 .OEt2 , TMSOTf, or AgOTf is necessary to carry out the reaction to completion (Figure 2.25). Although the unquestionable applicability of this approach, an undesirable side reaction has been encountered with glycosyl trichloroacetimidates in the presence of Lewis acid catalysis via the Chapman rearrangement.21b−c Hasegawa et al.23 have prepared the ganglioside shown in Figure 2.26 using 2,3,4,6-tetrabenzylglucopyranosyl-α-acetimidate with the liphophilic alcohol, to generate a ganglioside. The total synthesis of calicheamicin α and dynemicin A has been described by Danishefsky’s group,24 and involves glycosilation of calicheamicinone congener
82
2. O-Glycoside Formation OAc O AcO AcO
OAc O
i
AcO AcO
OAc OAc
OH OAc
OAc O ii
AcO AcO
CCl3
OAc O NH
i) Bn-NH2, HCl, THF. or NH2NH2 ii) Cl3CN, CsCO3/CH2Cl2, r.t.
FIGURE 2.24. Preparation of glycosyl imidate and 1 H NMR of imidate ramnosyl derivative.
with the complex glycosyl imidate using BF3 .OEt2 as Lewis acid catalyst (Figure 2.27). Naturally occurring herbicides known as tricolorin A, F, and G were isolated from the plant Ipomea tricolor and since then synthesized involving glycoside coupling reactions. The first total synthesis of tricolorin A was performed by Larson and Heathcock,25 involving three coupling reactions steps with imidate intermediates used as glycosyl donors (Figure 2.28). The lactonization key step for the preparation of the synthesized tricolorins has been achieved either under macrolactonization conditions reported by Yamaguchi26,27 and also under ring clousure methathesis conditions.22
2.1. General Methods OAc O AcO
OAc O
Nu
AcO
AcO AcO
CCl3
OAc O
83
NH Nu
+
Cl3C
OAc
OH
NH
Lewis acid
OAc O AcO
AcO
OAc HN
CCl3 O
Chapman Rearrangement
FIGURE 2.25. Nucleophilic displacement of imidate leaving group. OBn O BnO BnO
N3 CCl3
OBn O
+
i
HO
C13H27 OBz
NH
OBn O BnO BnO
OBn
N3 O
C13H27 OBz
i) NaH, CH2Cl2.
FIGURE 2.26. Coupling reaction for the preparation of ganglioside.
Another hetero-trisaccharide resin glycoside of jalapinolic acid known as tricolorin F has been synthesized involving coupling reactions with imidates as glycosyl donors. In this way disaccharide and trisaccharide were prepared sequentially. The resulting tricoloric acid C derivative was deprotected and subjected to lactonization under Yamaguchi conditions to produce protected macrolactone. Final removal of acetonide and benzyl protecting groups provided Tricolorin F (Figure 2.29).27 A convergent approach for obtaining a tumoral antigen fragment of Lewis X has been developed by Boons et al.28 Condensation of the imidate glycosyl donor and the trisaccharide glycosyl acceptor provided the hexasaccharide, which was
84
2. O-Glycoside Formation
O
O
CCl3 N3
HN
HO O
O
OH
O
O
O
OTBS O
O Me N OH OMe NPhth
Me S
O
TEOC Me
OMe
I
i
OMe O O
Me TBSO MeO O
O
OTBS
N3
HO O
O O
O
O
OTBS
O Me N
O
OH OMe NPhth
Me S
O
TEOC Me
OMe
I
OMe O O
i) BF3.OEt2, CH2Cl2, –78oC (28%).
Me TBSO MeO
OTBS
FIGURE 2.27. Glycosylation of calicheamicinone congener.
further allowed to react with trichloroacetimidate to generate a hexasaccharide glycosyl donor. The final coupling reaction with the disaccharide using BF3 .OEt2 , furnished the tumoral fragment Lewis X (Figure 2.30). Selectins (E,P and L) are mammalian C-type lectins involved in the recognition process between blood cells or cancer cells and vascular endothelium. L-selectins play a key role in the initial cell-adhesive phenomena during the inflammatory process, whereas E-selectins bind strongly to sialyl Lewis a and x.29,30 It has been found that the tetrasaccharide sialyl Lewis x is the recognition molecule and the preparation of sialyl Lewis x confirmed the hypothesis that sulfation increase the affinity for L-selectins.31 The chemical synthesis of 3e- and 6e-monosulfated and 3e,6e- disulfated Lewis x pentasacharides has been prepared according to Figure 2.31.
CO2Me
O
Me O
CO2Me
NH +
C5H11
O OPiv O
Ph
C5H11
i,ii
Cl3
O
OH
Me O
O OH
O
O O AcO
O
CO2Me OAc O
iii,iv
CCl3
C5H11 O
NH
Me O
v
O
O O
O O AcO
Ph
O
OH NH
C5H11 O
Me O
O O O
O
Ph
O O O
O
CCl3
Me AcO
O Me BnO
OH
O
OAc
O BnO
O
OBn vi
C5H11 O
Me O O
O
Ph
O Me AcO Me BnO
O
O O O
O
O O
O
OAc
O BnO
OBn
i ) AgOTf, CH2Cl2. ii) MeONa/MeOH. iii) AgOTf, CH2Cl2. iv) a)MeONa/MeOH. b) 1 eq. Ac2O, DMAP, CH2Cl2, Et3N. v) a) LiOH, THF, H2O. b) 2,4,6-trichlorobenzoyl chloride, Et3N, MAP, benzene. vi) AgOTf, CH2Cl2.
FIGURE 2.28. Synthesis of tricolorin A precursor.
CO2Me C5H11
CO2Me
RO
O
C5H11 O
CH3
O
O
O
i
RO RO
O
O
O
RO
OH
O
O
OR' OC(NH)CCl3
+
CH3
R = Bn; R' = Ac
O
RO RO
OR'
R = Bn; R' = Ac
ii
R = Bn; R' = H
CO2R'' C5H11 CH3 BnO BnO
CH3
O
O
O
O O
OAc OC(NH)CCl3 RO RO
i
O
O
RO
O
CH3 O RO RO
OR'
R = Bn; R' = Ac; R'' = Me iii R = Bn; R', R'' = H
C5H11
C5H11
O
CH3
O
O iv
O
BnO
OH CH3
O
HO HO
v
O
CH3 BnO BnO
O
CH3
O
O
O O
HO HO
BnO BnO
O
O O
HO HO O
O O -20 oC,
O
1 h; (ii) NaOMe, MeOH , 6h, rt. iii) KOH, MeOH- H2O, 4 h, reflux. iv) 2,4,6trichlorobenzoyl chloride, Et 3N, DMAP, PhH. v) 10% HCl-MeOH, Pd(OH)2 -C 10%, MeOH.
i) BF 3.Et2 O, CH2 Cl2,
FIGURE 2.29. Synthesis of Tricolorin F.
2.1. General Methods OBn
OBn O
OO
O OBn O Me
HO
+
OBn N3
O
CCl3
O
OBn OBn
OBn
OBn
O
87
OO O O OBn O OBn N3 OH Me
OTBDMS
OBn OBn
NH i
OBn
OBn O
O OBn O Me
OO
O
OO O O OBn O OBn N3 OH Me
O
OBn N3
O
OBn
OBn
OBn OBn
OBn OBn
ii
OTBDMS
R = OTBDMS R=H
iii R = Cl3CC(NH)
OBn
OBn HO
O
O BnO
O
O
iv
OBn
N3
O
OBn O BnO OBn
OBn O
O OBn O Me
OO
O
O
OBn N3
O
OBn
OBn OO
O OBn O OH Me
O OBn N3
O O
O
O BnO
O
OBn OBn
OBn OBn
v
Gal-β-(1,4)-GlcNac-β-(1,3)-Gal-β-(1,4)-GlcNac-β-(1,3)-Gal-β-(1,4)-GlcNAc Fuc-α-(1,3)
Fuc-α-(1,3)
i) BF3.OEt2, CH2Cl2. ii) TBAF, AcOH. iii) Cl3CCN, DBU. iv) BF3.OEt2, CH2Cl2. v) a) AcOH. b) H2, Pd-C.
FIGURE 2.30. Covergent synthesis of Lewis X fragment.
N3
OBn
88
2. O-Glycoside Formation OAc
OBn
AcO
O
O OAc OAc
OH
O
+
O AcHN
O
OBn O
HO
OC(=NH)CCl3
OBn
OBn O
O BnO
OBn OBn
OBn
OBn OBn
i
OH OAc AcO
OBn O
O OAc OAc
O O
OBn O
O OBn
OBn OBn OBn
AcHN O
O
O BnO
OBn
OBn OBn i) BF3-Et2 O, CH2 Cl2.
FIGURE 2.31. Coupling reaction for the preparation of Lewis x pentasaccharide intermediate.
Likewise, thioaryl donors can also be suitably converted to acetimidates for performing glycoside coupling reactions. This is the case of arabinosyl thio derivative, which is deprotected under NBS-pyridine conditions affording the lactol in 80% yield as a mixture of anomers (2:1). Treatment with NaH, followed by addition of Cl3 CCN, provided the desired trichloroacetimidate intermediate. This strategy has been succesfully applied in the syntheses of cytotoxic marine natural products Eleutherobin (Figure 2.32).32
2.1.7 The Sulfur Reaction O PO
O
promoter
SR
+
R'OH
PO
R = Me, Et
Promoter
Conditions
NIS-TfOH HgCl2 CuBr2 -Bu4 NBr-AgOTf MeOTf MeSOTf AgOTf-Br2 DMTST NBS-TfOH
0◦ C→r.t. CH2 Cl2 or MeCN 0◦ C CH2 Cl2 or MeCN, −20◦ C Et2 O, r.t. Et2 O, r.t. CH2 Cl2 MeCN, −15◦ C EtCN, −78◦ C
OR'
2.1. General Methods O PO
O
promoter
SR
+
89
R'OH
PO
OR'
R = Ph
Promoter
Conditions
NBS BSP DMTST MeOTf MeSOTf
CH2 Cl2, r.t. CH2 Cl2, MS, r.t
Thioglycosides are useful glycosyl donors widely used in the preparation of O-glycosides. An example of their applicability for the preparation of saccharide synthesis is represented in Figure 2.33. Thus, the synthesis of trisaccharide intermediate was obtained by combining the thioglycoside donor with a monosaccharide acceptor in the presence of methyltriflate, to provide the target trisaccharide in 72% yield.33 A convergent synthesis of the trisaccharide unit belonging to an antigen polysaccharide from streptococcus has been performed by Ley and Priepke.34 In this approach ramnosylalkylsulfur was used as the glycosyl donor, and cyclohexane1,2-diacetal as the protecting group (Figure 2.34). Thioalkyl donor are also useful derivatives for the preparation of biologically important natural sugars known as Sialic acids.23 An efficient procedure for introducing thioalkyl groups as leaving groups involves the conversion of acetate into thiomethyl by treatment with methylthiotrimethylsilane in the presence of TMStriflate. O-glycosilation reaction proceeds between the thioglycosylsialic donor with a glycosyl acceptor (bearing an -OH group available), using a catalyst such as N-iodosuccinimide-TfOH as promotor (Figure 2.35). 2-Thiophenyl glycosides were used as glycosyl donor for preparing complex oligosaccharides containing sialyl moieties. A remarkable convergent approach was described for preparing a sialyl octasaccharide consisting in the O Me Me
N N
O OMe O OAc Me
FIGURE 2.32. Citotoxic marine glycoside Eleutherobin.
Me O
OH OH
Me
90
2. O-Glycoside Formation O
Ph
H3C
O
O
SEt
O
NPhth
O OBz OBz
BzO BzO
+
OBz
OBz OH O OBz
i
Phth = phtalimido
OBz BzO O
Ph
O O
H3 C
O
O
O OBz
OBz
O
OBz
NH2
OBz OBz i) CF3SO3CH3, Et2O, MS, rt. ii) a) NH2-NH2 .H2O, EtOH reflux. b) Ac2O, Py
FIGURE 2.33. Thioglicoside coupling reaction for preparation of a trisaccharide intermediate.
initial glycosidic reaction between 2-thiophenyl Neu5Ac donor with trisaccharide intermediate to produce the expected tetrasaccharide in 45% having an α(2→6)linkage. The resulting tetrasaccharide was coupled with dimeric sialyl donor to yield hexasaccharide in 42%. Acetal hydrolysis was followed by coupling reaction SEt
O HO HO
OH
ii
i
SEt SEt O MeO
O
O O
BnO BnO
OH
OBn OMe
FIGURE 2.34. Synthesis of an antigen polysaccharide fragment.
2.1. General Methods
91
iii SEt
O MeO O O
O O OMe BnO BnO
OBn
OMe
O MeO O
iv
O
OH
OMe OMe
OMe
O
O
MeO O
HO O
OMe
O
HO
O
v
O
O
MeO O O
O
HO O
HO O O
OMe BnO BnO
OBn
HO HO
i) BnBr, NaH, DMF. ii) 1,1,2,2-tetramethoxycyclohexane. iii) IDCP, 4 Å MS. iv) NIS. v) AcOH-H2O. vi) H2, Pd/C, EtOH.
FIGURE 2.34. (Continued)
OH
CO2Me
OAc
OH
AcO
OBz O
SMe
O
+
Ac2N
OTE
HO OAc
OAc
OH i
CO2Me
OAc
OH OTE
AcO
O
O
O
OBz
Ac2N OAc
OAc
OH
i) NIS/TfOH, MeCN, –40oC.
FIGURE 2.35. Thioalkyl donor for the preparation of sialic acids. OBn OBn CO2Me
OAc AcO
HO NHAc
+
SPh
O
AcHN
O O
O
OAc OAc
O
O BnO
OTE OBn
OBn
O OH
O i
OBn OBn HO NHAc
O O
O
AcO AcHN
OTE OBn
OBn
O
O O CO2Me
OAc
OAc AcO i
O
O
AcO
AcO
O BnO
O O
AcHN OAc
OAc
CO2Me
O O
O AcHN OAc
SPh
OAc
FIGURE 2.36. Convergent synthesis of sialyl oligosaccharide.
2.1. General Methods
AcO AcHN OAc
O
O AcHN
O
R 1,R 2 = H
NHAc O
O O CO2Me
OBz
CO2Me
OAc
SMe
AcO
O
O
O
AcHN OAc
OAc AcO
O AcHN
AcO
O
O
OBn OBn
OAc
OAc
O
OBz NHAc
O
AcHN
O
AcHN AcO OAc
O
O
O BnO
O OTE OBn
OBn
O
OBz OBz AcO AcO
OAc
OBz
CO2Me
O AcHN
OAc CO2Me
O OAc
OBz
OAc
O
OAc OAc
OTE OBn
OR
AcO
OAc
O
O
OBn
O RO
AcO
ii
O BnO
O
OAc
OAc
AcO AcHN
OBn O
OAc
R1,R2 = acetonide
OBn
CO2Me
O
O
OAc
93
OH O O CO2Me
i) NIS/TfOH, 45%. ii) DMTST, 85%.
FIGURE 2.36. (continued)
with Neu5Acα(2→3)GalSMe donor to give the octasaccharide in 85% yield (Figure 2.36).35 Crich and Li36 introduced the use of 1-(Benezenesulfinyl)piperidine/triflic anhydride as promoter conditions for preparing O-glycosides from thioglycoside donors. These conditions were applied for preparing Salmonella-type E1 core trisaccharide (Figure 2.37).
94
2. O-Glycoside Formation Ph O
OBn O
O
Ph
O BnO
O +
O
O
O SPh O
HO O O
Ph-pNO2
OPiv O
O
S N
BSP =
i
Ph O O O O Ph
OBn O
O O BnO
O
Ph-pNO2
OPiv
O
O
O
O
O o
i) a) BSP, m.s., CH2Cl2, r.t. b) Tf2O, –60 C to 0oC 1h.
FIGURE 2.37. Preparation of Salmonella-type E1 core trisaccharide under BSP-Tf2 O conditions.
Highly fluorinated thiols have been developed and used as donors in the preparation of disaccharides. The reactivity of these novel fluorinated thiols were examined using different acceptors. Thus, disaccharide formation under glycosidic conditions provided the disaccharides in high yields (Figure 2.38).37 OBz OBz BzO BzO
OH
O
+
S OBz
O
BzO BzO
OBz
N H3C
O
i
OCH3
BzO BzO
O O OBz BzO BzO
C8H17
i) NIS (2 eq.), AgOTf (0.2 eq.), CH2Cl2.
FIGURE 2.38. Highly fluorinated thiols glycosyl donor for glycosidation.
O OBz
OCH3
2.1. General Methods O
O Opent
HO OR
Opent
Opent
+
RO
O
RO OR
R = Bn
O
O
promoter
95
OR
OR
glycosyl acceptor
glycosyl donor "armed"
"disarmed"
O HO
O
O
O
OR' OR' promoter
O
RO
O OR'
OR
OR
OR'
R' = Acetonide
FIGURE 2.39. General scheme for the armed-disarmed approach.
2.1.8 The Armed-Disarmed Method This versatile approach has been attributed to Mootoo and Fraiser-Reid,38 and considers the use of a glycosyl donor in the classical sense coined with the term “armed saccharide” (because the reducing end is armed for further coupling reaction), and an acceptor, in this case “disarmed saccharide,” which contains both a free alcohol and a leaving group sufficiently resistant for the ongoing coupling reaction. The resulting disaccharide now becomes an armed disaccharide, which in turn is reacted with another glycosyl acceptor or disarmed sugar to produce the oligosaccharide chain elongation (Figure 2.39). This method was first implemented in the preparation of 1-6 linked trisaccharide shown in Figure 2.40. As one can see, the disarmed sugar intermediates function as glycosyl acceptor bearing the hydroxyl group at position 6 available for establishing a glycosidic linkage with the armed unit. Despite the usefulness of pentenyl as protecting group, clear preference in the use of thioglycoside donors as armed and disarmed donors is often observed (Figure 2.41).39 This concept was applied successfully in the stereocontrolled synthesis of Lex oligosaccharide derivatives by using two glycosylation steps as described by Yoshida et al.40 The first coupling between “armed” thiophenyl fucopyranosyl derivative with “disarmed” thiophenyl lactose derivative under NIS-TfOH conditions provided trisacccharide, which was subjected without purification to second condensation with different acceptors, one of which is indicated in Figure 2.42. The construction of α-linked mannoside disaccharide was achieved under the armed-disarmed approach by using armed thiogalactoside donor activated
96
2. O-Glycoside Formation OBn OBn O
BnO BnO
O
OH i
O
OPent + AcO OBn AcO
OPent
BnO BnO
OBn O O
OAc RO RO
Pent =
OPent
OR
R = Ac R = CH2Ph
ii,iii
OBn O
BnO BnO
BnO BnO
O
OBn O
O
OH
OBn O
O
O
O
O
BnO BnO
OBn O O RO RO
OPent
O
OBn
O
i
OR
O
O O
i) I(collidine)2ClO4, 2 eq. of CH2Cl2. ii) NaOMe, MeOH. iii) BnBr, NaH, DMF, (n-Bu)4NI.
FIGURE 2.40. The armed-disarmed approach.
by BSP/Tf2 O and condensed with disarmed thiomannoazide intermediate bearing a free hydroxyl group. Addition of triethyl phosphate prior to the aqueous work up led to the generation of the expected α-linked disaccharide in 74% (Figure 2.43).39 PO O HO
SPh
PO O
"disarmed"
O PO
PO
SPh
O O
SPh
promoter "armed"
"armed"
PO O HO
PO
SPh "disarmed"
promoter
O PO
PO O
O
O O
SPh
P = protecting group
FIGURE 2.41. The general scheme of the armed-disarmed approach with thioglycosyl sugars.
O
2.1. General Methods Me OBz O O
O
OBn OBn
SPh
O HO
O
SPh OBn
O
OBz
O
OBz
OBz
O O
O
i
OBz
OBz
O
97
O OBz
OBz Me
O
OBn
OBn OBn
OBn OBn O
OEt OBz
HO OBn
O O
O
O O
O ii
OBn OBn
OBz
O
OBn
OBz
OBz Me
O
OEt
O
OBn
OBn OBn i,ii) CHCl3, 4 Å, NIS-TfOH, –20oC, 1h.
FIGURE 2.42. Preparation of Lewis X tetrasaccharide using armed-disarmed coupling method.
Recently S-benzoxazol thio glycoside (SBox) was synthesized and introduced as alternative glycosyl donor for preparing disaccharides under the armed-disarmed approach. Thus, the SBox glycosyl donor was used as armed donor and condensed with disarmed thioglycoside to provide the target disaccharide (Figure 2.44).41
Ph
BnO
N3 O
O O HO
O
SPh
O BnO
OBn
BnO
OBn
BnO
SPh
SPh
OBn
OBn
BSP
Ph
OTf Ph
S
O
O
O
O N3
SPh
N
FIGURE 2.43. Synthesis of α-linked mannosyl disaccharide following an armed-disarmed strategy.
SPh
98 R2
2. O-Glycoside Formation
N
O
R1 BnO BnO
OAc
R2
OAc +
i
N O
R1 BnO
HS O
S O
OBn
Br
SBox
R1 = OAc; R2 = H R1 = H; R2 = OAc
OH
OBz
O BzO
R2 SEt
R1 BnO
OBz
OAc O OBn O
OBz ii
O BzO
SEt
OBz i) K2CO3, acetone, 90%. AgOTf, CH2Cl2.
FIGURE 2.44. Armed-disarmed synthesis using S-benzoxazol (SBox) as disarmed glycosyl donor.
2.1.9 The Glycal Reaction O
O
DMDO
PO Acetone
O
promoter +
PO
ROH
PO OH
O
Promoter
Conditions
ZnCl2
THF
The glycals are unsaturated sugars with a double bond located between C1 and C2. These useful intermediates were discovered by Fischer and Zach in 191342 and their utility in the preparation of building blocks for oligosaccharide synthesis is increasingly important. Different routes for the preparation of triacetyl glycals have been examined by Fraser-Reid et al.,43 involving the Ferrier rearrangement. Moreover, a suitable one-pot preparation of glycals has been more recently described, starting from reducing sugars by Shull et al.44 The general procedure for preparing these valuable intermediates is based on the reductive removal of a halogen and neighboring acetate group through the use of zinc in acetic acid (Figure 2.45). The completion of this reaction can be followed by 1 H NMR, where the presence of a signal around 6.3 ppm as double of double with J1,2 = 6.2 Hz, J1,3 = 0.3 Hz is expected for H-1, and a multiple shifted upfield for H-2.
OR
2.1. General Methods
99
FIGURE 2.45. The Fischer-Sachs glucal and 1 H NMR of benzylfucopyranosyl glycal.
More recently the use of alternative catalysts such as titanium complex, Li/NH3 , Sodium, Cr (II), and vitamin B-12 as catalysts has been described as improved method, for preparing especially acid sensitive glycals. As for any double bond, these unsaturated sugars may undergo electrophilic addition, which takes place at the C2 position leaving a positive charge at C1, which instantly reacts with the conjugate base. This reaction is particularly useful for the preparation of 2-deoxypyranosides (Figure 2.46). OAc OAc O
O EX AcO
AcO AcO
AcO
FIGURE 2.46. Electrophilic addition.
E
X
100
2. O-Glycoside Formation O
O OR
OR O RO RO
H3C
CH3
O RO
acetone
RO O
FIGURE 2.47. The Brigl epoxide formation.
A more extended application for glycoside bond formation has been developed recently. Such strategies consist of the conversion of glycals into Brigl’s epoxide, and then further treatment with nucleophiles to effect ring opening. The oxidation of the double bond has been successfully achieved with dimethyl dioxirane (DMDO) in acetone (Figure 2.47). The standard procedure for generation of DMDO was developed by Murray and Jeyaraman45 and optimized by Adam et al.46 Such procedure involves the use of potassium monoperoxysulfate as oxidative acetone agent, and the reaction conditions require temperatures below 15◦ C, an efficient stirring. The DMDO/acetone solution generated must be immediately distilled under moderate vacuum. The concentrations of DMDO are in the order of 0.09–0.11 M (5%), and it is used as acetone solution. The transformation of the glycal to the epoxide can be verified by 1 HNMR, where the disappearance of the signal at 6.3 ppm for H-1 double bond is observed, and it is expected the presence of a signal at 5.0, as double for H-1 and at 3.1 as double of double for H-2 (Figure 2.48). The stereo selectivity of epoxide formation is protecting group-dependent, observing in the case of acetate protecting group a mixture of epoxide anomers, and preferentially the α-anomers if the protecting groups are benzyl, or methyl groups (α:β ratio 20:1). As expected, the epoxide ring opening by nucleophiles occurs with inversion of configuration, providing β-glycosides exclusively (Figure 2.49). Likewise, alternative epoxide conditions from glycals have been assayed besides DMDO treatment. Among them, cyclization of a bromohydrin,47 mchloroperoxybenzoic acid-potassium fluoride complex oxidation of the glycal,48 and potassium tertbutoxide oxidation of fluoride glycosyl donor49 has been described (Figure 2.50). The potential of 1,2-anhydro sugars as glycosyl donor for the preparation of β-linked saccharides was established by Halcomb and Danishefsky50 and such strategy consist in the treatment of the glucal having available a hydroxyl group at position 6, with the sugar epoxide under Lewis acid conditions (ZnCl2 ) at low temperature. The resulting glucal disaccharide generated as a single coupling product was further converted to the epoxide, which eventually led to the next coupling reaction with another glucal acceptor (Figure 2.51). The tetrasaccharide Cap domain of the antigenic lipophosphoglycan of Leishmania donovani has been prepared under the glycal approach by Upreti and Vishwakarma.51 Thus, the preparation of the hexa-O-benzyl-lactal under stardard
2.1. General Methods
101
FIGURE 2.48. 1 H NMR spectra of 1,2-anhydro-3,4-di-O-benzyl-α-D-fucopyranose (and traces of acetone).
procedures was followed by oxirane formation with dimethyl dioxirane to generate the corresponding oxirane. Methanolysis ring opening and gluco→manno conversion generated the disaccharide intermediate. This was coupled to the mannobiose donor to produce the tetrasaccharide, which after deprotecction led to the tetrasaccharide Cap domain (Figure 2.52). Brigl’s epoxide has been exploited successfully for the preparation of glycosylated peptides such as collagen type II derived glycosides carrying β-Gal and αGlc-1,2-βGal side chains.52 Galactosyl glycal is reacted with DMDO-acetone solution and the resulting epoxide reacted with hydroxylysine and ZnCl2 as promoter (Figure 2.53). General procedures for preparation of glycosidic bond of glycopeptides can be reviewed in the comprehensive study reported by Kunz.53 OAc
OAc
O
O
HO-R AcO
AcO
AcO O
R
AcO
FIGURE 2.49. Ring opening for β-glycoside formation.
O
OH
102
2. O-Glycoside Formation O
OH
RO
i
RO
Br OR
R = Me, Bn
O
O RO
RO
ii
O RO
RO
OR
OR R = Ac, Bn
O
F
RO
iii
RO
OAc OR
R = Bn i) KH or, KHMDS, 18-crown-6, –70oC. ii) MCPBA-KF, CH2Cl2, r.t. iii) t-BuOK, THF.
FIGURE 2.50. Alternative glycal-epoxidations. OBn O BnO BnO
OH O
+
BnO BnO
O
OBn O
ii
i
BnO BnO
BnO BnO
O
O
OH
BnO BnO
OBn O
iii
O
OBn O
BnO BnO
BnO OBn BnO
O
O
O
BnO OBn BnO
O
OH O
OBn O
BnO BnO i
BnO BnO
O
BnO OBn BnO
O
O
BnO OH BnO
i) ZnCl2/THF, –78oC to r.t. ii) NaH, BnBr. iii) DMDO-acetone.
FIGURE 2.51. Epoxide glycal as glycosil donors.
O
OBn
OBn OBn
O
BnO
OBn
BnO
O
OBn OAc
AcO
O BnO
OBn
OBn
iii
OH
BnO
O BnO
O OBn
O
ii
O BnO
OBn OMe
OH O
OMe
O BnO
OR
RO
AcO AcO
O
RO
O O
AcO
O
O
OBn
O
BnO
OBn
i
O BnO
OBn OBn
OBn
OBn
O
RO
AcO AcO
O O
RO CCl3
O
R = Ac R2 = Bn
RO
NH OR2
iv
OR2
RO R2O
O
RO2
R3 = Me
O OR2
O O
OR3
RO R, R2, R3 v H
o
o
i) DMDO, CH2Cl2, 0 C, 2h. ii) MeOH, rt, 4h. iii) a)(COCl)2, DMSO, CH2Cl2, –78 C. b) NaBH4, rt, 4h. iv) TMSOTf, CH2Cl2, –30oC, 45 min. v)a) Pd(OH)2, H2, 4h. b) NaOMe, MeOH. c) Ac2O/AcOH/H2SO4.
FIGURE 2.52. Synthesis of a tetrasacharide using an epoxide disaccacharide as glycosyl donor. NHFmoc HO O
OTBDPS O
OTBDPS O
O i
O
COOR2 R
O
ii
O O
NHFmoc
OTBDPS O O
COOR2
O OH
R
αGlc-1,2-βGal
H2NH2C
H-Gly-Glu-Hyp-Gly-Ile-Ala-Gly-Phe
Gly-Glu-Gln-Gly-Pro-Lys-OH O
1) DMDO-acetone. ii) ZnCl2, THF
FIGURE 2.53. Amino acids glycosidation.
104
2. O-Glycoside Formation
This methodology has been extended for the preparation of E-selectin ligand tetrasaccharide sialyl Lewisx (SLex ), which is located at the terminus of glycolipids present on the surface of neutrophils. The chemoenzymatic sequence consisted in the reaction of the 6-acetylated glucal with β-galactosidase transferase to produce disaccharide, which was subjected to further transformations according to the pathway presented in Figure 2.54.54
2.1.10 Miscellaneous Leaving Groups 2.1.10.1
Fluoride Glycosyl Donors O
PO
O
promoter
X
+
ROH
PO
OR
X=F
Ppromoter
Conditions
SnCl2 -AgClO4 Cp2 HfCl2 -AgOTf SnCl2 -AgOTf
Et2 O, −15 → r.t. CH2 Cl2 , −25◦ C CH2 Cl2 , 0◦ C
Fluorine is considered a poor leaving group, and its use for glycoside bond formation has been more restricted than chlorine and bromine, although display higher thermal and chemical stability. Nonetheless several Oglycoside synthesis involving glycosyl donors with fluorine as leaving group has been described, specially for the preparation of α-O-glycosides with high stereoselectivity.55 Based in the use of fluorine glycosyl donors, the synthesis of the marine algae α-agelaspines, was carried out through the condensation of perbenzylated galactopyranosyl fluorine as anomeric mixture with the long chain alcohol in the presence of a mixture of SnCl2 -AgClO4 as catalyst (Figure 2.55).56 A general procedure for the preparation of ribofuranosyl fluorides and their use as glycosyl donors for O-glycosylation with α-stereocontrol was developed by Mukaiyama et al.,57 and consists of the conversion of 2,3,5-tri-O-benzyl-Dribofuranoside that react under mild conditions with 2-fluoro-1-methylpyridinium tosylate at room temperature to give an anomeric mixture (α:β 58:42) in 84% yield. These two fluorines could be either separate or interconverted by treating the α-anomer with boron trifluoride etherate in ether at room temperature (Figure 2.56). It has been observed that the glycosylation reaction between the glycosyl fluorine with different alcohols under Lewis acid conditions provides mainly αriboglucosides in high yield as it is shown in Figure 2.57. Sulfated Lex and Lea -type oligosaccharide selectin ligands were synthetically prepared as described below. Thus, glycosyl donor and acceptor were condensed under Mukaiyama conditions (AgClO4 -SnCl2 ) to form the
2.1. General Methods
105
OH OH O O
HO
AcO AcO
OAc O
OAc i
OH OH iii-vii
HO
O HO O
OH
OAc O
HO HO
ii
OH O
HO
viii
O
HO2C
NHAc
OAc O
O HO O
OH
OH OH OH
OH
OH OH
NO2
OH O
O HO O
OH NHAc
OH
O HO HO
OH
AcHN
OH
OH OH OH
O
H3C OH OH ix
O O
O O
HO2C
AcHN
OH NHAc
OH
O HO HO
OH O
sialyl Lea
OH OH
i) subtilisin, DMF. ii) β-galactosidase. iii) Ac2O. iv) NaN3, CAN. v) H2 cat. vi) Ac2O. vii) saponification. viii) α2-3SiaT, CMP-NeuAc. ix) α1-3/4 FucT, GDP-Fuc.
FIGURE 2.54. Chemoenzymatic synthesis of tetrasaccharide sialyl Lea .
β-glycoside in 90% yield. The sulphated tetrasaccharide was formed by reaction of tetrasaccharide acceptor with SO3 .NM3 complex in anhydrous pyridine (Figure 2.58).58 2.1.10.2
Silyl Glycosyl Donors O
PO
promoter
OR
+
R'OH
O PO
R
Promoter
Conditions
Me3 Si t BuMe Si 2
TMSOTf or BF3 .Et2 O TMSOTf
CH2 Cl2, −5◦ C CH2 Cl2 -acetone, −35◦ C
OR'
106
2. O-Glycoside Formation O OBn
OBn O
(CH2)12CH3
HN
i
+ BnO
F
HO
OBn
(CH2)13CH3 OH O
OBn
OBn O
(CH2)12 CH3
HN
BnO OBn O (CH2)13CH3 OH
i) SnCl2, AgClO4/THF. ii) H2, Pd-BaSO4/THF.
FIGURE 2.55. Fluorine monosaccharide as glycosyl donor.
BnO
BnO
O OH
+
F
OTs
+
F
N H
OBn OBn
O
i
OBn OBn α/β 58/42 i) NEt3, CH 2Cl2
BnO
O
BnO i
F OBn OBn
O
F
OBn OBn
i) BF3.OEt2, Et2O, r.t. 10min, 72%
FIGURE 2.56. The Mukaiyama protocol for preparation of ribofuranosyl fluoride.
2.1. General Methods BnO
BnO
O
F
O
107
i + R-OH
OR OBn OBn
OBn OBn
α/β 72/28 i) SnCl2, Ph3CClO 4, Et2O, MS 4A, 93%
FIGURE 2.57. N-glycosylation reaction using ribofuranosyl fluorine.
t
OBn
OAc OBn
O
O
BuMe2SiO AllylO
+
F NPhTh
HO
OR1 OBn
OBn i
R4O AllylO
OBn OBn
O
O O NR2R3
OBn
OBn
R1 = Ac, R2, R3 = Phth, R4 = SitBuMe2
ii
R1 = H, R2, R3 = H2, R4 = SitBuMe2 iii
R1 = Ac, R2, R3 = H, Ac, R4 = SitBuMe2
iv
R1 = Ac, R2, R3 = H, Ac R4 = H
F OAc OAc
O
OAc OAc
O MCAO
O
RO
OAc
OBn OBn
O
O
O
MCAO
OAc
OAc OBn
OBn
O
F
OBn
NHAc
OBn
v
vii
OBn
R = Allyl
vi
R=H
OH
OAc OAc
OAc OBn
OBn
O
O
O
OAc O
NHAc
OBn vii
OBn OBn
O
O
O
RO
OH
O ix
HO3SO
OBn
O
OH O
O
O
OH OBn
OH
O
O
NHAc OH
R = MCA R=H
viii
OH
OH OH
R = SO3H
FIGURE 2.58. Total synthesis of sulphated Lex .
OH
OH
108
2. O-Glycoside Formation AcO OAc O
OSiMe3
AcO
O
i + COOMe
Me
AcO
OAc
AcO
OAc O
O
O
AcO AcO
OAc COOMe
Me
AcO i) TfOSiMe 3, –40oC.
FIGURE 2.59. Silyl derivatives as glycosyl donors.
Silyl groups are best known as versatile protecting groups, and their use as leaving groups for glycoside bond formation has been more limited. An example of glycoside formation involving a silyl group as leaving group is reported for the preparation of luganol O-glycoside.59 In this work, the glycosyl donor is combined with luganine in the presence of trimethylsilyltriflate at low temperature (Figure 2.59). It is worth mentioning that stereoselectivity is dependent on C-2 neighboring group participation. When acetate is the C-2 protecting group, the β-anomer is obtained, while if the protecting group is benzyl, the α-anomer is preferred. The use of selenoglycosides as glycosyl donors and acceptor in glycosilation reactions has also been described by Metha and Pinto.60 A typical glycosidation procedure with phenylselenoglycoside donors involves the glycosyl acceptor, ˚ molecular sieves, silver triflate, and potassium carbonate in dichloromethane 4-A (Figure 2.60). Tetrazol has also been tested as a leaving group for the preparation of an antibiotic fragment.61 A coupling reaction with the methoxyphenyl glycosyl acceptor was catalyzed with (Me3 )3 OBF4 as shown in Figure 2.61. 2-Aminodisaccharides were obtained by an elegant [3,3] sigmatropic rearrangement, by Takeda et al.62 The addition of thiophenol to an unsaturated C-1 in the presence of Lewis acid was followed by a sigmatropic rearrangement with an imidate group that migrates from C-4 to C-2. Disaccharide formation was catalyzed with Pd(CH3 CN)2 -AgOTf complex in dichloromethane (Figure 2.62).
2.1. General Methods SePh Ph
O
O
HO
Bn
O
O
i
O
O
+
AcO AcO
O
Ph
O
109
Bn
OMe O
OAc AcO AcO
i) K2CO3 , AgOTf, MS, CH2Cl2.
OAc
FIGURE 2.60. Phenylselenosugars as glycosyl donors.
The total synthesis of the cyclic glycolipid Arthrobacilin A, a cell growth inhibitor was achieved by Garcia and Nizhikawa,63 under zinc p-tert-butylbenzoate salt as glycoside catalyst, obtaining the β-galactoside glycoside in 73% along with α-isomer in 27% (Figure 2.63). X O
OMP X
O AcO
O
+
O
iii O AcO
OH
X = α-OMP
i
X = OH ii
X = α-OMP
i
X = OH
X = Tet OMP
ii
O
O
iii
O O O AcO
i) CAN. ii) 1H-tetrazole. iii) (CH3)3OBF4, MS.
FIGURE 2.61. The use of tetrazol as a leaving group.
X = Tet
OMe
110
2. O-Glycoside Formation
OAc
OAc
OAc
O
OAc O
i
AcO
OH
OH O
ii
SPh
iii
SPh OBn
CCl3
O HN
OTBS O
HO BnO
OTBS O
iv
O
OBn
NHCOCCl3
OMe
v SPh SPh OTBS
OTBS O O
NHCOCCl3
vi
OBn
O
NHCOCCl3
O
O O
O BnO
OAc
OBn
BnO
OMe
OAc NHCOCCl3
O
OBn O
AcO
OBn
OMe
OAc O
vii
OBn
+
O BnO
OBn
AcO AcO
NHCOCCl3
O O BnO
OMe
OBn
OBn
i) PhSH, SnCl4/CH2Cl2. ii) MeONa/MeOH. iii) a) TBSCl-imidazol/CH2Cl2. b) Cl3CCN-NaH/CH2Cl2. iv) xylene, reflux. v) Pd(CH3CN)2-AgOTf, MS 4A/CH2Cl2. vi) m-CPBA/CH2Cl2. viii) Ac2O-AcOH/ BF3.OEt2.
FIGURE 2.62. Sigmatropic rearrangement.
2.1.10.3
Heterogenous Catalysis
Stereocontrolled α- and β-glycosylations by using environmentally benign heterogenous catalyst has been developed as a novel approach for stereoselective formation of β-O-glycosidic linkages. Polymeric materials such as montmorillonite K-10,64 heteropoly acid (H4 SiW12 O40 ),65 sulphated zirconia (SO4 /ZrO2 ),66 and perfluorinated solid-supported sulfonic acids (Nafion resins)67 have been assayed successfully providing series of stereocontrolled O-glycosides in high yield (Figure 2.64).
OMe
2.1. General Methods OBn
OAc O
i
O +
BnO OBn
OBn
OH
OAc C9H19
O
BnO OBn
Cl
OMe
O
111
OMe C9H19 O
OR OR O RO
O
C9H19 O
O
OR O
O C9H19
O O RO
OR
RO O
O O
RO
C9H19
O
OR i) zinc p-tert-butylbenzoate, 2-methyl-2-butene, MS, CH2Cl2, r.t., 2.5h
FIGURE 2.63. Glycosylation reaction for preparation of Arthrobacilin A. OBn
OBn O
BnO BnO
+
montmorillonite K-10
R-OH
10:1 CH 2Cl2-CH 3CN
OBn OP(OEt)2
heteropoly acid (H4SiW12O40)
O
+
OBn OR
–20oC, 30 min 90%
OBn BnO BnO
O
BnO BnO
R-OH MeCN 90%
OBn OH
β >> α
OBn O
BnO BnO
+
OBn OR α/β 92:8
OBn
OBn BnO BnO
O
OR
SO4/ZrO2
BnO BnO
Et2O
OBn
OBn
O
+
R-OH
SO4/ZrO2 CH3CN
OBn
BnO BnO
OBn
F
BnO BnO BnO
OR
BnO
OBn O Y
+
R-OH
Nafion CH3CN
X
O
BnO BnO
OBn O
OR
X = S(O)Ph, Y= H Y = S(O)Ph, X= H
FIGURE 2.64. Stereocontrolled O-glycosidations using heterogeneous polymeric materials.
112
2. O-Glycoside Formation OBn
OBn
OBz
O
OBz O
+
STol
BnO
STol
HO
OLev
O(NBz)
(BzN)O
O
+
STol O(ClBn)
HO
NHTroc i
OBn
OBz
OBn
OBz (BzN)O
O(NBz) O
O
O
STol O(ClBn)
O
O
BnO
NHTroc
OLev
i) NIS, TfOH.
FIGURE 2.65. One-pot reaction for two β-linkages formation.
2.1.10.4
The Pool Strategy
This term applies to define a one-step reaction used to build up two β-linkages simultaneously from 3 sugar intermediates.68 This approach has been described for the preparation of the glycosyl ceramide Globo H hexasaccharide identified as an antigen on prostate and breast cancer cells. The synthesis consisted in the initial synthesis of the trisaccharide building block from the one-pot reaction of the 3 suitable sugar intermediates under N-iodosuccinimide and triflic acid conditions in 67% yield (Figure 2.65). 2.1.10.5
Phosphate Glycosyl Donors O
PO
O
promoter
OR
+
R'OH
R P(=O)(OPh)2 P(=S)(Me)2 P(=O)(NMe2 )2 P(=NTs)(NMe2 )2
PO
Promoter
Conditions
TMSOTf TrClO4 TMSOTf BF3 -Et2 O
CH2 Cl2, −5◦ C
OR'
CH3 CN, −40◦ C CH2 Cl2
Phosphorous glycosyl donors are another option for preparing oligosaccharides. These donors have been used for the preparation of sialyl oligosaccharides; however, the yield reported were moderate. This is the case of the preparation of sialyl tetrasaccharide derivative, which was carried out by condensation
2.1. General Methods
AcO
+
AcHN
OMe
O
HO
CO 2Me
O
OBn O
OBn
OP(OR)2
OAc
OH
O
OAc OAc OBn
OBn
O
O OBn
113
OBn
OBn
R = Et : 36% R = Bn : 20%
i CO2Me
OAc AcO
O
O
O
AcHN OAc OAc
OBn O
OBn
OH
O
O OBn O OBn
OMe OBn
OBn
OBn
i) TMSOTf, MeCN, –40oC, 1h.
FIGURE 2.66. Phosphorous glycosyl donors for oligosaccharide synthesis.
between sialyl phosphite with trisaccharide acceptor under TMSOTf as catalyst (Figure 2.66).69
2.1.11 Enzymatic Approach Enzymes in organic chemistry has become an essential tool for the synthesis of important target molecules, and in many cases they are considered the first choice, especially for those key steps involving stereospecifically controlled reaction conditions. In general, enzymes are considered efficient catalysts that perform the desired transformation under mild conditions with high selectivity and specificity, usually avoiding epimerization, racemization, and rearrangements processes. Besides there is a current need of developing economical and environmentally friendly processes for synthesis. However, some aspects still need close attention in order to fulfill thoroughly the requirements especially for high-scale production. Thus, many enzymes are unstable, high cost, difficult to handle, and require expensive cofactors. Glycosyltransferases are important enzymes involved in essential processes related to oligosaccharide biosynthesis, and they have been found also very useful as biocatalyst for the chemoenzymatic synthesis of interesting oligosaccharides
114
2. O-Glycoside Formation OH
HO HO
OH O
OH
i
OH
OPO32–
OH
OH
ii
O
HO HO
iii
HO OH
OUDP
OH
R-OH
O
OH O
HO OH
OUDP
i) UTP, UDP-Glc pyrophosphorylase. ii) UDP-Glc 4-epimerase. iii) Gal transferase.
FIGURE 2.67. Glycosylation with galactosyltransferases.
and nucleotides.70,71 They have been classified as Leloir if they are involved in the biosynthesis of most of N- and O-linked glycoproteins in mammalians, and requires mono- and diphosphates as glycosyl donors, and non-Leloir enzymes which utilize sugar phosphates as substrates. Glycosylations with galactosyltransferases can be performed through the use of glucose-1-phosphate as donor. A general sequence consists in the conversion by using UDP-Glc pyrophosphorylase to give UDP-glucose. Epimerization with UDP-glucose epimerase affords UDP-galactose, which is used for glycosylation with galactosyltransferase (Figure 2.67).72 Several chemoenzymatic synthesis of α(2→6) and α(2→3)-oligosaccharides have been reported through the use of sialyltransferases for glycosidic coupling reactions. One described approach involves the in situ regeneration of CMP-Neu5Ac, requiring catalytic amount of CMP-Neu5Ac (Figure 2.68).73
OH OH HO
NHAc
HO
O
O O OH
OH
OH
CMP-Neu5Ac i CMP
OH
HO AcHN HO HO
COOH O
O OH
HO
O OH
HO
NHAc
O O OH
OH
i) α-(2-6)-sialyltransferase
FIGURE 2.68. Synthesis of silayl trisaccharide mediated by silayl glycosiltransferase.
OR
2.1. General Methods OH OH HO
NHAc
HO O
O
O
O OH
OH
OH O HO
O OH
OH
NHR
O
OH
115
C13 H27
O
OH OH
CMPNeu5Ac
CMP
OH
COOH
HO
O
AcHN HO HO
O OH
HO O
O
HO
O OH
OH
OH
NHAc
O
OH
O OH
O OH
O HO
OCer
OH
i) α-(2-6)-sialyltransferase
FIGURE 2.69. Enzymatic synthesis of ganglioside.
Sialyltransferases also proved to be efficient biocatalysts in the preparation of gangliosides, being involved in (2→6) linkage formation between the tetrasaccharide ceramide with CMP-Neu5Ac (Figure 2.69).74 Glucosamine may be enzymatically transformed to glucosamine 6-phosphate by treatment with hexokinase from yeast, and ultimately to glucosamine 1-phosphate by the action of phosphoglucomutase (Figure 2.70).75 UDP-glucuronic acid was prepared from UDP glucose by the action of UDPGlc dehydrogenase along with NAD. This cofactor was regenerated with lactate dehydrogenase in the presence of piruvate (Figure 2.71).76
OH HO HO
OPO32– O
NH2
i
OH
HO HO UDP
UTP
OH
O NH2
iii
HO HO
OH
ii
Pyr
PEP
i) Hexokinase from yeast. ii) pyruvate kinase. iii) phosphoglucomutase.
FIGURE 2.70. Enzymatic preparation of glucosamine 6- and 1-phosphate.
O NH2
OPO32–
116
2. O-Glycoside Formation OH O
HO HO
-O2C
i
OH
OH
2 NAD 2 NADH
OUDP
O
HO HO
OUDP
L-LDH
O
OH 2
2
CO2–
CO2–
i) UDP-Glc dehydrogenase
FIGURE 2.71. Enzymatic preparation of UDP-glucuronide.
CMP-N-acetylneuraminic acid has been prepared from CTP and NeuAc under catalysis by CMP-NeuAc synthetase. In a cascade representation, it is observed that CTP is synthesized from CMP with adenylate kinase and pyruvate kinase (Figure 2.72).77
OH O
HO HO
OH NHAc HO–
HO HO HO
O CO2–
NHAc O OH
OH
OH
HO
i
CO2H
O
AcHN OH HO iii
CMP CDP
CTP
iv
ii PEP CDP
CTP iii
Pyr
Pyr
Pyr = pyruvate
OH
OCMP
HO PEP
O
AcHN
CO2H
OH HO i) UDP-NeuAc aldolase. ii) CMP-NeuAc synthetase. iii) pyruvate kinase. iv) adenylate kinase.
FIGURE 2.72. Synthesis of CMP-N-acetylneuraminic acid.
2.1. General Methods
O OH O HO HO
OH
OHO O F
OH
O
F
OH
H
117
OH O
OPhNO2 HO HO
H O
OH HO
OH
O
OPhNO2
OH
FIGURE 2.73. Glycosynthase-catalyzed oligosaccharide synthesis.
2.1.11.1
Enzymatic Synthesis of Oligosaccharides
Mutated glycosidase also known as glycosynthase AbgGlu358Ala in combination with activated glycosyl donors and suitable acceptors can generate synthetic oligosaccharides. Thus, for this transformation the conditions selected were α-glycosyl fluoride as glycosyl donor and p-nitrophenyl as glycosyl acceptor in the presence of ammonium bicarbonate buffer. The proposed mechanism of glycosynthase-catalyzed reaction is illustrated in Figure 2.73.78 The Regioselective preparation of α-1,3 and α-1,6 disaccharides by using αglycosidase as biocatalyst has been described. Thus, by combining p-nitrophenylα-galactose functioning as glycosyl donor, with the glycosyl acceptor methoxygalactose, the expected 1,3- and 1,6-disaccharides were obtained in the form of αand β- anomers (Figure 2.74).79 A transglycosylation reaction mediated by α-L-fucosidase from Alcaligenes sp. was performed by combination of p-nitrophenylglycosides donors, with different acceptors such as N-acetylglucosamine, lactose, D-GlcNAc, and D-Glc, providing the corresponding p-nitrophenyl glycosides of di- and trisaccharides containing a (1→2)-, (1→3)-, (1→4)-, or (1→6)-linked to the α-L-fucosyl group. In the general procedure illustrated in Figure 2.75 the p-nitrophenyl fucoside donor was combined with p-nitrophenyl lactosamine acceptor, being incubated with α-Lfucosidase at 50◦ C to produce the 2- and 3-linked trisaccharides.80 Sulfotransferases provides a versatile method for the preparation of glycoside sulfates. A recent report describes the use of 3 -phosphoadenosine -5’phosphosulfate (PAPS), and GlcNAc-6-sulfotransferase as catalyst (Figure 2.76).81 A chemoenzymatic synthesis of rhodiooctanoside isolated from Chinese medicines was described. The synthesis was carried out by direct β-glucosidation between 1,8-octanediol and D-glucose using immobilized β-glucosidase from almonds with the synthetic propolymer ENTP-4000 to generate the glycoside in 58% yield (Figure 2.77).82 Lactosamine was prepared using an enzymatic approach consisting in the preparation of UDP glucose and condensation with N-acetyl glucosamine (GlcNAc) in the presence of galactosyl transferase (Figure 2.78).83
2.1.12 The Solid-Phase Methodology Perhaps what remains the most challenging task for sugar chemistry is the synthesis of complex oligosaccharides such as those found in bacterial membranes or
OH
OH
O HO HO R = C6H4-p-NO2
OR
OH
OH
OH
OH
O
O
HO
OMe
HO HO
HO OMe
OH
OH
OH
OH
O
O
OH
OH
HO
HO O
HO
HO OH
OMe
O
O
HO
O OMe
HO HO
FIGURE 2.74. Example of microbial catalyzed coupling reaction. OH
OH OH
OPhNO2-p
O
O O H3 C
OH
+
OPhNO2-p
O HO
HO
NHAc
OH
HO OH a-L-fucosidase
OH
OH OH O HO
HO
O HO OH
OPhNO2-p
O HO
O OH O
OH
H 3C
O
O
+
NHAc
O
OH
OH OH
O
O
H 3C
-HOPhNO2-p
OPhNO2-p NHAc
OH
HO OH
FIGURE 2.75. Transglycosylation reaction for the preparation of 2- and 3-linked trisaccharides.
2.1. General Methods OH
OSO32-
GlcNAc-6-sulfotransferase
O
HO HO
119
O
HO HO
OR
OR NHAc
NHAc NH2 N O
N
N
O
N
O
-O S O P O O
NH2
2–
N
O
O–
O3PO
–
O P O
N
OH
2–
N
O
O–
N
OH
O3PO
3',5'-ADP
PAPS
FIGURE 2.76. Transfer of the sulfuryl group from PAPS to the glycoside.
OH
OH HO HO
i
O
+
O
HO HO
Me(CH2)6CH2OH
OH
O(CH2)7Me NHAc
OH
OH HO HO
O O O
HO HO
O(CH2)7Me NHAc
i) β-glucosidase (250u), 50oC, H2O.
FIGURE 2.77. Chemoenzymatic synthesis of rhodiooctanoside.
OH
OH
OH
OH O
O +
HO
HO NHAc OH
OH OUDP
Gal-transferase
OH
OH O
HO OH
FIGURE 2.78. Enzymatic synthesis of lactosamine.
β-D-Gal(1
NHAc HO O
O OH
4)-D-GlcNAc
OH
120
2. O-Glycoside Formation
wall cells and are usually in the form of glycopeptides. Different types of monosaccharides can be present as constitutive parts such as glucose, galactose, mannose, N-acetylglucosamine, silaic acid, and L-fucose. Also, the order of linkage and stereoselectivity between them is rarely conserved. The different nature, stereoselectivity, and linkage sequence have been a formidable obstacle for the development of general procedures of the type used for peptides and oligonucleotides which can be prepared on machine synthesizers with high efficiency. The main advantage of the solid-phase methodology is the coupling of sugar units to the resin, which allows easy washing away of the nonreacted reagents, avoiding tedious purifications steps. Nonetheless, despite the difficulties, interesting progress has been made for preparing oligosaccharides84a and glycopeptides,84b suggesting that in the solid phase technology for complex sugars will be affordable. The solid-phase approach involves three elements, namely the glycosyl donor, glycosyl acceptor, and the resin, which is properly activated with a group susceptible for attachment either with the glycosyl donor or acceptor depending on the strategy of choice. Although it appears obvious, it is important to remain that the linkage between the resin and the sugar should be easily cleaved under compatible conditions for the glycoside bond. According to a comprehensive review,85 the synthetic strategies are classified by (a) Donor-bound, (b) Acceptor-bound, and (c) Bidirectional Strategies. One general approach involves the initial attachment of a glycosyl donor (halides, trichcloroacetimidate, sulfoxides, phosphates, phosphates, thio and pentenyl and glycols) to the resin (polystyrene-base). The attached sugar is selectively deprotected depending on the required position (1,2- 1,3- 1,4- 1,6), transforming the resin-sugar complex in a sugar acceptor which will be coupled to the next glycosyl donor to produce a second linkage. By repeating this sequence an elongated chain is obtained. The final release and full deprotection will produce the free oligosaccharide (Figure 2.79).86 An example of the donor-bound strategy is the bounding of sulfur glycoside to polistyrene resin to form a sulfur linkage between the donor and the resin (Figure 2.80). Suitable hydroxyl group from the donor will serve as linkage site with de next sugar unit for chain elongation. It should be noted that the glycosyl donor also contains a position available for the linkage with the next sugar. In other words, the glycosyl donor once attached to the resin becomes a glycosyl acceptor, as can be seen for the next coupling sequence (Figure 2.81).85 The synthesis of β-(1→6) gentotetraose was accomplished by using a benzoyl propionate as resin linker. The glycosyl donor chosen was acetobromoglucose functionalized with trichloroacetate group as a temporary protecting group at position 5. Glycosylation reactions were effected under Helferich conditions and cleavage from resin was performed with hydrazinium acetate (Figure 2.82). Polymer solid phase has been also exploited successfully by Crich et al,87 for the synthesis of sensitive β-mannosides, using a variation of sulfhoxide method, consisting in the transformation of sulfoxide to triflic group as leaving group. The
2.1. General Methods O
O
O
O
OR4 i
OR4
ii
OR3
R1O
O
O
OR4
121
OR8
OR2
OR2
OR2
O
O
R1O
OH
R1O
OR7
R5O OR6 O
O
O
O
OR4
i
OR4
ii
O
O
R 1O
O
R 1O
OR8
O
OR8
OR2
OR2
O
R5 O
OH
R5 O
O
OR11
OR6
OR6
OR10
R 9O OR10
O
i
O
OR4 O
R1 O
O
OR8
O oligosaccharide
OR2 O
R5 O
O
OR11
iii
OR6 oligosaccharide
OH
R9 O OR10
i) deprotection. ii) glycosyl donor. iii) cleavage.
FIGURE 2.79. General scheme for solid-phase oligosaccharide synthesis 1,4-linkage case.
subsequent addition of alcohol acceptor to the donor attached to the Wang resin will result in the glycoside β-mannoside formation (Figure 2.83). The enzymatic solid-phase oligosaccharide synthesis relies mainly by the use of glycosyltransferases, glycosidases and glycosynthases. By taking advantage on their high stereo- and regioselectivity, various oligosaccharides and glycopeptides have been prepared usually under mild conditions without the need of using protecting groups. Unfortunately, the enzymatic approach is still in some cases OH O BnO BnO
OBn
SH
+
Cl polystyrene resin
BnO BnO
OH O
S
OBn
FIGURE 2.80. Example of donor-bound strategy for solid-phase glycosilation reactions.
122
2. O-Glycoside Formation OAc O BnO BnO
OH O BnO BnO
OAc O BnO BnO
OBn Br
S
OBn O
OBn
O BnO BnO
OAc O
OH O BnO BnO
BnO BnO
OBn
OBn
OAc O BnO BnO
OBn Br
OBn
O
O O
BnO BnO
S
O
S BnO BnO
OBn
OBn O O
BnO BnO
S
OBn
OAc O BnO BnO
OBn O O
MeI, H2O
BnO BnO
OBn O O
BnO BnO
OH OBn
FIGURE 2.81. Sulfur mediated solid-phase coupling reaction.
unaffordable due its high cost for large-scale processes, lower yields provided, and their limited capability for recognizing a broad range of sugars, especially those not common. Two general approaches have been proposed for the preparation of oligosaccharides through the solid-phase approach (Figure 2.84).88 A solid-phase enzymatic approach for extending the oligosaccharide chain was described by Gijsen et al.88 in which a disaccharide-linker fragment attached to a resin was coupled with the glycosyltransferases UDP-galactose and CMP-NeuAc in the presence of galacosyltransferases and Sialyltransferase as enzymatic catalyst. Final treatment with hydrazine was used to release the tetrasaccharide from the solid support (Figure 2.85).
O O
O
CCl3 HO
O AcO AcO
O
OAc Br i,ii
OH
O
O AcO AcO
O
OAc
O O O
CCl3
O iii
AcO AcO
O
O
OAc AcO AcO
OAc Br
O O
CCl3
O AcO AcO
O
O
OAc AcO AcO
O O
OAc AcO AcO
O
O
OAc
O
AcO
O ii,iii,iv
AcO AcO
OAc Br
AcO
O AcO AcO
O
OAc AcO AcO
O
O
OAc AcO AcO
O
O
OAc AcO AcO
O OAc
i) TBABr, 35oC. ii) MeOH, Py. iii) Hg(CN)2, 30oC. iv) hydrazinium acetate 50oC.
FIGURE 2.82. Solid-phase coupling promoted by Helferich conditions.
OH
124
2. O-Glycoside Formation B
O O BnO
B
OBn O
i,ii
O O BnO
OBn O
OR
SPh iii
HO HO BnO
OBn O
OR
+
B(OH)2
i) BSP, TTBP, Tf2O, –60oC. ii) ROH. iii) Me2CO/H2O.
FIGURE 2.83. Solid-phase synthesis of β-mannoside glycoside.
2.2 Cyclic Oligosaccharides The synthesis of cyclic oligosaccharides involves the preparation of linear saccharides, which ultimately are joined together to form a cyclic macromolecule. There are two main approaches proposed based on the cycloglycosylation step. The first involves the preparation of a long chain having at each end the donor and acceptor functionalities that will be interconnected through a glycosidic bond at a final step, and the second involving the polycondensation of smallest repeating unit called “saccharide monomers.” It has been observed that the later strategy is considered less laborious however produce cyclic oligomers of different size since under these conditions the ring formation step is not controllable. The chemical synthesis of cyclic oligosaccharides has been mainly driven to obtain cyclic (1→4)-linked oligopyranosides, however (1→3), and (1→6) linked cycloforms are also described. In the case of (1→2)-linked oligosaccharides, the ring closure requires about 17 or more glucopyranoside residues because (1→2)linkage composed of pyranoside connected by one equatorial and one axial bond assumes rigid conformations and cannot cyclize.89 The pioneering total synthesis of cyclic oligosaccharide α-Cyclodextrin was carried out by Ogawa’s group in 1985,89 and since then alternative chemical or enzymatic methodologies appeared for preparing cyclic oligosaccharides. Nowadays the industrial production of cyclodextrins relies on the enzymatic conversion of prehydrolyzed starch into a mixture of cyclic and acyclic oligomers. A full report about cyclic oligosaccharides90 proposes four approaches to the synthesis of cyclic oligosaccharides developed during the last 10 years: 1. the stepwise preparation of a linear precursor that is subjected to cycloglycosylation; 2. the one-pot polycondensation /cycloglycosylation of a small “oligosaccharide monomer” typically, a di-, or trisaccharide that can yield a range of macrocycles of different sizes; 3. the enzyme-assisted synthesis of natural or unnatural cyclic oligosaccharides;
2.2. Cyclic Oligosaccharides
125
A) Immobilized substrate Transferases
O O
OH i
O O
O
O OH
Enzyme recovery
i
O O
O
O
O O OH
i) nucleotide sugar transferase
B) Immobilized enzymes
O O
OH
Transferase 1
Transferase 2
Transferase 3
O O
O O
O O OH
FIGURE 2.84. Two general approaches for immobilized solid-phase oligosaccharide synthesis.
126
2. O-Glycoside Formation OH
OH
OH
O
O
HO HO
O O
H N
O
OH
(CH2 )5
OH
O O
UDO-Gal Gal-T Linker
CMP-NeuAc Sialyl-T
CO2H OH
OH O
OH
OH
AcHN
O HO
OH HO
OH
O
O
OH
O
OH O
O
HO
O
OH
linker
OH
FIGURE 2.85. Enzymatic-solid phase glycosylation reaction.
4. the ring opening of cyclodextrins followed by oligosaccharide chain elongation and cycloglycosylation (Figure 2.86). Despite the significant advances observed in cyclic oligosaccharide synthesis, their preparation is time-consuming, producing the target compounds with low regio- and stereoselective in low yields. The total synthesis of α-CD and γ-CD was described according to Figure 2.87.91,92
AG
GD
GD
AG
4 AG = acceptor linear oligosaccharide
disaccharide
O
O
O
GD = donor
O
O
cyclo-oligomerization
O
O
O O
cyclic oligosaccharide
O
O
O enzymatic degradation or
O O
O
O
cyclo-oligomerization
HO
OH n
smaller cyclic oligosaccharide
polysaccharide or disaccharide (n = 0)
FIGURE 2.86. The four suggested approaches to the synthesis of cyclic oligosaccharides.
2.2. Cyclic Oligosaccharides
127
In 1990 it was reported the chemical synthesis of β-(1→3) linked hexasaccharide. The chemical approach involved the glycosidic reaction between benzylidene acceptor and protected glucosyl bromide as glycosyl donor, under silver triflatepromoter conditions. As can be seen in Figure 2.88, the construction of the linear oligosaccharide and its final cycloglycosylation was performed by using glycosyl bromides, which were prepared by photolytic brominolysis of 1,2-O-benzylidene glucose with BrCCl3 (Figure 2.88).93 The formation of (1→6)-glycopyranosidic linkages might produce cyclic ditri- and tetrasaccharides. An early synthesis of β-(1→6)-glucopyranan under Helferich conditions, generated along with the linear oligomer, a cyclic di- and tetrasaccharide in 12 and 6%, respectively (Figure 2.89).94 An improved synthesis of cyclotetraoside was described by the same group 10 years later, consisting in the preparation from the peracetylated tetrasaccharide into the tetrasaccharide derivative having both the acceptor and the donor components. The final cyclization was performed under Helferich conditions providing a mixture of tri- and tetrasaccharide in 22% and 25% yield, respectively (Figure 2.90).95
2.2.1 Chemoenzymatic and Enzymatic Synthesis The use of enzyme is as mentioned for many O- or N-glycosides the parallel possibility for preparing cyclic oligosaccharides. The limitation continues to be
OBn
OBn
O
AcO BnO BnO
OBn O
O BzO
O
HO BnO
+
BnO
F
OBn
OBn O
O BnO
OAll
BnO
OBn HO BnO
i
O OBn O
OBn O BnO
OBnO
OBn O 4BnO
OBn
OBn AcO BnO
O OBn O
OBn O BnO
OBn O
OBn O 6 BnO
OAll
OBn
FIGURE 2.87. Chemical synthesis of cyclic α(1→4)-oligosaccharide γ-CD.
OAll
128
2. O-Glycoside Formation
ii,iii,iv
OBn O
RO BnO
OBn O
OBnO v
BnO
OBn O
OBnO
R = Ac R=H
6
BnO
F
OBn
i
RO OR RO OR
OR O
O
O
RO
O
OR
O OR
O
O
RO
RO
O O
RO
vi
R = Bn R=H
OR
RO
OR
OR O
O
OR
RO
O RO
RO
O
OR O OR
O
O
OR
OR
RO
i) SnCl2/AgOTf. ii) PdCl2/AcOH. iii) SO2Cl2/DMF. iv) AgF/MeCN. v) NaOMe/MeOH/THF. vi) H2, Pd-C, THF-MeOH/H 2O.
FIGURE 2.87. (continued)
the availability and affordability, however. Some enzymes such as glycosidases and cycloglycosyltransferases (CGTases) that are involved in the preparation of cyclodextrins from starch and other α-(1→4)-glucans are accessible and more versatile.95 The feasibility of the chemoenzymatic approach was established in the preparation of cyclic β(1→4) hexa-, hepta- and octasaccharides, from 6-Omethylmaltosyl fluoride when incubated with CGTase. Thus, a mixture of 6I , 6III , 6V -tri-O-methyl-α-CD (42%), 6I , 6III , 6V -tetra-O-methyl-γ-CD (16 %) and in less proportion 6I , 6III , 6V -tri-O-methyl-β-CD was obtained (Figure 2.91).96
2.2. Cyclic Oligosaccharides O O RO
Me
O O HO
Me
O
i-iii
129
O O
OBz Br
Ph
O
R = ClCH2CO-
iv
Me O
O O RO
Me ii,iii
O O O
O v
O
OBz
Ph
R = ClCH2CO-
Me
O O RO
O O O
Me O
BzO
OBz
Me
O
O O O O
Me O
O O HO
O
OBz
Br
O O
Ph
iv,ii,iii
Me
O O RO
O
Me
O
O
O
OBz
Me
O O O
Me O
O O HO
O O HO
BzO 2
O
Ph
O
Me O
O
OBz
Br
O O
OBz
Me
O
O
OBz
R = ClCH2CO-
iv
O
Me
O
O
O
O
O
Me O
O
O
OBz
BzO 4
iv
FIGURE 2.88. Synthesis of cyclic β-(1→3)-linked oligosaccharide.
Br
130
2. O-Glycoside Formation Me O
O
Me O
O O
O O
RO
O
OR O
RO
O
O O
Me
Me
O O O
O
O
OR
O
RO O
OR
O
O O
vi
O
Me
O
R = Bz R=H
Me
FIGURE 2.88. (continued)
HO
HO O
AcO AcO
i
O AcO
O
AcO AcO
O
AcO AcO AcO
O
OAc Br AcO OAc
AcO +
O AcO AcO
OAc OAc O
OAc
AcO O
O
O
OAc AcO AcO
+
AcO
O
O
O
O AcO AcO
OAc OAc
O
O O OAc
OAc
O OAc OAc
i) Hg(CN)2, HgBr2, MeCN.
FIGURE 2.89. Preparation of linear and cyclic β(1→6) di- and tetrasaccharides.
n
2.2. Cyclic Oligosaccharides
131
Cl3CCOO O
AcO AcO
O O
OAc AcO AcO
n=1 n=2
O OAc
n
O
AcO AcO
OAc AcO
i,ii
HO O
AcO AcO
O O
OAc AcO AcO
O OAc
n
O
AcO AcO
Cl AcO
iii
OAc
OAc
AcO AcO
AcO O
AcO O
O
OAc
+
AcO
O
O
O
O
O AcO AcO
O
O O OAc
OAc OAc
OAc OAc
O
O
AcO AcO
OAc
OAc
O OAc OAc
i) Cl2CHOMe, BF3.Et2O/DCE. ii) HgBr2/DCE, MS.
FIGURE 2.90. Improved synthesis of cyclic β(1→6) tri- and tetrasacharides.
Furthermore, under the same conditions it was possible to prepare from the maltotriosyl fluoride the cyclic α(1→4) hexasaccharide (6I , 6II -dideoxy-6I ,6II diiodo-α-CD) in 38% (Figure 2.92).97 An alternative option for the enzymatic preparation of cyclic oligosaccharides besides CGTases are glycosidases, which exert their action on polysaccharides. This possibility was exploited in the preparation of cyclic fructins by conversion of β-(1→2)-fructofuranan by bacterial fructotransferases isolated from Bacillus circulans (Figure 2.93).98
132
2. O-Glycoside Formation MeO HO HO
O HO OH
O
O
HO
OH F
i
O O
OH
HO
OH
HO
O MeO O
OH
HO O
O OMe
HO
OH
HO O
O
OH HO
O OH O HO
OMe O O HO OH OH HO
OH OH O
HO O HO
O
OH HO
O MeO
O HO
O OH
HO O HO
O OH
HO
OH
O OH O
O
O HO O
O OH
O
O OH
OH
OMe
HO
HO O
O HO OH
OH HO
OH OH
O
OMe
O HO
O HO
O
O OMe
HO
O
OH
O MeO
HO
HO HO
O
O
O
MeO O O
HO HO
HO OH
i) CGTase phosphate buffer pH 6.5
FIGURE 2.91. Synthesis of of 6I , 6III , 6V -tri-O-methyl-α-CD, 6I , 6III , 6V -tetra-O-methyl-γCD and 6I , 6III , 6V -tri-O-methyl-β-CD.
OAc
AcO
OAc
O
O O AcO
I O
OAc
AcO O
O OAc
AcO
OAc
AcO O
O
OAc AcO
O
I
OAc O O OAc AcO
O AcO
i) CGTase phosphate buffer pH 6.5
I O
HO HO
OH OH
O
O HO
OH OH
O
O HO
OH F
i
FIGURE 2.92. Enzymatic synthesis of 6I , 6II -dideoxy-6I ,6II -diiodo-α-CD. OH HO HO
HO
OH
O
OH
O OH O
HO
HO
O OH
HO
O OH
O
OH
O O OH O OH HO
i
HO
O OH
O O
n
OH HO
O OH
O O OH
HO O OH
O OH
O OH
HO O OH
OH
OH OH n = ca. 35 i) CFTase phosphate buffer pH 7.0
FIGURE 2.93. Enzymatic synthesis of cycloinulooligosaccharides.
OH
134
2. O-Glycoside Formation
Summary of Preparation of the Main Glycosyl Donors OAc
OAc AcO AcO
O
HBr/AcOH 33%
OAc
OAc CH2Cl2, r.t., 12 h
OAc
OAc AcO AcO
O
AcO AcO
Br
OAc
O
Cl3CCN/Cs2CO3
OAc
OH CH2Cl2, r.t., 12 h
AcO AcO
O OAc
CCl3
O NH
OAc AcO AcO
OAc PhSNa
O
Et2O/H2O
OAc
AcO AcO
Br
OAc
OBn BnO BnO
EtSH/BF3-Et2O
O OAc
SPh
OAc
OAc AcO AcO
O
OAc
CH3Cl
O
AcO AcO
CH2Cl2, 0oC, 1 h
SEt
OAc
OBn
O
O
O
BnO BnO
O
O
References 1. 2. 3. 4. 5. 6. 7. 8.
K. Toshima, and K. Tatsuta, Chem. Rev. 93, 1503 (1993). F.B. Anderson, and D.H. Leaback, Tetrahedron 12, 236 (1961). H.P. Wessel, Carbohydr. Chem. 7, 263 (1988). Y.F. Shearly, C.A. O’Dell, and G. Amett, J. Med. Chem. 30,1090 (1987). W. Koenigs, and E. Knorr, Chem. Ber., 34, 957 (1901). K. Igarashi, Adv. Carbohydr. Chem.Biochem., 34, 243 (1977). J.-H. Kim, H. Yang, J. Park, and G-J. Boons, J. Am. Chem. Soc., 127, 12090 (2005). M.P. De Ninno, P.A. McCarthy, K.C. Duplatiel, C. Eller, J.B. Etienne, M.P. Zawistowski, F.W. Bangerter, C.E. Chandler, L.A. Morehouse, E.D. Sugarman, R.W. Wilkins, H.A. Woody, and L.M. Zaccaro, J. Med. Chem. 40, 2547 (1997). 9. R.B. Conrow, and S. Bernstein, J. Org. Chem. 36, 836 (1971). 10. A.V. Stachulski, and G.N. Jenkins, Natural Products Reports 173 (1998). 11. A. Bredereck, A. Wagner, H. Kuhn, and H. Ott, Chem. Ber. 93, 1201 (1960).
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18. 19. 20. 21.
22. 23. 24. 25. 26. 27. 28. 29.
30.
31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43.
135
P. B¨achli, E.G. Percival, J. Chem. Soc. 1243 (1952). A.Y. Khorlin, I. M. Privalova, and I.B. Bystrova, Carbohydr. Res. 19, 272 (1971). H. Paulsen and H.Tietz, Angew. Chem. Int. Ed. Engl. 21, 927 (1982). H.P. Wessel, N. Iberg, M. Trumtel, and M.-C. Viaud, BioMed. Chem. Lett. 6, 27 (1996). K. Katano, H. An, Y. Aoyagi, M. Overhand, S.J. Sucheck, W.C. Stevens Jr., C.D. Hess, X. Zhou, and S.M. Hecht, J. Am. Chem. Soc. 120, 11285 (1998). (a) S. Umezawa, S. Koto, K. Tatsuta, H. Hineno, Y. Nishimura, and T. Tsumura, Bull. Chem. Soc. Jpn., 42, 529 (1969). (b) S. Hanessian, M. Tremblay, and E.E. Swayze, Tetrahedron, 59, 983 (2003). (c) H. Tanaka, Y. Nishida, Y. Furuta, and K. Kobayashi, Bioorg. Med. Chem. Lett., 12, 1723 (2002). H.J. Roth and A. Kleeman, Pharmaceut.Chem. 7, 263 (1988). T. Suami, T. Otake, T. Nishimura, and Y. Ikeda, Bull. Chem. Soc. Jpn. 46, 1014 (1973). N. Bagget, A.K. Samra, and A. Smithson, Carbohydr. Res. 124. 63 (1983). (a) R.R. Schmidt, Angew. Chem. Int. Engl., 25, 213 (1986). (b) R.R. Schmidt, and K.-H. Jung, Carbohydr. Eur., 27, 12 (1999). (c) R.R. Schmidt and W. Kinzy, Adv. Carbohydr. Chem. Biochem., 50, 21 (1994). A. F¨urstner and T. M¨uller, J. Am. Chem. Soc. 121, 7814 (1999). A. Hasegawa, K. Fushimi, H. Ishida, and M. Kiso, J. Carbohydr. Chem. 12, 1203 (1993). S. Danishefsky and M.D. Shair, J. Org. Chem. 16, 61 (1996). D.P. Larson, C.H. Heathcock, J. Org. Chem. 62, 8406 (1997). S.F. Lu, Q.O. O’Yang, Z.W. Guo, B. Yu, and Y.Z. Hui, J. Org.Chem. 62, 8400 (1997). M. Brito-Arias, R. Pereda-Miranda, and C.H. Heathcock, J. Org. Chem. 69, 4567 (2004). (a) G.J. Boons, S. Isles, J. Org. Chem. 61, 4262 (1996). (b) G.-J. Boons, Contemporary Organic Synthesis 3, 173 (1996). (a) S. Komba, H. Galustian, H. Ishida, T. Feizi, R. Kannagi, and M. Kiso, Angew. Chem. Int. Ed. 38, 1131. (1999). (b) Y. Zhang, A. Brodsky, P. Sinay, Tetrahedron: Asymmetry 9, 2451 (1998). (c) A. Hasegawa, K. Ito, and H. Ishida, Kiso J. Carbohydr. Chem. 266, 279 (1995). (a) A. Koenig, R. Jain, R. Vig, K.E. Norgard,-Sumnicht, K.L. Matta, and A. Varki, Glycobiology, 7, 79 (1997). W.J. Sanders, E. J. Gordon, O. Dwir, P. J. Beck, R. Alon, and L.L. Kiessling, J. Biol. Chem. 274, 5271 (1999). A. Lubineau, J. Alais, and R. Lemoine J. Carbohydr. Chem. 19, 151 (2000). K.C. Nicolaou, T. Ohshima, F.L. van Delft, D. Vourloumis, J.Y. Xu, J. Pfefferkorn, and S. Kim, J. Am. Chem. Soc. 120, 8674 (1998). H. Lonn, Carbohydr. Res. 115, 139 (1985). S.V. Ley, and H.W. Priepke, Angew. Chem. Int. Engl. 33, 2292 (1994). K. Hotta, H. Ishida, M. Kiso, and A. Hasegawa, J. Carbohydr. Chem. 14, 491 (1995). D. Crich, and H. Li, J. Org. Chem. 67, 4640 (2002). Y. Jing, ad X. Huang, Tetrahedron Lett. 45, 4615 (2004). D.R. Mootoo, P. Konradsson, U. Udodong, and B. Fraser-Reid, J. Am. Chem. Soc. 110, 5583 (1988). J.D.C. Codee, R.E.J.N. Litjens, R. den Heeten, H.S. Overkleeft, J.N. van Boom, and G.A. van der Marel, Org. Lett. 5, 1519 (2003). M. Yoshida, T. Kiyoi, T. Tsukida, and H. Kondo, J. Carbohydr. Chem. 17, 673 (1998). A.V. Demchenko, N.N. Malysheva, and C. De Meo, Org. Lett. 5, 455 (2003). E. Fischer, and K. Zach, Sitz. ber. kgl. preuss. Akad. Wiss., 16, 311 (1913). B. Freiser-Reid, D.R. Kelly, D.B. Tulshian, and P.S. Ravi, J. Carbohydrate Chem. 2, 105 (1983).
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53. 54. 55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78.
2. O-Glycoside Formation B.K. Shull, Z. Wu, and M. Koreeda, J. Carbohydr. Chem. 15(8), 955 (1996). R.W. Murray and R. Jeyaraman, J. Org. Chem. 50, 2847 (1985). W. Adam, J. Bialas, and L. Hadjiarapoglou, Chem. Ber. 124, 2377 (1991). C.H. Marzabadi, and C.D. Spilling, J. Org. Chem. 58, 3761 (1993). G. Belluci, G Catelani, G., Chiappe, C., D’Andrea, F., Tetrahedron Lett. 53, 10471 (1997). Y. Du and F. Kong, J. Carbohydr. Chem. 14(3), 341 (1995). R.L. Halcomb and S.J. Danishefsky, J. Am. Chem. Soc. 111, 6661 (1989). M. Upreti, D. Ruhela, and R.A. Vishwakarma, Tetrahedron 56, 6577 (2000). J. Broddefalk, K.-E. Bergquist, and J. Kihlberg, J. Tetrahedron Lett. 1996, 37, 3011. Broddefalk, J.; B¨acklund, J.; Almqvist, F.; Johansson, M.; Holmdahl, R.; Kilhberg, J. J. Am Chem. Soc. 120, 7676 (1998). H. Kunz, Angew. Chem. Int. Ed. Engl. 26, 294 (1987). C-H. Wong, Y. Ichikawa, T. Krach, C. Gautheron,-Le Narvor, D.P. Dumas, and G.C Look, J. Am. Chem. Soc. 113, 8137 (1991). M. Shimizu, H. Togo, and M. Yokohama, Synthesis 6, 779 (1998). M. Morita, T. Natori, K. Akimoto, T. Osawa, H. Fukushima, and Y. Koezuka, BioMed. Chem Lett 5, 699 (1995). T. Mukaiyama, Y. Hashimoto, S. Shoda, Chem. Lett. 1983, 935. K.C. Nicolaou, and N.J. Bockovich,, and D.R. Carcanague, J. Am. Chem. Soc. 115, 8843 (1993). L.F. Tietze and R. Fischer, Angew. Chem. 5, 902 (1983). S. Metha, and B.M. Pinto, J. Org. Chem. 58, 3269 (1993). A. Sobti, K. Kim, and G.A. Solikowski, J. Org. Chem. 6, 61 (1996). K. Takeda, E. Kaji, H. Nakamura, A. Akiyama, A. Konda, and Y. Mizuno, and H. Takayanagi, and Y. Harigaya, Synthesis 341 (1996). D.M. Garcia, H. Yamada, S. Hatakeyama, and M. Nishikawa, Tetrahedron Lett. 35, 3325 (1994). H. Nagai, S. Matsumura, and K. Toshima, Tetrahedron Lett. 43, 847 (2002). K. Toshima, H. Nakai, and S. Matsumura, Synlett 9, 1420 (1999). K. Toshima, K. Kasumi, and S. Matsumura, Synlett 6, 813 (1999). M. Oikawa, T. Tanaka, N. Fukuda, S. Kusumoto, Tetrahedron Lett. 45, 4039 (2004). (a) F. Burkhart, Z. Zhang, S. Wacowich-Sgarbi, and C-H Wong, Angew. Chem. Int. Ed. 40, 1274 (2001). (b) Lahmann, M., Oscarson, S. Org Lett. 2, 3881 (2000). J.M. Coteron, K. Singh, J.L. Asensio, M. Domingues-Dalda, A. Fernandez-Mayoralis, J. Jimenez-Barbero, and M. Martin-Lomas, J. Org. Chem. 60, 1502 (1995). K.G. Nilsson, Carbohydr. Res. 95, 167 (1987). G.A. Freeman, S.R. Shauer, J.L. Rideout, and S.A. Short, Bioorg. Med. Chem. 3, 447 (1995). E.S. Simon, S. Grabowski, G.M. Whitesides, J. Org. Chem. 55, 1834 (1990). Y. Ichikawa, G.J. Shen, C.-H. Wong, J. Am. Chem. Soc. 113, 4698 (1991). J.J. Gaudino, J.C. Paulson, J. Am. Chem. Soc. 116, 1149 (1994). J.E. Heidlas, W.J. Lees, P. Pale,and G.M. Whitesides, J. Org. Chem. 57, 146 (1992). E.J. Toone, E.S. Simon, and G.M. Whitesides, J. Org. Chem. 56, 5603 (1991). J.L.C. Liu, G.-J. Shen, Y. Ichikawa, J.F. Rutan, G. Zapata, W.F. Vann, and C.-H. Wong, J. Am. Chem. Soc. 114, 3901 (1992). L.F. Mackenzie, Q. Wang, Q., R.A.J. Warren, and S.G. Whiters, J. Am. Chem. Soc. 120, 5583 (1998).
References
137
79. D.G. Drueckhammer. W.J. Hennen, R.L. Pederson, C.F. Barbas III, C.M. Gautheron, T. Krach, and C.-H. Wong, Synthesis, 499 (1991). 80. X. Zeng, T. Murata, and T. Usui, J. Carbohydr. Chem. 22, 309 (2003). 81. B.N. Cook, S. Bhakta, T. Biegel, K.G. Bowman, J.I. Armstrong, S. Hemmerich, and C.R. Bertozzi, J. Am. Chem. Soc. 122, 8612 (2000). 82. H. Akita, E. Kawahara, and K. Kato, Tetrahedron Asymmetry 15, 1623 (2004). 83. C.-H. Wong, S.L. Haynie, G.M. Whitesides, J. Org. Chem. 47, 5416 (1982). 84. (a) K.C. Nicolaou, N. Watanabe, J. Li, J. Pastor, and N. Winssinger, Angew. Chem. Int. Ed. 37, 1559 (1998) K.C. Nicolaou, N. Winssinger, J. Pastor, and F. De Roose, J. Am. Chem. Soc. 119, 449 (1997) Wong, C.-H., Ye, X.-S., Zhang, Z. J. Am. Chem. Soc. 120, 7137 (1998). (b) S.A. Mitchell, M.R. Pratt, U.J. Hruby, and R. Polt, J. Org. Chem. 66, 2327 (2001). 85. P.H. Seeberger and W.C. Haase, Chem Rev. 100, 4349 (2000). 86. P. Sears. and C.-H. Wong, Science 291, 2344 (2001). 87. D. Crich and M. Smith, J. Am. Chem. Soc. 124, 8867 (2002). 88. H.J.M. Gijsen, L. Qiao, W. Fitz, and C.-H. Wong, Chem Rev. 96, 443 (1996). 89. G. Gattuso, S.A. Nepogodiev, and J.F. Stoddart, Chem. Rev. 98, 1919 (1998). 90. T. Ogawa and Y. Takahashi, Carbohydr. Res. 138, C5 (1985). 91. Y. Takahashi and T. Ogawa, Carbohydr. Res. 169, 277 (1987). 92. P.M. Collins and M.H. Ali, Tetrahedron Lett. 31, 4517 (1990). 93. D. Bassieux, D. Gagnaire, and M. Vignon, Carbohydr. Res. 56, 19 (1977). 94. G. Excoffier, M. Paillet, and M. Vignon, Carbohydr. Res. 135, C10 (1985). 95. N. Nakamura, Methods Carbohydr. Chem. 10, 269 (1994). 96. S. Cottaz, C. Apparu, and H. Driguez, J. Chem. Soc., Perkin Trans. 1 2235 (1991). 97. C. Apparu, S. Cottaz, C. Bosso, and H. Driguez, Carbohydr. Lett. 1, 349 (1994). 98. M. Kamakura and T. Uchiyama, Biosc. Biotechnol. Biochem. 57, 343 (1993).
3 N-Glycosides
These types of glycosides are generated when a sugar component is attached to an aglycon, through a nitrogen atom, establishing as a result a C-N-C linkage. Nucleosides are among the most relevant N -glycosides since they are essential components of DNA, RNA, cofactors, and a variety of antiviral and anti-neoplasic drugs. Usually for nucleosides, a pyrimidine or purine base is linked to the anomeric carbon of a furanoside ring. The nucleosides responsible for the formation of the genetic material DNA and RNA are adenine, guanine, cytidine, and thymine, the latter exchanged by uracil in the case of RNA (Figure 3.1). Nucleosides can be classified in natural nucleosides such as those involved in the genetic storage of information, naturally modified nucleosides, and synthetic nucleosides. Naturally modified nucleosides include a significant and diverse number of compounds, some of them with slight changes mostly at the base, or major structural modifications done by enzymes. So far most of them have unknown biochemical function;1 nonetheless they have been strongly associated with antiviral, antitumoral, and growth regulation processes (Figure 3.2). Representative examples of natural modified nucleosides includes queuosine (Q) and Wye base (W), which have been found in the tRNA of some plants and bacteria, and it plays an important rule in the inhibition of tumor processes. Derived from this relevant biological function the total synthesis of these unique nucleosides have been reported for Q2–4 and W.5 Moreover, the synthesis of complex nucleoside antibiotics has been reviewed.6 The analysis was focused on the challenging synthetic methods for carbohydrate and nucleoside chain elaboration, glycosidation, and methods for controlling stereochemistry and for joining subunits. As a result, the total synthesis of Polyoxin J,7 sinefungin,8 thuringiensin,9 tunicamycin V,10 nikkomycin B,11 octosyl acid A,12 hikizimycin,13 and capuramycin14 was completed (Figure 3.3). Important cofactors playing a key rule as biological catalysts required by the enzymes for the optimal performance of biochemical transformations are nucleotides. Such is the case of adenosine triphosphate ATP and nicotinic acid adenine dinucleotide NAD that are constituted by an adenosine nucleoside combined with phosphate for the former, and phosphate and nicotinamide for the latter (Figure 3.4). 138
3.1. Nucleoside Formation O
NH2 5 4
3N
6 1
2
N
O NH
N
O
NH O
N
HO
HO
O
O 3'
O
1'
2'
OH
OH
R
R = OH R= H
R
OH
thymine
Heterocyclic base = cytosine
uracil
thymidine
DNA nucleoside = 2' deoxycytidine
uridine
RNA nucleoside = cytidine
NH2 N 7 8
9
N
O N
5 6 1N 4 3 2
NH
N
N
N
HO
5'
O 4'
R
R= OH
R= H
HO
O
HO
5' 4'
139
3'
OH
NH2
O 2'
1'
R
OH
R
R=H R = OH Heterocyclic base = adenine DNA nucleoside = 2' deoxyadenosine RNA nucleoside = adenosine
guanine 2' deoxyguanosine guanosine
FIGURE 3.1. DNA and RNA nucleosides.
3.1 Nucleoside Formation Considering a disconnection analysis, there are two major general routes for nucleoside syntheses.15 The first is based on the attachment between the aglycon base and the protected sugar activated with a good leaving group at the anomeric position. Under these conditions, the stereoselectivity is conditioned by the protecting group attached at position 2. The second general procedure considers the coupling reaction between a base precursor and the sugar derivative, which contains the free amine linked to the anomeric carbon. The ring closure generally takes place after the glycosidation reaction and the configuration is predetermined by the nitrogen attached to the anomeric carbon. The latter approach has been most efficiently used for preparing carbocyclic nucleosides (Figure 3.5).
140
3. N-Glycosides O
O H3CHNH2C
NH N R
O NH
O
N R
dihydrouridine
NH S
N R ribothymidine (T)
5-methylaminomethyl-2-tiouridine (mmm5s2U)
O
O
O
CO2H
MeO NH N R
O
5-methoxyuridine
N R
CH2CO2CH3
N R
uridine-5-oxyacetic acid
CH3
H3C
NHCOCH3 CH3
N R
5-methylthiouridine
O
N 4-cetylcytidine
O
thiouridine
O
NH2
N R thiocytidine
CH2CO2CH3
HN
N O
N R
(m5C)
N N R
NH
5-methylcytidine
(m3C)
(mcm5U)
S
N N R
O
3-methylcytidine
5-(methoxycarbonylmethyl)uridine
S
O
NH2 N
N R
HN
N R
O
NH
O
NH
(acp3U)
O HN
HO2CH2CO
3-(3-amio-3-carboxypropyl)uridine
(mo5U)
O
NH2
N
O
S
S
N R
5-(methoxycarbonylmethyl)-2-thiouridine
(m5S2U)
(mcm5S2U)
FIGURE 3.2. Naturally modified nucleosides.
3.2 Protecting Groups It has been mentioned in the previous chapter that protecting groups are important components for most of the general methodologies designed for establishing glycosidic bonds. Usually the methods for glycoside formation require prior protection of those elements (usually heteroatoms) within the molecule that are needed
O
O N
N
NH
N R
N
N R
N inosine (I)
N R
CH3
N
NH
N R
N
N
1-methylinosine
N6-methyladenosine
(m1I)
(m6A)
O
NH N
NHCH3
N
CH3
O
N
N
N R
N
CH3
N N R
NH2
N
1-methylguanosine
1-methyladenosine
CH3
(m2G)
NHCO2CH3
O O
N N R
N
2-methylguanosine
(m1G)
(m1A)
NH
NH N
CO2CH3
N
N CH3
NH2
N R
N H
N H
7-methylguanosine
base W
(m7G)
HO
R2O HN
O N
NH
N R
N
NH2
queuosine (Q) R2 = mannose or galactose R, R2 = H queuine
FIGURE 3.2. (continued)
NHCH3
142
3. N-Glycosides
to remain unaltered. Also important is the fact that the cleavage of the protecting group should be carried out under preferentially mild conditions, and in the case of complex nucleosides the installation and removal of the protecting groups for nitrogen, oxygen, and sulfur should be accomplished under compatible conditions. The protection and deprotection of nucleosides can be done by chemical or enzymatic means. Some of the most commonly used protecting groups used in the preparation of O-glycosides are also useful in the synthesis of nucleosides (Figure 3.6).
3.2.1 Ribofuranoside Protecting Groups Enzymes have been found to be interesting alternatives for installing protecting groups on nucleosides. Some of the enzymes used for this purpose are subtilisin mutant (8350)16 and lipases mainly from Pseudomona and Candida strains.17 Representative protections of purine and pyrimidine nucleosides are indicated in Figure 3.7. By using the appropriate lipase it is possible to achieve regioselective acyl protections on nucleosides. For instance, the enzymatic transesterification reaction of 5 -fluorouridine with n-octanoic anhydride catalyzed with Candida Antarctica (CAL), Pseudomona sp. (PS), (KIWI-56), and Mucor javanicus (M) lipase was performed, producing 5 -, 3 - and 2 -acylnucleosides, respectively (Figure 3.8).18 Regioselective removal of certain protecting groups such as acetates attached to the ribosyl moiety of nucleosides might be carried out by enzymes. For instance, Subtilisin strain selectively hydrolyzes the 5 -position of purine and pyrimidine tri-O-acylated esters to produce 2 ,3 -di-O-Acylribonucleosides in 40–92% (Figure 3.9).19 On the other hand, diastereoselective deacetylation of peracetylated 2 deoxyribofuranosyl thymine was carried out using wheat germ lipase (WGL) and
CH3 O O
OH
O
CO2H O
H2N
N
NH
N H
O OH
NH2
O HO
OH
polyoxin J
FIGURE 3.3. Complex nucleoside antibiotics.
3.2. Protecting Groups N
NH2 O
143
NH2
N
HO2C
N N
NH2 HO
OH
sinefungin
OH AcHN
OH OH
O
O
H N
(CH3)2CH(CH2)9
O O
OH O
O
N
NH
HO OH
O HO
OH
tunicamycin V
NH O HN
O
O
O
NH2 O
O N
NH
O
HO OH
O H3CO
OH
capuramycin
FIGURE 3.3. (continued)
ATP
NH2 O N
N
H2N O N
O
P
O O OH
O O
P
−
N
O O
−
O
P O
O
N
O
−
OH
OH
OH
NAD+
FIGURE 3.4. Structure of nucleoside cofactors ATP and NAD. R2
R2 R2 N
N
N H
R1O
N
RO Cl
R1O
N
OR1
C Y
N N
R3
X
N N
N
X
RO
X
R3
N
NH2
X
X = O, S, CH2
RO
R1 = Ac, Bz, Tol, Bn R2= NH2, OH R3 = H, NH2
OR OR
FIGURE 3.5. General procedures for N-glycoside formation. Acetate (CH3CO-)
HO
AcO
O OH
O OAc
i
OH OH
i) Ac2O, CH 2Cl2, DMAP, r.t.
cleavage: (1) NaOMe, MeOH. (2) Aqueous NH3, dioxane.
FIGURE 3.6. Common ribose protecting groups.
OAc OAc
OR
3.2. Protecting Groups
145
Benzoyl (PhCO-).
O
O CH 3
HN O HO
CH 3
HN i
N
O
N
BzO
O
OH
O
OBz
i) Bz-Cl, pyridine.
cleavage: (1) R-NH2, EtOH, 100oC. (2) EtOH, KOH, reflux, 3 h. (3) NH3, MeOH
Toluyl (p-MePhCO-)
Cl
Cl N N HO
N
N
N
N
i
TolO
O
O
OTol
OH
i) Tol-Cl, pyridine. cleavage: NH3, MeOH, 100oC, 78%.
Pivaloyl (Me3CCOCl )
HO
T O
PivO i
i) Piv-Cl, pyridine. cleavage: NaOMe, MeOH.
FIGURE 3.6. (continued)
T O
N N
Trityl (Ph3C-)
HO
TrO
O OH
O OH
i
OH OH
OH OH
i) Tr-Cl, pyridine, r.t.
cleavage: (1) 80%, AcOH, 60oC. (2) HCO2H, Et2O.
Benzyl (PhCH2-)
T
HO
T
BnO
O
O
i
OBn OBn
OH OH i) BnBr, NaH, DMF.
cleavage: H2/Pd(OH)2 , EtOH.
Tertbutyldimethylsilyl (tBuMe2Si-)
U HO
O
U i
OH
TBDMSO
O
OH
i) TBDMS-Cl, pyridine, r.t.
cleavage: (1) tetrabutylammonium fluoride (TBAF). (2) pTsOH, MeOH, H 2O, 7h.
FIGURE 3.6. (continued)
3.2. Protecting Groups
147
Tetraisopropylsilyl ([( iPr)2Si]2O-)
HO
O
O
O
O
iPr2Si
i
O
O iPr2Si
HO
O
i) Pr2iSi(Cl)OSi(Cl)Pr2i, imidazole, THF, rt, 90 min.
cleavage: Bu4NF, THF.
FIGURE 3.6. (continued)
porcine liver esterase (PLE), affording pure β-anomer thymidine in 29 and 31%, respectively (Figure 3.10).20 When porcine pancreas lipase (PPL) in phosphate buffer is used for deacetylation of 3 ,5 -di-O-acetylthymine, the removal of the acetyl group at the 5 -position is achieved, leading to the 3’-O-acetylthymidine (Figure 3.11).20 Other suitable selective protections and deprotections useful for chemical manipulations that might occur at the ribosyl moiety are illustrated in Figure 3.12.
HO
B
AcO
B
AcO
O
O i
OH
X
OH
X
B = T, U, C, A X = H, OH i) Subtilisin 8350, DMF. 65-100%
O F
O CO2H
F
CO2H
i
N HO O
N O
R
O O
i) Pseudomona cepacea lipase, RCO2Et, AcOEt, rt, 72h.
FIGURE 3.7. Enzymatic regioselective acylation by oximeacetates and lipases.
148
3. N-Glycosides HO
B O
i
O
R HO
O
O
B O
N +
O
R
OH O
R
B = T, A
B O
ii
O OH i) Pseudomona cepacea llipase (PSL), Pyridine. ii) Candida antartica lipase (CAL), THF.
FIGURE 3.7. (continued) O F NH HO
N
B ii
O
O
R
O R
O
O
B
i
HO
O O
OH OH OH
O R = CH3(CH2)6−
OH
iii
HO
B O
OH
R
O O
i) Candida antarctica lipase (CAL), 90%. ii) Pseudomona sp. lipase (PS), 92%. iii) Mucor javanicus lipase (M), 42%.
FIGURE 3.8. Regioselective acyl protection by lipase.
OH
3.2. Protecting Groups AcO
OAc
HO
B
O
i
B
O
OAc
OAc
149
OAc
B = U, C, A, G, N-2AcG, H i = Subtillisin or PPL, organic solvent, phosphate buffer, pH 7.
FIGURE 3.9. Selective enzymatic 5 -acetyl deprotection. O
O
NH
NH i
N
AcO
N
HO
O
O
O
O OH
OAc
i) WGL, phosphate buffer, 29%. or PLE, phosphate buffer, 31%.
FIGURE 3.10. Lipase-catalyzed deacetylation of anomeric nucleoside.
Regioselective protections and deprotections is often a critical step especially for the preparation of complex nucleosides. Some suitable deprotections of complex nucleosides that do not alter the original composition of the structure have been described (Figure 3.13).6
O
O NH
NH i
N
AcO
O
O
OAc
N
HO
O
O
OAc
i) PPL, phosphate buffer, 98%.
FIGURE 3.11. Selective enzymatic.5 -deacetylation of 3 ,5 -di-O-acetyl thymidine.
150
3. N-Glycosides NBn2
NBn2 N
N
N
N
BnO
O
BnO
N
N i
BnO
N
N
O
BnO
OBn
OH
i) t-BuMgBr, PhH, 80oC, 69%
Ref.21 Cl
Cl N
N
N
N TrO
N
N
N
N
i,ii
HO
O
O
OH OBn
OBz OH i) BnOH, Me2NCON=NCONMe2. ii) NH 3/MeOH
Ref.22 B HO
O
OH OH
B DMTO i-iv
O
OH OTBDMS
B = G, A, C, U i) t-Bu2Si(OTf) 2, Im, DMF, 0oC. ii) t-BuMe2SiCl, Im, DMF, 60oC, 80-87%. iii) HF-Py, CH2Cl2, 0oC, 90% iv) DMT-Cl, Py, 0oC, 90%.
Ref.23 FIGURE 3.12. Miscellaneous chemical protection and deprotection.
3.3. General Methods BnO
BnO
O
O
O
O
OH
i
O
O
151
O
i) DIBAL, NiCl2, Et2O, 0oC, 55%
Ref.24 NH2
NH2 N N ButMe2SiO
N
N
N
i
N
HO
O
O
N
O
OSiMe2But
N
O
OSiMe2But
i) CF3COOH-H 2O (9:1), 0oC, 95 %.
Ref.25 FIGURE 3.12. (continued)
3.3 General Methods The following are general methods that we will explain in this section: r Michael reaction r Fischer-Helferich reaction
NH O O HN O
O
O
AcO
O
NH2 N
OAc
O H3CO
FIGURE 3.13. Suitable deprotection of complex nucleosides.
NH
O
OPiv
1. NaOH, aq MeOH, 2.5 h (cleaves O-Ac and O-Piv)
152
3. N-Glycosides O
Boc-O CH3
O
H N
CO2H
CHO
O
N
N H O
N Boc
HO
OH
1. TFA, 0oC, 15 min. (cleaves O- and N-BOC) 2. H2O, then lyophilize (cleaves acetal)
N3
OPiv OPiv
PivO AcHN
N
O
O OAc
O N
OAc
O OBn
AcO
OAc
OAc
N3 OAc
1. DDQ, CH2Cl2, 58oC, 43h (cleaves O-Bn) 2. n-Bu4NOH, MeOH, reflux, 2 h (cleaves acyls) 3. H2, Lindlar, H2O (reduces azide groups)
TBSO CH3
O
CO2Bn
O O
N
N H TBDPS O
N3 HO
OH
NH O
1. n-Bu4NF, THF, 30 min. (cleaves 2 O-SiR3) 2. H2, 10 % Pd-BaSO4, aq. MeOH, 30 min. (cleaves benzyl ester and reduces -N3)
FIGURE 3.13. (continued)
r r r r r r
Davol-Lowy reaction Silyl-mediated reaction Sulfur-mediated reaction Mitsunobu reaction Palladium-mediated reaction Microbial/enzymatic approach
3.3. General Methods
153
OTBS AcHN
O O
Cbz
H N
O
O O
O OH O
N
BOMO
BOC OH
O OH
HO
1. 10% HCO2H, Pd, 1.5 h (cleaves O-BOM, N-Cbz) 2. 13% HCO2H, MeOH, 40oC, 5 h (cleaves N-BOC, acetonide) 3. HF, MeOH, CH3CN (cleaves O-TBS)
FIGURE 3.13. (continued)
3.3.1 The Michael Reaction 3.3.1.1
General Figure and Conditions
O
N
promoter +
PO
X
O N H
PO
X = Cl, Br
Promoter
Conditions
NaH K2 CO3 KOH-TBA
DMF DMF CH2 Cl2
It is a classical procedure for preparing nucleosides, and it can be considered a modified O-glycoside approach. In this way, the sugar derivative is an R-Ofuranosyl halide, where R can be acyl-, benzoyl, benzyl, tosyl, or silyl, and the halogen commonly chlorine instead of bromine, since it has probed to be more stable for furanose derivatives than its counterpart. The nitrogen base (purine or pyrimidine) is reacted under basic conditions, usually NaH or K2 CO3 in DMF (Figure 3.14). A variety of antibiotics have been prepared according to this method, as in the case of the nucleoside known as methyltubercidine. For achieving this goal, the 7-deazaguanine was used as the nitrogen base, which was condensed to
154
3. N-Glycosides O O
NH
RO
O i,ii
NH
+
N H
O
N
RO
Cl
O
O
OR OR
OR OR
i) NaH/DMF. ii) MeONa/MeOH
FIGURE 3.14. The Michael modification.
2,3,5-tri-O-benzylribofuranosyl bromide under NaH/DMF conditions to afford a 1:1 anomeric mixture of the N-glycoside (Figure 3.15).26 More recently, Battaharya27 reported the synthesis of fluoroarabinotubercidine, toyocamicine, and sangivamicine, under the current N-glycoside formation OCH3 OCH3
CH3
BnO
N
O i
N
+
N H
N
N
N
H3CS
Br H3CS
CH3
BnO
OBnOBn
O
OBnOBn OCH3
CH3
OCH3
N
N N
N ii-vi
CH3
HO
O
O
O
N
N
vii-ix
AcO
O
OH OH
i) NaH/DMF. ii) Ni/EtOH-PhH. iii) HCl/dioxane. iv) H2, Pd-C. v) a) acetone/p-TsOH. b) Ac2O/Py. vii) POCl3. viii) NH3/MeOH. ix) F3CCOOH/H2O.
FIGURE 3.15. Synthesis of methyltubercidine.
3.3. General Methods
155
procedure. Other deazapurines have been described by Seela et al.28 involving the condensation between the purine base, with protected ribosyl halides under basic conditions. According to Seela29 and Kazimierczuk,30 the stereoselective glycosylation of the sodium salts of halopurines, with 2-deoxy3,5-di-O- p-tolouyl-α-D-erytro-pentofuranosyl chloride, gave β-nucleosides via Walden inversion. This was demonstrated in the preparation of 2-amino 2 desoxytubercidine and 2-aminotubercidine by condensation of 3,5-di-O-(ptolyl)-α-D-pentafuranosylchloride and 5-O-[(1,1-dimethylethyl)dimethylsilyl]2,3-O-(1-methylethyliden)-α-D-ribofuranosylchloride with the halopurine under Michael conditions. Final ammonia treatment provided the target deazanucleoside (Figure 3.16). The 7-deazapurine nucleoside Cadeguomycin isolated from strain of the actinomycete culture filtrate Streptomyces hygroscopicus was also synthesized under this approach. Thus, coupling reaction between protected 7-deazapurine derivative with 1-chloro-2-deoxy-3,5-ditoluyl-α-D-erythro-pentofuranose was effected with preference for the β-isomer. Subsequent transformations provided the target molecule 2 -deoxycadeguomycin (Figure 3.17).31
NH2 Cl TsO
N
O
N
i,ii,iii
+
H2 N
N H
N
H2 N
Cl
N
N HO O
OTs
OH
NH2 Cl SiO
N
O i,iii,iv
N +
H2 N
N
N H
Cl O
O
N
N
H2 N HO
O
OH OH i) KOH, TBA/CH2 Cl2 . ii) MeONa/MeOH. iii) NH3/MeOH. iv) CF 3COOH/H2 O.
FIGURE 3.16. Synthesis of 2-aminotubercidine and 2-amino-2 -deoxytubercidine.
156
3. N-Glycosides O CO2Me MOM
N
O CO2Me MOM
N
O
TolO
Cl
N H
N
N R1
O
i
+ N R1
O
TolO
O
TolO ii
R 1 = BOM
TolO
R1 = H
(α:β; 1:5.5)
O CO2H
O CO2Me R3
HN
N
iii
R2
HO TolO
N
N
H2 N
vi
N
N
O
O
HO TolO iv
R2 = ArSO2O, R3 = CH2OCH3 R2 = PhCONH, R3 = CH2OCH 3
v
R2 = PhCONH, R3 = CH2OCH3
i) NaH, CH3CN, 25oC. ii) H2/Ph(OH)2, MeOH, 25oC. iii) NaH, THF, TIPBS-Cl. iv) PhCONH2, NaH, THF. v) TFA, CH2Cl2.
FIGURE 3.17. Synthesis of 7-deazapurine nucleoside 2-deoxycadeguomycin.
3.3.2 The Fischer-Helferich Reaction 3.3.2.1
General Figure and Conditions
O
N
promoter +
PO
X
O N H
PO
X = Cl, Br
Promoter
Conditions
Silver salts
xilene
This general procedure consists in the use of an acylfuranoside or acylpyranoside, which is reacted with the silver or mercury salts of a nitrogen base. The
3.3. General Methods
157 CH3
O H3C
OAc
N
N
CH3
O
N Ag H
N
O
AcO
i
OAc
Cl +
O
N
Cl
O
N
N
N
Br
OAc
O
OAc
OAc
CH3
OAc OAc
i) Xylene
FIGURE 3.18. The Fischer-Helferich method.
original reaction involves the condensation between silver salt of theophylline with acetobromoglucose in hot xylene, giving preferentially the N-7 regioisomer (Figure 3.18). The feasibility of this method is observed in the synthesis of adenosine and guanosine by condensation of tri-O-acetyl-α-D-ribofuranosyl chloride with the silver salt of 2,8-dichloroadenine to generate an intermediate which under the conditions described below can generate either adenosine or guanosine (Figure 3.19).32 The stereochemistry of this reaction can be predicted by applying the “trans rule” proposed by Tipson33 and extended by Baker. The rule establishes that the condensation between the purine or pyrimidine sal with the acyl-O-glycosyl halide will generate a nucleoside with C1-C2 trans configuration regardless of the initial configuration of C1-C2 of the sugar. The trans rule is demonstrated in the preparation of thymidine acetoglucopyranose and mannopyranose, where -OH at position 2 for the former is equatorial, and axial for the latter. By following the rule, the coupling reaction generates the β- and α-anomers, respectively, having both of them a trans disposition between substituents at positions 1 and 2 (Figure 3.20).
3.3.3 The Davol-Lowy Reaction 3.3.3.1
General Figure and Conditions
O
N
promoter +
PO
X
O N H
PO
X = Cl, Br
Promoter
Conditions
Hg(CN)2 Hg(CN)2
CH3 NO2 , reflux xilene
158
3. N-Glycosides NH2 NH2 N
N
AcO
Cl
O
i
Cl
Cl + Cl
N
N
N N AcO
Cl
N Ag H
N O
OAc OAc
OAc OAc ii,iii
NH2
N
N HO
ii,iv,v
N
N
O
O
N
HN
OH OH
H 2N
N
N HO
O
i) xylene. ii) MeONa/MeOH. iii) H2, Pd-C. iv) HNO2. v) NH3.
OH OH
FIGURE 3.19. Synthesis of adenosine and guanosine.
This method has been also considered a modified Fischer-Helferich procedure and involves the use of mercury chloride instead of silver salts. Under these conditions the useful intermediate chloropurine nucleoside has been prepared under mild conditions (Figure 3.21). The nature of the glycosyl halide is important for determine the regioselectivity of the glycosidic linkage. If the condensation reaction occurs between purines with acetobromoglucose the N-7 regioisomer is obtained preferentially. On the other hand, if acetoribosyl chloride is condensed with the same purine, the N-9 regioisomer is the major product observed (Figure 3.22). Another purine nucleoside prepared under these conditions is shown in Figure 3.23, consisting of the coupling reaction between the protected guanine with protected furanosyl chloride in nitromethane under refluxing conditions produced by the corresponding N-glycoside in 50% yield.34
3.3. General Methods
159
O AcO AcO AcO
HN
O OAc
Br
O
OAc OAc
AcO
O HN O
OAc
N
O
AcO
N H
OAc
AcO O
OAc
OAc OAc
O
AcO AcO
N
O
Br NH O
FIGURE 3.20. Tipson’s trans rule.
Cl N
N Cl
BzO
O
N
N
i
+
O
Cl N
N HgCl H
N
N BzO
OBz OBz
i) xylene
OBz OBz
FIGURE 3.21. The Davol-Lowy method.
3.3.4 Silyl Coupling Reaction 3.3.4.1
General Figure and Conditions O
promoter
N
+
PO
OAc
N
O
OTMS PO
O
160
3. N-Glycosides OAc OAc
OAc
O
AcO
OAc OAc
OAc
N
N N
N-7 regioisomer i,ii
N
OAc
N
N
N(CH3)2 N
O
N(CH3)2
Br
N HgCl H
N(CH3)2 BzO
O
N
N Cl
OBz OBz
N
N AcO
O
i) xylene. ii) MeONa/MeOH.
OAc OAc N-9 regioisomer
FIGURE 3.22. Preparation of N-7 and N-9 regioisomers.
Promoter
Conditions
TMS-OTf TMS-OTf SnCl4 HMDS-TMDS (MeSi)2 NAc CF3 (CF2 )3 SO3 K/HMDS-TMSCl HMDS/(NH4 )2 SO4
CH3 CN, 0◦ C→r.t PhNO2 ,127◦ C CH3 CN
Various types of silyl agents have been tested as either protecting groups and/or N-glycoside promoters. Among them trimethylsilyl chloride (TMS-Cl), bis(trimethylsilyl) acetamide, trimethylsilyltriflate, and hexamethyldisilasane are representative examples. De Clercq et al.35 prepared purine and pyrimidine α-D-lixofuranosylnucleosides employing HMDS, TMS, and TMSF as silyl coupling agents. Nucleoside α-D-lyxofuranosyl thymine was prepared by condensation between 1,2,3,5-
3.3. General Methods
161 O
N
O EtHN
NH
O Cl
O
N
NH
OBz
N H
OBz
N
N
i
+
EtHN
N
NHAc
O O
NHAc
OBz
OBz
i) Hg(CN)2, CH3NO2, reflux, 16 h.
FIGURE 3.23. Glycosidation reaction for preparation of guanine derivative.
tetra-O-acetyl-α-D-lyxose with thymine in the presence of HMDS-TMSCl mixture (Figure 3.24). Likewise cytidine has been synthesized in 95% through condensation of silyl cytidine obtained from cytosine with bis [trimethylsilyl] acetamide, and sugar derivative 2,3,5-tri-O-benzoylribose, as represented in Figure 3.25. O
O
HN O AcO
N H
OAc OAc O OAc
O
N OAc OAc O OAc
O i
AcHN
N
N
HN
N SiMe3 H
O
+
N
HN AcHN
N
N
AcHN
i) HMDS-TMSCl
OAc OAc O OAc
O
N
HN
N
N OAc OAc O OAc
FIGURE 3.24. Preparation of α-D-lyxofuranosyl thymine and guanine protected nucleosides.
162
3. N-Glycosides NH2 NHTMS
BzO
O
N i,ii
N +
TMSO
OH
N
HO
N
O O
OBz OBz
OH OH
i) (CH3Si)2NAc. ii) Ba(OH)2/MeOH.
FIGURE 3.25. Silyl mediated coupling reaction.
Hilbert and Johnson36 developed a procedure for preparing nucleosides employing a mixture of hexamethyldisilane (HMDS), trimethylsilane chloride, and potassium nonaflate. According to this procedure, 5-methoxyuridine was prepared by condensing 5-methoxyuracil, with 1-O-acetyl-2,3,5-tri-O-benzoyl-βD-ribofuranose (Figure 3.26). A widespread silyl-based methodology was developed by Vorbr¨uggen37 based on the use of persilylated purines or pyrimidines, which are condensed with peracylated sugars in the presence of Lewis acid catalysis. Usually silylation of the base is achieved with hexamethyldisilazane (HMDS) or N,Obis(trimethylsilyl)acetamide, the latter less difficult to remove during the workup process. Among the Lewis acids employed as catalysts, trimethylsilyl triflate (TMSOTf) has been the most suitable condensing agent for this reaction. AZT alkylthioanalogs have been synthesized under the method reported by Vorbr¨uggen. This condition requires hexamethyldisilane for activation of the anomeric center, and trimethylsilyltriflate as condensing agent (Figure 3.27). V¨orbruggen-type coupling reaction has been method of choice in the Nglycoside bond formation of various complex nucleosides such as octosyl acid A, tunicaminyl-uracil, sinefungin, and hikizimycin.Some of the general conditions O O
BzO OMe
HN
OMe
OAc
HN
O OBz
i,ii
O
N H
N
O
+
HO OBz
O OH
i) CF3(CF2)3SO3K/HMDS-TMSCl. ii) Ba(OH)2/MeOH.
FIGURE 3.26. Hilbert and Johnson approach.
OH
3.3. General Methods TMSO O R
R2S
O
O
OAc R
OTMS
HN
163
HN R
HN
i
N3
N H
R2S
N
R2S TMSO
ii
O
N H
i) HMDS/(NH4)2SO4. ii) TMSOTf/CH3CN.
N3
FIGURE 3.27. Vorbr¨uggen’s synthesis of AZT thioderivatives.
reported for the accomplishment of the mentioned synthesis are described in Figure 3.28.6a−b
3.3.5 Sulfur-mediated Reaction 3.3.5.1
General Figure and Conditions O
promoter
N
+
PO
SR
N
O
O
OTMS PO
R = Ph, (=O)Ph Promoter
Conditions
NIS-OTf TMS-OTf Br2
CH2 Cl2 DCE r.t. DMF
Derived from their extensive use in the preparation of O-glycosides, the sulfur glycosyl donors have become another standard procedure for N-glycosylations. The conditions reported for the coupling reactions involve the sulfur glycosyl donor, the silyl protected heterocycle acceptor, and usually N-iodosuccinimide, triflic acid as catalyst (Figure 3.29).38
3.3.6 Mitsunobu Reaction This reaction has been selected as another strategy for preparing N- and carboxyclic nucleosides. The mechanism involves a nucleophilic substitution displacement with inversion of the configuration between species bearing poor leaving groups with nucleophiles. The reaction mechanism involves the initial reaction
164
3. N-Glycosides OMe OTMS
Cbz-HN
SnCl4
OAc
O
+
O
N
OAc
AcO
N
74.5%
OTMS
OAc OAc
AcO OMe Cbz-HN O
O
OAc O
N
AcO OAc
O OAc
AcO
OMs
CO2Me
OBn O
MeO
NH
OTMS OAc
+
N
TMS-OTf, CH3CN 0oC to r.t.
N 91 %
O OAc
AcO
OTMS CO2Me
OMs
O
OBn O
MeO
N
O
NH O
AcO
OAc
FIGURE 3.28. V¨orbruggen-type coupling reactions.
of triphenylphosphine (Ph3 P) with diethylazodicarboxylate (DEAD) to produce a dipolar intermediate that will react with an alcohol to form an alcoxyphosphonium salt and diimide. Then the nucleophile will displace triphenylphospine oxide to give the substitution product. (Figure 3.30).39 This procedure was used successfully for preparing the N-glycoside shown in Figure 3.31 by reacting 2,3,4,6-tetraacetyl glucose with the heterocyclic base under the Mitsunobu conditions.40
3.3.7 Palladium-mediated Reaction Palladium catalysis is a well-established and versatile methodology for the preparation of nucleosides. Also known as the Heck reaction, it was developed initially
3.3. General Methods BnO
BnO
OTMS O
SPh
AcO
N
O
i
N
O
N
AcO
+
NH O
OTMS
OPiv
MeO
165
OPiv
MeO
i) NIS, TfOH, CH2 Cl2, −20o C to 0o C, 10 min, 85%
Ph O O
Ph N
OPiv
O
OTMS
O O OPiv
O
SPh
O
N3
N
+
i
N3
O N
O
N Ac
TMS
N NHAc
i) NIS, TfOH, CH2 Cl2, 1h, 95%
FIGURE 3.29. N-glycoside formation via sulfur glycosyl donor.
for C-C bond formation and consists in the coupling of an aryl halide with activated olefin in the presence of palladium (0) as catalyst (Figure 3.32).41 More recently, other palladium-mediated reaction have been developed with great potential for heterocycle coupling reaction with furanosides, to produce an interesting variety of nucleosides. The group of reactions includes the Suzuki X
EtO2C N N CO2 Et
Ph3 P HX
X +
PO
EtO2C X
PO
H N N PPh 3
EtO2 C
CO2 Et
H N N H
N
N H OPPh 3
OH X = CH2, O
X +
O
PPh3
PO
FIGURE 3.30. The Mitsunobu reaction for the construction of a glycosidic bond.
CO2Et
166
3. N-Glycosides OAc CH3 N
O
OAc
N
O
O
AcO AcO
O
CH3 O
OH N N Boc
i
N N Boc
N H AcO
N
O
i) DEAD, Ph3P, THF, −78oC, 61%
OAc
OAc OAc
FIGURE 3.31. The Mitsunobu reaction for preparation of N-glycosides.
(organoboranes),42 Stille (organostannanes),43 Negishi (zincated),44 Sonogashira (alkyne-CuI),45 Hiyama (organosilicon),46 and Tsuji-Trost47 (Figure 3.33). Early reports in the use of Heck-type reactions for the preparation of nucleosides were described by Bergstrom.48 More recently a comprehensive overview about palladium-mediated reactions for N -glycoside bond formation or modifications at the base or the sugar moieties were described. A general figure summarizing such possibilities is shown in Figure 3.34.49
3.3.8 Microbial/Enzymatic Approach The synthesis of nucleosides by enzymatic methods is another extended possibility, and for this purpose the enzyme nucleoside phosphorylase has been selected as one of the most appropriate one. Usually the conversion proceeds by the reversible formation of a purine or pyrimidine nucleoside and inorganic phosphate from ribose-1-phosphate (R-1-P) and a purine or pyrimidine base. The general approach consists of the reaction of R-1-P as the glycosyl donor, which is condensed with purine or pyrimidine analogs. Following this method any heterocycle recognized by this enzyme can be glycosilated (Figure 3.35). The enzyme synthetase phosphoribosyl pyrophosphate PRPP was used for nucleotide synthesis of UMP. The sequence involves the conversion of ribose-6-phosphate with PRPP synthetase to produce phosphoribosyl pyrophosphate which was condensed with orotate in the presence of O5P-pyrophosphorylase PdX
X
PdX
Pd
o
H 2C
CH2
FIGURE 3.32. The Heck reaction.
3.4. Oligonucleotide Synthesis
Br +
Ar
Ar
B(OH)2
167
Pd(0)
Ar
Ar
Suzuki reaction
R'
R
PdL4
+ OTf
R''
R'
R
SnR3
R'
Stille reaction
R Br + R2'
Pd(0)
Zn
R R'
Negishi reaction
R Br + R3'
Pd(0)
Si
R R'
Hiyama reaction
R
+
H
Pd(0)
R
R
CuI
R
X Sonogashira reaction
+
R
R
Nu
Pd(0)
X
Pd
R Nu
X
Tsuji-Trost reaction
FIGURE 3.33. Palladium-mediated coupling reactions.
to yield the nucleotide intermediate orotidine 5 -phosphate that, after descarboxylation produced by the action of O 5P-decarboxylase the nucleotide Uridine monophosphate (Figure 3.36).50
3.4 Oligonucleotide Synthesis Deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) are very important natural polymers responsible for the processing of the genetic information of all organisms.
168
3. N-Glycosides OP OAc
AcO
O
OP Heterocycle coupling "Pd"
Heck
Tsuji-Trost
O
O R
NH N
HO
"Pd"
O
various
O
N
HO
X
NH
X
Heck, Stille
OH OH
Negishi
OH OH Heterocycle modification
"Pd"
Tsuji-Trost "Pd"
Sonogashira
O
O NH NH HO
N
HO
O
N
O
X
X
Me Me
Sugar modification
R
FIGURE 3.34. Palladium-assisted modifications.
The basic repetitive unit known as nucleotide is composed by a nucleotide base, a sugar moiety, and a phosphate. The combinatorial pattern of the four different nucleosides constituted by the heterocyclic bases cytosine, thymine, guanine, and adenine are the base of the DNA structure. In RNA strands uracil replaces thymine and the furanoside is ribose instead of 2-deoxyribose. The phosphate group is attached at position 3 of one sugar unit and the 5 position of the next one, forming a 3 -5 elongation chain (Figure 3.37). Oligonucleotide synthesis does not involve N-glycoside bond formation, but it requires the design of nucleoside donors and nucleoside acceptors, following
3.4. Oligonucleotide Synthesis HO
HO
O B1
HO
O
i
OH X
O B2
i
O-PO32−
169
B2
OH X
OH X
X = H, OH
HO
O B1
ii
HO
OH X
O B2
OH X
i) nucleoside phosphorilase. ii) trasribosylase.
FIGURE 3.35. General figure for enzyme-mediated nucleoside synthesis.
the same principle that applies for glycoside coupling reactions where suitable protecting groups, glycosyl donors and acceptors are requested. Solid-phase procedures appear to be of great advantage for the coupling of nucleosides, and unlike for oligosaccharide solid-phase chemistry, the attachment positions are always the same (3 and 5 ). The sequence of reactions that occurs in oligonucleotide synthesis starts on the attachment of 3 -OH position of 5 -protected nucleoside to a resin. Next is deprotection of 5 -OH and subsequent attachment to a nucleoside donor, which contains a phosphate precursor, which in turn will be converted to a phosphate group. O O -O P O O−
NH
O ATP
O
AMP
OH OH OH
-O P O O−
PRPP synthetase
O O O O P O P O– O− O− OH OH
-O 2C
O NH
OH OH
NH O
O5P decarboxylase
O -O P O
O−
O
O5P pyrophosphorylase
O
O -O 2 C N -O P O O O−
N H
N O
OH OH UMP
FIGURE 3.36. Enzyme-catalyzed synthesis of nucleotide.
O
170
3. N-Glycosides NH2 N
N
N O
Adenine
N
O
NH2 N
Cytosine
O O
P
O−
N
O
O
O O N
NH
O O
P
O−
N
O
N
O
Guanine
NH2
O NH
Thymine
O O
P
O−
N
O
O
O O O
P
O−
O
FIGURE 3.37. Fragment of a single strand of DNA structure.
There are mainly two procedures for oligonucleotide synthesis: the phosphoramidite and the phosphonate methods.15,51
3.4.1 Phosphoramidite Method This methodology involves the use of the air-sensitive reagent 2-cyanoethyl tetraisopropylphosphorodiamidite {[(CH3 )2 CH]2 N}POCH2 CH2 CN or 2cyanoethyl N,N-diisopropylchlorophosphoramidite (iPr)2 NP(Cl)OCH2 CH2 CN for activation of nucleoside donor.52 This intermediate can be obtained by treatment of PCl3 with 2 eq of diisopropylamine, and 1 eq of cianoethylethanol. The general phosphoramidite approach is outlined in Figure 3.38 and begins with
3.4. Oligonucleotide Synthesis
171
HO2CCH2CH2CO2H
(EtO)2Si(CH2)NH2
(CH2)3NH2
CO2H
(CH2)3NHCOCH2CH2CO2H
B1
B1
OTr
O
OTr
O
CO2H
OH
O
O
OH
B2
B1 i
+
O
OTr
O
O
B2
O
OTr
O
O P
N
CN
O
O P B1
CN
O
O
O
iii
ii
O O B3 B2
OH
O
OTr
O
B3
OTr
O
O O
N P
P B1
O
O
O
O O
CN
CN
B2
O
O
P O
ii
O O
P O
B1
O
O
O
O O
FIGURE 3.38. The phosphoramidite oligonucleotide strategy.
CN
CN
172
3. N-Glycosides B3
OH
O
FIGURE 3.38. (continued)
O B2
O
O
P
O
OH
iii,iv
O P B1
O
O
O
OH
O O i) Cl3CCOOH. ii) tetrazol. iii) Cl3CCOOH. iv) a) I2/H2O. b) NH4OH
a nucleoside previously protected at the 5 -OH position with 4,4 -dimethoxytrityl group (Tr-), also attached to a silica support. The trityl group is then removed from the 5-OH position and allowed to react with a nucleoside donor protected at position 5-OH with Trityl group and activated at position 3 with 2-cyanoethyl diisopropylphophoroamidite. The coupling reaction being the critical step is catalyzed by tetrazol, and the process is repeated for the installation of subsequent nucleoside unit. Once the oligonucleotide chain is formed, the phosphoramidite group is transformed to phosphate with I2 -H2 O and released from resin with ammonia.
3.4.2 Phosphonate Method In this method the nucleoside donor functions as a phosphotriester sugar derivative that reacts with the nucleoside acceptor at the 5-OH position, which is available for linkage. An advantage of this method is the possibility of introducing substituents to the phosphate position giving place to the preparation of modified oligonucleotides (Figure 3.39).
3.4.3 Modified Oligonucleotides Modified oligonucleotides are another important application of solid-phase oligonucleotide synthesis. It is known that natural oligonucleotides used as therapeutic strategy against viral infections as antisense for targeting RNA sequences may undergo enzymatic hydrolysis by endonucleases. Series of modified oligonucleotides carrying the modification either on the base, sugar, or phosphate moiety
3.4. Oligonucleotide Synthesis B2
B1
B2
OH
O
OTr
O
O
OTr
O
173
O
P
H
+
B1
O
O
P
O
O
H
O
O
B2 TrO
O
O
O
B1 O
O
O P
O
H
FIGURE 3.39. The phosphonate method.
provides ideally endonuclease resistance as well as high affinity for complementary RNA sequences. Phosphodiester bond is the primary target for endonuclease breakage. Therefore, the effort has been focused mainly on the modification of this segment of the chain. As a result of this, a first generation of modified phosphorous oligonucleotides such as phosphothioates, methylphosphonates, phosphoramidates, phosphotriesters, and phosphodithioates was synthesized. Although these phosphorous derivatives showed increased resistance to endonuclease activity, the affinity for complementary sequences was decreased.53-55 For instance, the
RO
B2
O
X
W
Y
Z
W
O
Y
Z
O
-P(O)S-
O
CH2
O
-P(O)CH3-
O
CH2
O
CH2
O
B1
X
-P(O)NHR-
O
-P(O)OR-
O
CH2
NH
-P(O)O-
O
CH2
OR
FIGURE 3.40. Modified oligonucleotides.
174
3. N-Glycosides O NH
O NH N
TrO
N
TrO
O
O
O O
NH O
O
N
SCN
O
i
NH
HN S
O
+
N
HN H2N
O
O
N3 N3
O
O
NH
NH O
N
TrO
O
N
TrO
O
O
O
O NH
HN
NH2
S O
N
HN
NH
HN ii,iii
N
HN
O
O
O
O
O NH
HN
NH2
S N
HN
NH
HN O
N
HN
N3
O
O
O
N3
i) DMF. ii) H2S. iii) 3´-azido-5´-isothiocyano-3´,5´-deoxythymidine. iv) a) TFA. b) H2NC(=NH)SO2H. c) NH4OH.
FIGURE 3.41. Preparation of guanidinium oligonucleotides.
synthesis of the antisense oligomer phosphorothioate analog of a 28-nucleotide homo-oligodeoxycytidine (S-dC28 ) was achieved, and tested as a potent inhibitor of HIV in vitro, showing significant inhibition of reverse transcriptase activity and syncytium formation between HIV-1 producing cells and CD4+ .56
3.4. Oligonucleotide Synthesis
175
A second generation proposed the replacement of phosphodiester group by a bioisoster such as amides, urea, and carbamate (Figure 3.40). In general the observations reveal better enzymatic hydrolysis resistances, but again poor affinity toward RNA complementary sequences. Alternatively, Dempcy et al.57 reported the synthesis of modified guanidinetimidine oligonucleotide following the procedure depicted in Figure 3.41. The reactions involved are the condensation between 3 -amino-5 -O-trityl-3 deoxythymidine and 3 -azido-5 -isothiocyano-3 ,5 -deoxythymidine, to generate 5 →3 thiourea-nucleoside dimer. Reduction followed by coupling reaction of dimer with the later nucleoside produced chain elongation reaction. Guanidine conversion was done with aminoiminosulfonic acid and ammonium hydroxide, affording guanidinium thymidyl pentamer. The unit assemble for oligoribonucleotide synthesis is to some extent similar to deoxyribonucleotides synthesis. However, an additional consideration should be taken into account, which is the suitable protection of position 2-OH of ribose. The use of the silyl protecting group is one of the best choices so far reported, in particular the hindered tert-butyldimethyl silyl (TBDS) group. The protection of tritylribonucleoside produced a mixture of isomers, being the 2-OH silyl derivative
TrO TrO
O
B
Si
B
O
TrO
O
B
Cl +
HO
O
HO
OH
Si
O Si
i
50-90 %
i
TrO
B O
NCH2CH2C
O
O P
Si
Ni-Pr
FIGURE 3.42. Ribose protecting groups for oligoribonucleotide synthesis.
OH
176
HO
3. N-Glycosides
O
B i
i
B
O
O
i
Pr2Si
ii
O
B
Pr2Si O
O i Pr Si 2
OH OH
O
i
O
OH
Pr2Si
O
O
OPh O
B = heterocyclic base HO
B O
iii,iv
OH i) (iPr)2SiCl O, Py. ii) ClC(S)OPh, DMAP, MeCN. iii) Bu3SnH, AlBN, PhCH3. 2 iv) Bu4NF, THF.
FIGURE 3.43. The Barton-McCombie procedure for the preparation of 2 deoxynucleosides.
generated in between 50–90% yield. Final removal of this protecting group is usually achieved with 1 M tetrabutylammonium fluoride in THF (Figure 3.42). Some other choices for 2-OH protection are tertahydropyran-1-il, 4methoxytetrahydropyran-4-il, and modified ketal of 1-(2-fluorophenyl)-4methoxypiperidin-4-il (Fpmp). However, it has been found that acid conditions for removal of these protecting groups are not compatible with the trityl protecting group. Simultaneous protection of positions 3 and 5 can be achieved by using the silyl protecting group tetraisopropyldisiloxychloride (TIPS-Cl) in pyridine. This type of protection has been useful in the conversion of adenosine to 2 -deoxyadenosine under the conditions reported by Barton and McCombie58 (Figure 3.43).
References 1. S. Nishimura, Progress Research Molecular Biology 12, 49 (1972). 2. T. Kondo, T. Ohgi, and T. Goto, Agric. Biol. Chem. 41, 1501 (1977). 3. H. Akimoto, E. Imayima, T. Hitaka, H. Nomura, and S. Nishimura, J. Chem Soc Perkin Trans. I 1637 (1988). 4. C.J. Barnett and L.M. Grubb, Tetrahedron 56, 9221 (2000). 5. T. Itaya, Chem. Pharm. Bull. 38, 2656 (1990). 6. (a) S. Knapp, Chem. Rev. 95, 1859 (1995). (b) M.T. Migawa, L.M. Risen, R.H. Griffey, and E.E. Swayze Org. Lett. 7, 3429 (2005). 7. N. Chida, K. Koizumi, Y. Kitada, C. Yokohama, and S. Ogawa, J. Chem. Soc. Chem. Comm. 11 (1994). 8. M.P. Maguire, P.L. Feldman, and H. Rapoport, J. Org. Chem. 55, 948 (1990). 9. L. Kalvoda, M. Prystas, and F. Sorm, Collect. Czech. Chem. Commun. 41, 788 (1976). 10. A.G. Myers, D.Y. Gin, and D.H. Rogers, J. Am. Chem. Soc. 116, 4697 (1994).
References
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11. H. Hahn, H. Heitsch, R. Rathmann, G. Zimmermann, C. Bormann, H. Zahner, and W. Konig, Liebigs Ann. Chem. 803 (1987). 12. S. Hanessian, J. Kloss, and T. Sugawara, J. Am. Chem. Soc. 108, 2758 (1986). 13. N. Ikemoto and S.L. Schreiber, J. Am. Chem. Soc. 114, 2524 (1992). 14. S. Knapp and S.R. Nandan, J. Org. Chem. 59, 281 (1994). 15. G.M. Blackburn and M. Gait, Nucleic Acids in Chemistry and Biology, IRL 77 (1990). 16. C.-H. Wong, S.T. Chen, W.J. Hennen, J.A. Bibbs, Y-F. Wang, J.L-C. Liu, M.W. Pantoliano, M. Whitlo, and P.N. Bryan, J. Am. Chem. Soc. 112, 945 (1990). 17. A. De la Cruz, J. Elguero, V. Gotor, P. Goya, A. Mart´ınez, and F. Moris, Synth. Commun. 21, 1477 (1991). V. Gotor, and F. Mor´ıs, Synthesis 626 (1992). 18. S. Ozaki, K. Yamashita, T. Konishi, T. Maekawa, M. Eshima, A. Uemura, and L. Ling, Nucleosides Nucleotides 14, 401 (1995). 19. H.K. Singh, G.L. Cote, and R.S. Sikirski, Tetrahedron Lett. 34, 5201 (1993). 20. D.L. Damkjaer, M. Petersen, and J. Wengel, Nucleosides Nucleotides 13, 1801 (1994). 21. Kawana et al., Chem Lett. 1541 (1981). 22. S. Kozai, T. Fuzikawa, K. Harumoto, T. Maruyama Nucleosides, Nucleotides & Nucleic Acids 22, 779 (2003). 23. V. Serebryany and L. Beigelman, Tetrahedron Lett. 43, 1983 (2002). 24. Taniguchi et al., Angew. Chem. Int. Ed. 37, 1136 (1988). 25. M.J. Robins, V. Samano, and M.D. Johnson, J. Org. Chem. 55, 410 (1990). 26. T. Kondo, T. Ohgi, and T. Goto, Chemistry Lett. 419 (1983). 27. B.K. Battacharya, T.S. Rao, and G.R. Revankar, J. Chem. Soc. 1543 (1995). 28. F. Seela, H. Steker,. H. Driller, and U. Bindig, Liebigs Ann. Chem.15 (1987). 29. F. Seela and A. Kehne, Liebigs Ann. Chem. 876 (1983). 30. Z. Kazimierczuk, H.B. Cottam, G.R. Revankar, and R.K. Robins, J. Am. Chem. Soc. 106, 6379 (1984). 31. E. Edstrom and Y. Wei, J. Org. Chem. 60, 5069 (1995). 32. J. Davoll, B. Lythgoe, and A.R. Todd, J. Chem. Soc. 967 (1948). 33. R. S. Tipson, J. Biol. Chem. 55, 130 (1939). 34. K.H. Jung, and R.R. Schmidt, Liebigs, Ann., Chem. 1013 (1988). 35. E. De Clercq, G. Gosselin, M.C. Bergogne, J. De Ruddes, and J.L. Imbach, J. Med. Chem. 30, 982 (1987). 36. G.E. Hilbert and T.B. Johnson, J. Am. Chem. Soc 52, 4489 (1930). 37. (a) H. Vorbr¨uggen, K. Krolikiewicz and B. Bennua, Chem. Ber. 114, 1234 (1981). (b) H. Vorbr¨uggen and G. H¨ofle, Chem. Ber. 114, 1256 (1981). 38. S. Maier, R. Preuss, and R.R. Schmidt, Liebigs Ann. Chem. 483 (1990). 39. O. Mitsunobu, Synthesis 1 (1981). 40. Marminon et al., J. Med. Chem. 46, 609 (2003). 41. R.F. Heck, Organic Rect. 27, 345 (1982). 42. N. Miyaura and A. Suzuki, Chem. Rev. 95, 2457 (1995). 43. W.J. Scott, G.T. Crisp, and J.K. Stille, J. Am. Chem. Soc. 106, 4630 (1984). 44. E.-I. Negishi, J. Organomet. Chem 653, 1 (2002). 45. K. Sonogashira, In Comprehensive Organic Chemistry, Trost, B. M., Fleming, I., Eds.; Pergamon Press: N.Y. 3, 521 (1991). 46. Y. Hatanaka and T. Hiyama, Synlett 845 (1991). 47. (a) B.M. Trost, and D.L. Van Vranken, Chem Rev. 96, 395 (1996). (b) Tsuji, J., Yamakawa, T., Tetrahedron Lett. 20, 613 (1979).
178
3. N-Glycosides
48. J.L. Ruth and D.E. Bergstrom, J. Org. Chem. 43, 2870 (1978). D.E. Bergstrom and J.L. Ruth, J. Am. Chem. Soc. 98, 1587 (1976). D.E. Bergstrom, J.L. Ruth, and P. Warwick, J. Org. Chem. 46, 1432 (1981). 49. L.A. Agrofolio, I. Gillaizeau, and Y. Saito, Chem. Rev. 103, 1877 (2003). 50. A. Gross, O. Abril, J.M. Lewis, S. Geresh, and G.M. Whitesides, J. Am. Chem. Soc. 105, 7428 (1983). 51. F. Eckstein, Oligonucleotides and Analog:- a Practical Approach, IRL (1991). 52. N.-S Li and J.A. Piccirilli, J. Org. Chem. 69, 4751 (2004). 53. A. De Mesmaeker, R. Haner, P. Martin, and H.E. Moser, Acc. Chem. Res. 28, 366 (1995). 54. M.J. Damha, P.A. Giannaris, P.A. Marfey, and L.S. Reid, Tetrahedon Lett. 32, 2573 (1991). 55. M. Sekine, H. Tsuruoka, S. Iimura, H. Kusuoku, and T. Wada,. J. Org. Chem. 61, 4087 (1996). 56. H. Mitsuya, R. Yarchoan, and S. Broder, Science 249, 1533 (1990). 57. R. Dempcy, K.A. Browne, and T.C. Bruice, J. Am. Chem. Soc. 117, 6140 (1995). 58. D.H.R. Barton and S.W. McCombie, J. Chem. Soc. Perkin Trans 1 1574 (1975).
4 Nucleoside Mimetics
Modified nucleosides are useful therapeutic agents being currently used as antitumor, antiviral, and antibiotic agents. Despite the fact that a significant variety of modified nucleosides displays potent and selective action against the mentioned diseases, the challenge still attracts full attention since most of them do not discriminate between normal and tumor cell and in viral infection resistant strains usually appear during the course of the treatment. Synthetic acyclic, carbocyclic, C-nucleosides, and modified N-nucleosides have shown remarkable action against AIDS, hepatitis, and Herpes infections, among others. Some of the nucleosides used as approved drugs are acyclovir, carbovir being the treatment of choice against Herpes, AZT, ddI, ddC, ddG, Abacavir, which in combination with protease inhibitors is indicated in the treatment against HIV, and C-nucleoside Ribavirin in the treatment against hepatitis.1,2 Representative examples of chemotherapeutic agents modified at the heterocyclic base, the sugar fragment, L and Cnucleosides, carbocyclic and acyclic nucleosides are depicted in Figure 4.1. A significant number of synthetically modified nucleosides were designed as antiretroviral drugs in the therapy of human immunodeficiency virus (HIV) infection. During retroviral infection, the viral RNA is used as a template for proviral DNA synthesis, a process mediated by the viral DNA polymerase better known as reverse transcriptase. Thus, the process involves the initial formation of an RNADNA hybrid, which is then degraded by an RNAse to release the DNA strand that will be the template for the synthesis of the doublestranded viral DNA, a process also catalyzed by the reverse transcriptase.3 The proposed mechanism of action of modified agents such as AZT during viral infection involves the interruption of the viral replication process that occurs between the virus and host, particularly the replication inhibition inside T cells, monocytes, and macrophages. When the modified nucleoside is introduced into the cell, a sequential 5 phosphorylation process mediated by kinases occurs on the furanoside ring, which is subsequently incorporated into the DNA as triphosphate (Figure 4.2).
179
180
4. Nucleoside Mimetics O
O F N
NH
NH
N N
N
N
NH2
HO
O
HO O
OH
O
OH
OH 2-Deoxyfluorouridine
8-Azainosine
O O
O
NH NH N
NH
O N
O
N
HO O
HO
HO O
N3
N3
AZT
O
F
FIGURE 4.1. Representative synthetically modified nucleosides.
An important collection of active nucleosides mimetics has been synthesized and classified for better understanding as follows:4 Modified Nnucleosides Lnucleosides (Disomers) Cnucleosides Carbocyclic nucleosides Acyclic nucleosides Thionucleosides
4.1 Modified Nucleosides A broad number of modified nucleosides have been developed and tested on clinical trials, some being highly promising. The chemical manipulations have been made at the heterocyclic base, the sugar of both. Some representative examples of chemical modifications leading to key intermediates or active nucleosides are
O
4.1. Modified Nucleosides NH2
181
NH2 N
N N
N
N
O
NH2
N
HO
HO
O
S O
HN O Thiazolidinone
DAPD
NH2
O
N
NH N
NH2
N
O
N O
N
HO
HO
HO O
O
O
O
O NH2 S
HN
NH
N
O HO
HO
O
O OH OH
OH
OH Pseudourdine
Tiazofurin
FIGURE 4.1. (Continued)
4.1.1 Heterocycle Modifications 4.1.1.1
C-5 Substituted Pyrimidines
Several nucleoside analogs bearing modifications at the 5-position have been found to be active as antiviral and anticancer drugs. Examples of this are BVDU, IDU, and FIAU (Figure 4.3) 5
O
182
4. Nucleoside Mimetics O NH2 H3C
F
NH N N N
O
O HO
HO O
F
O S
OH L-FMAU
L-FTC
NH2 N N
O N
N
N
NH
N
N
HO
O
N
N
HO O
ddA
ddI
O
ddG
O
N
NH2
HO
HN
N
NH N
NH2
N
HO
O
N
NH
N N
N
N
NH2
N
HO
N
N
H2N HO
OH Carbovir
OH Abacavir
Neplanocin A
O N N HO
O N
NH N
NH2
N HO
O
O
HO DHPG
Aciclovir
FIGURE 4.1. (Continued)
NH N
NH2
4.1. Modified Nucleosides O
183
O NH
N
NH O
HO
N
i
P
O
O
ii
O
O
N3
N3 O O NH NH N N
P
P
O
O
P
P
P
O
O
ii
O
O N3
N3 i) Timidinkinase. ii) Timidilatokinase. iii) Nucleosidediphosphatekinase.
FIGURE 4.2. Phosphorylation of AZT.
Palladium-mediated transformations is a suitable strategy for introducing substituents at C-5. Some of the reactions implemented for this purposes are the Sonogashira,6,7 Stille,8,9 Heck,10 and Hiyama11 (Figure 4.4). 4.1.1.2
C-6 Substituted Pyrimidines
By following palladium-mediated substitutions, a more limited number of C-6 substituted pyrimidines have been described in comparison with C-5. For instance, applying the Stille reaction allows one to prepare C-6 substituted aryl, vinyl, alkynyl derivatives (Figure 4.5). 12 O
O
O
I
Br
HO
N O
I
NH
NH O
HO
N O
NH O
HO
N
O
O F
OH BVDU
OH
OH IDU
FIGURE 4.3. Active C5-substituted pyrimidines.
FIAU
184
4. Nucleoside Mimetics O
O
R
TfO
NH
NH H N
AcO
R AcO
O
O
i
N
O
O
OAc OAc
OAc OAc
i) Pd(PPh3)4, 10%, CuI, 20%, Et3N 1.2 eq./DMF.
O
O
R
I
NH
NH H N
HO
R HO
O
O
i
N
O
O
OH
OH i) Pd(PPh3)4, CuI, 20%, iPrEtN 40-60%.
O
O I
CO2R
NH HO
N
HO
O
O
RO2C
i
OH
NH N
O
O
OH
i) Pd(OAc)2, PPh3, Et3N, dioxan, 40%.
FIGURE 4.4. Palladium-mediated substitutions at C-5 pyrimidine position.
4.1.1.3
Purine Formation
The conventional methods of preparation of C-C purines are based on heterocyclization.13,14 The classical procedures involve.
4.1. Modified Nucleosides
N
O
O
i
N
MOMO
O
O
G=
SnBu3
N
O
ii
MOMO
H Ph SiMe3
O
O
G
O
O
O
O
HN
HN
HN
MOMO
O
O
O
185
O
CH 2CH=CMe2
CH=C=CH2
N SEM
i) LDA, then Bu3SnCl, 98%, G-X (Pd), CuI, DMF, 60-90%.
FIGURE 4.5. Palladium-mediated substitution of 6-C substituted pyrimidines.
1. 2-C-Cpurines cyclization of 4-aminoimidazole-5-carboxamides or nitriles with carboxylic acid equivalents. 2. 8-C-Cpurines from 5,6-diaminopyrimidines and carboxylic acid derivatives; and for 6-C-C-purines from 4-alkyl or 4-aryl-substituted 5,6-diaminopyrimidines (Figure 4.6).15 Other explored methods involves radical16,17 or nucleophilic substitution,18 sulfur extrusion,19 and Wittig-type reactions.20,21 Despite their usefulness, other methods based on the use of organometallic complex are getting particular significance especially in the synthesis of substituted purines (Figure 4.7).15 Usually the cross-coupling reactions involving organometallic compounds include organolithium,22 magnesium,23 aluminum,24 cuprates,25 zinc,26 stannanes,27 and boron28 reagents, in the presence of palladium catalyst, and the purine base bearing a good leaving group is usually halides or tosyl (Figure 4.8). Deazapurines are pyrrolo[2,3]pyrimidines of natural or synthetic source with significant antitumor, antiviral, and antibacterial activities. Some compounds included in this class are tubercidin, toyocamycin, sangivamycin, and the hypermodified nucleoside queuosine. A flexible route for the preparation of pyrrolo[2,3]pyrimidines (7-deazapurines) has been developed, consisting of the condensation of protected uracil with ethyl N-(p-nitrophenethyl)glycinate and subsequent treatment with acetic anhydride and amine base with heating to afford 5(-acetyloxy)pyrrolo[2,3-d]pyrimidine 2,4-dione in 74% yield (Figure 4.9).29
4.1.2 Sugar Modifications 4.1.2.1
2 3 -Dideoxysugars
A significant number of saturated and unsaturated dideoxysugars have been synthesized and tested as antiviral or anticancer drugs. Remarkably, ddI and ddC are
186
4. Nucleoside Mimetics Y
Y N
N
X R
N
N
HN
X
N
N
X
N
Z
R N
NH2
N X
N
YCOX'
NH Z
R
X
+
NH2
N X
N
RCOX'
Y N
N
+
Z
Y
X
RCOX'
N
H2 N
Z
N
+
N Z
X
N
NH Z
R = C-substituents X, Y, Z = other substituents
FIGURE 4.6. Conventional methods of preparation of C-C purines.
approved drugs for the treatment of AIDS,3 and others such as d4T being currently under clinical studies (Figure 4.10).30,31 A method for preparing ddC was described involving bromoacetylation with HBr in acetic acid of N4-acetylcytidine followed by reductive elimination with zinc-cooper couple in acetic acid to provide the corresponding 2 3 -unsaturated derivative. Final hydrogenation over 10% palladium on charcoal gave ddC in 95% accompanied by some N-C cleavage in 5% (Figure 4.11).32 Similar reaction conditions were used for preparing 2 3 -dideoxyadenosine in 81% yield from adenosine.33 The design and synthesis of potent inhibitors for Human Hepatitis B Virus (HBV) 2 ,3 -dideoxy-2 3 -didehydro-β-L-cytidine (β-L-d4C) and 2 ,3 -dideoxy2 3 -didehydro-β-L-5-fluorocytidine (β-L-Fd4C) nucleosides were carried out according to the pathway shown in Figure 4.12.34 The key starting material 3 ,5 dibenzoyl-2 -deoxy-β-L-uridine was submitted to transglycosilation reaction with silylated 5-fluorouracil using TMSOTf as catalyst, affording an anomeric mixture separated by chromatography. After benzoyl deprotection, the anomeric nucleosides were treated with mesyl chloride followed by base to form cyclic ethers.
4.1. Modified Nucleosides Y
Y R-M Pd(Ni) cat.
N
N N
X
N Z
R
N
LG
N
Y
N Z
X
N
Y
N
N Z
N
N
Y X
N Z
Y R-M Pd(Ni) cat.
N
N
N
N
Y X
N Z
R R-M Pd(Ni) cat.
N
N
N
N
X GL
187
R X
N
N Z
LG = Cl, Br, I, OTs R = alkyl, alkenyl, alkynyl, aryl, hetaryl M = MgBr, AlR 2, (Cu), ZnCl, SnR'3, B(OH)2 X, Y, Z = diverse substituents
FIGURE 4.7. General figure between purines and organometallic compounds.
Further transformation at the pyrimidine ring was followed by potassium tertbutoxide treatment to furnish β-L-d4C and β-L-Fd4C. Other methods designed for the preparation of 2 3 -unsaturated and saturated deoxyfuranosides are based on (a) the Corey-Winter reaction involving cyclic thionocarbonate,,35,37 (b) the Eastwood olefination process in which a fivemembered cyclic orthoformate suffer a fragmentation to give in the presence of acetic anhydride the desired olefin (successfully applied in the preparation of ddU),38,39 and (c) the Barton deoxygenation involving the cyclic thionocarbonate or the bisxantate, and then treated with tributyltin hydride,40,41 or alternatively diphenylsilane42 (Figure 4.13). The synthesis of modified nucleosides from natural nucleosides is another useful alternative for preparing pharmaceutically active dideoxy nucleosides.The potent antiviral inhibitors ddC, ddG, d4C, and d4G have been obtained from the corresponding protected natural nucleosides, as shown in Figure 4.14.43 The chemoenzymatic approach has been also explored for the synthesis of 2 ,3 dideoxynucleosides. Such is the case of the antiviral 2 ,3 -dideoxyguanosine, which was synthesized from guanosine in 40% overall yield using as a key step the commercially available mammalian adenosine deaminase (ADA) (Figure 4.15).44
188
4. Nucleoside Mimetics R' I
R
Li N
N
i
N
N
N THP
N
ii
OH N
N
N THP
N
N THP
N
i) BuLi, –130 oC. ii) RCOR'.
I
ZnI N
N
i
N
N
N Y
N
R ii
N
N
N Y
N
N Y
N
R = alkenyl, aryl Y = protected sugar i) Zn, THF. ii) R-X, Pd. cat.
Cl
Cl
Cl N
N
i
N Y
N
N
N Bu3Sn
ii
N Y
N
N
N R
N Y
N
i) a) LMPT. b) Bu3SnCl. ii) R-X, Pd, cat..
FIGURE 4.8. Cross-coupling reactions for purine modification. O OAc
CO2Na
O
MOM MOM
N
i,ii
HN
N
+
N BOM
O O
Cl
N BOM
PNPE R = PNPE
iii R=H i) EtOH/H2O, ∆. ii) Ac2O, n-Pr3N, 100 C. iii) DBU, CH3CN, 25 C 81% o
o
FIGURE 4.9. Synthesis of 7-deazapurine analogs.
N R
4.1. Modified Nucleosides O
NH2
N
NH
N
HO
O
N
N
O
189
N
HO
NH O
ddI
O
N
HO
O
O
ddC
d4T
FIGURE 4.10. Anti-AIDS 2 3 -dideoxy nucleosides.
A strategy for preparing D- and L-2 -fluoro-2 3 -unsaturated nucleosides has been described and their anti-HIV activity evaluated. This approach requires 1acetyl-5-O-benzoyl-2,3-dideoxy-3,3-difluoro–D-ribofuranose as key starting material, which was condensed under V¨orbruggen’s conditions with purines and pyrimidines to provide the corresponding nucleosides. The resulting nucleosides were subjected to β-elimination to generate the fluoro unsaturated nucleosides (Figure 4.16).45
HO
O
HO
NHAc
NHAc
NHAc
N
N
N
N
RO
i
O
OH
O
AcO
N
RO
O
O
+
Br
Br
N
O
OAc
R = Me2C(OAc)CO
NHAc
NH 2
N ii
RO
O
N
N O
iii,iv
HO
O
ddC i) Me2C(OAc)COBr. ii) Zn-Cu/AcOH. iii) H 2, 10% Pd-C. iv) Triton B.
FIGURE 4.11. Synthesis of anti-AIDS ddC.
N
O
190
4. Nucleoside Mimetics O
F
F
NH
NH
N O
N
BzO
O
OSiMe3
N
O
N
BzO
OSiMe3
O
O
i
OBz
OBz O
O R
N
R
NH
NH
BzO
O
R
ii
O
N
HO
NH O
O
O
N
iii,iv
O
O O
OH
R=H R=F
OBz
NH2
NH 2 R
R
N
N vii
v,vi
N O
O
N HO
O
O
O i) CF 3SO3 SiMe3 , CH3 CN. ii) NH 3 /MeOH. iii) MsCl, Py. iv) 1N NaOH, EtOH/H2 O. v) 1,2,4-triazole, p-ClC6 H 4 OPOCl2 , Py. vi) NH 4OH, dioxane. vii) t-BuOK, DMSO.
FIGURE 4.12. Synthesis of anti-hepatitis B virus β-L-d4C and β-L-Fd4C.
4.1.2.2
2 Deoxynucleosides
The Barton deoxygenation provides another useful method for preparing 2 - and 3 -deoxynucleosides (obtained as a mixture) and involves as a key step the hydride reduction of the cyclic thionocarbonate with tributyltin hydride.42 On the other hand, 2 -monotosylate nucleoside, when treated with excess of lithium triethylborohydride, produces the 2 -deoxy-3 β-hydroxy nucleoside in high yield (Figure 4.17).46 2 -deoxynucleosides have been obtained from starting materials of different composition such as α,β-unsaturated aldehydes47 chiral epoxy alcohols,48 butenolides,49,50 and polyfunctionalized acetals, among others.51
4.1. Modified Nucleosides FIGURE 4.13. Alternative procedures for preparing 2 3 -unsaturated nucleosides.
B
HO
O
B
HO
O
191
O
O S
i) P(OR)3 Corey-Winter reaction
HO
B
O
O
i
AcO
O
B
O OMe
i) Ac2O Eastwood olefination
RO
O
B i
O
MeS
O
B
SMe
O
S
RO
S
i) Bu3SnH or Ph2SiH2 Barton Deoxygenation
The remarkable 2 -deoxynucleoside AZT widely prescribed as an anti-AIDS drug was originally prepared from thymidine by Horwitz and coworkers,52 and since then, several other syntheses have been developed, some of them starting with either a nucleoside or a sugar derivative,5356 and others relaying on the use of noncarbohydrate starting materials.56,57 The procedure developed by Chu et al.50 consisted of the use of mannitol as staring material, which was subsequently transformed to provide the protected key intermediate 3 azide-2 deoxyribofuranose. The next step involved the coupling reaction with silylated thymine under V¨orbruggen’s conditions to produce an anomeric mixture of nucleosides in 66%. Final desilylation and separation by chromatography column provided AZT in overall yield of 25% from the furanoside intermediate (Figure 4.18).
192
RO
4. Nucleoside Mimetics
B
O
RO i
B=
HO
OH
O
i-PrOCHN
N
iii
RO
O
B
RO
O
B
RO v
iv
O
O HO
N
HN
N N
O
O
NH2
N
d4C
B
vi
NH2
O
O
O S
HO
N
N
O
ii
O
N
HN
N
O
OCSCH3
H3CSCO
O
NHAc
B
O
N
HO O
d2C
N
N
H2N
N
HN H2N
N
N HO
O
d4G
O
d2G
i) NaOH, CS2/CH3I. ii) (Im)2C=S. iii) Bu3SnH. iv) (EtO)3P. v) H2, Pd-C. vi) NH3/MeOH.
FIGURE 4.14. Antiviral modified nucleosides from natural sources.
Another possibility was described by Hager and Liotta involving the coupling reaction between the azido diol intermediate and silylated thymine under V¨orbruggen conditions to yield a diastereomeric mixture of azido diol nucleoside. Finally, when exposed to concentrated acidic conditions, the open form is converted into the βanomer of AZT in 67% yield (Figure 4.19).57 Transglycosidic reaction mediated by a deoxyribosyl transferase obtained from E.coli has been used in the synthesis of 3 -azido-2 ,3 -dideoxyguanosine. The enzymatic reaction occurs between AZT, which acts as glycosyl donor, with substituted 2-amino-6-purines to generate the desired purine nucleoside and thymine as byproduct (Figure 4.20).58 4.1.2.3
3 -Deoxynucleosides
These deoxynucleosides may be readily prepared from 3 -O-tosylate via a [1,2]hydride shift from C3 to C2 position with accompanying inversion of the C2 center
4.1. Modified Nucleosides Cl
O N
N HO
N
NH N
N
NH2
N N
HO O
O
OH
193
OH
OH
OH
O N
N HO
NH N
NH2
O
i) adnosine deaminase, phosphate buffer, pH 6.5.
FIGURE 4.15. Chemoenzymatic synthesis of 2 ,3 -dideoxyguanosine.
affording a 3 -ketone that was stereoselectively reduced by the hydride to produce 3 -deoxynucleoside (Figure 4.21).46,2 Also, 3 -deoxyguanosine was synthesized by an enzymatic transglycosylation of 2,6-diaminopurine using 3 -deoxycytidine as a donor of the sugar moiety. The diaminopurine nucleoside was transformed to 3 -deoxyguanosine by the action of adenosine deaminase (Figure 4.22).59 Lodenosine [9-(2,3-dideoxy-2-fluoro-β-D-threo-pentofuranosyl)] adenine (FddA) is a reverse transcriptase inhibitor with activity against HIV. This purine analog was evaluated as one of the most selective inhibitors in a series of 2 3 -dideoxyadenosines, although less active than ddA. An efficient method was developed starting from chloropurine riboside, which was tritylated and selectively benzoylated at 3 -position. Before fluorination the 2 -hydroxyl group was converted to imidazolesulfonate or trifluoromethanesulfonate. Fluorination proceeds smoothly with 6 equiv. of Et3 N.3 HF at reflux in 88% yield. Simultaneous 6-amination and 3 -debenzoylation was done with ammonia in high yield. Elimination of the 3 -hydroxy group was carried out under the Barton-McCombie procedure involving the formation of the 3 -O-thiocarbonyl followed by silane treatment. Final removal of trityl group afforded FddA (Figure 4.23).60 4.1.2.4
4 -Substituted Nucleosides
4 -Substituted nucleosides have attracted much attention because of the discovery of potent anti-HIV agents 4 -azido- and 4 -cyano thymidine (Figure 4.24).
NH2
194
4. Nucleoside Mimetics BzO
O
OAc
F F
a
Cl
NHBz
O X
X
N
N
N
NH
BzO
O
O
O
X = CH 3 X=H
F
X=H X=F
F
e,h
N
N
O
F
F
f,g,h
f,g,h
O
X NH2
O
N
X
X
N
HO O
O
N
HO
O
O
NH
N
N
HO
O
N
NH2
O F
F
N
N
N
NH
HO
F
N
O F
e,h
N
N
N
BzO
F
F
F
Cl N
N
O BzO
N
BzO
d
c
b
F
F
i) silylated thymine, TMSOTf, MeCN. b) silylated N4-Bz-cytosine derivatives, TMSOTf, MeCN. c) silylated 6-chloropurine, TMSOTf, MeCN. d) silylated 6-Cl-2-F-purine, TMSOTf, MeCN. e) NH3/MeOH, r.t. f) NH3/MeOH, 90 oC. g) HSCH2CH2OH, MeONa, MeOH, reflux. h) t-BuOK, THF.
FIGURE 4.16. Preparation of D- and L-2 -fluoro-2 3 -unsaturated nucleosides.
One procedure involves the epoxidation of the exoglycal with dimethyldioxirane and ring opening of the resulting 4 ,5 -epoxynucleosides to produce with high stereoselectivity the 4 -C-branched nucleosides (Figure 4.25).61 Likewise, other 4 -substituted nucleosides such as 4 -C-Ethynyl-β-D-arabino and 4 -C-Ethynyl-2 -deoxy-β-D-ribopentofuranosyl pyrimidines have been reported by a different approach outlined in Figure 4.26.62
4.1. Modified Nucleosides NH2
NH2 N
N
N
HO
i
N
N
O
O
HO
N
N
N
HO
195
HO
OTs i) LiEt3 BH, DMSO/THF
FIGURE 4.17. The Barton deoxygenation for preparing 2 -deoxynucleosides.
4.1.3 Complex Nucleosides The hypermodified Q base Queuine found in tRNA of plants and animals has been strongly associated with tumor growth inhibition. Three different approaches for preparing queuine have been described,63,65 the more recent in 11 steps from ribose. Completion of the synthesis involved the condensation of bromo aldehyde intermediate with 2,3-diamino-6-hydroxypyrimidine to give the desired heterocyclic product in 45%. Final removal of protecting groups provided Q base (Figure 4.27). Capuramycin is a complex nucleoside antibiotic isolated from Streptomyces griseus 446-S3, which exhibits antibacterial activity against Streptococcus pneumoniae and Mycobacterium smegmatis ATCC 607. The total synthesis was reported by Knapp and Nandan66 consisting of the glycosylation reaction between the key thioglycoside donor and silylated pyrimidine to produce the corresponding L-talo-uridine. The next glycosidic coupling reaction was carried out with L-talo-uridine and imidate glycosyl donor under TMSOTf conditions to afford
HO
CHO 2-steps D-Mannitol
i
O
CO2Et O
O
iii
TBDMSO
O
O
ii
O
O
iv
TBDMSO
O
O
N3
FIGURE 4.18. Synthesis of AZT from mannitol.
O
v
196
4. Nucleoside Mimetics OTMS CH3
N TBDMSO
N
TMSO
TBDMSO
O
O
vi
OH
OAc vii
N3
N3
O
TBDMSO CH3
HN O TBDMSO
O
vii
N
N3
O
N
+
O NH H3 C O
N3 O CH3
HN N
O HO
HO
O
N3 +
N
O
O NH H3 C O
N3
i) Ph3P=CHCO2Et, MeOH, 0oC. ii) HCl dil. iii) t-Bu(Me)2SiCl. imidazole, DMF. iv) LiN3, THF, AcOH, H2O. v) DIBAL, CH2Cl2, -78oC. vi) Ac2O, Py. vii) TMS-triflate, ClCH2CH2Cl. viii) n-Bu4NF, THF.
FIGURE 4.18. (Continued).
the disaccharide nucleoside. Further transformations led to the target molecule (Figure 4.28). Capuramycin has been also chemically transformed in an attempt to extend the antibacterial spectrum. Thus, radical oxygenation gave unexpected lactone
4.1. Modified Nucleosides
197
OTMS CH3
N TMSO
OR
O CH3
HN
N
OH
BnO
OR
N
O
OH
b,c
OBn
N3
OBn
N3
R=H a R = Bz
O CH 3
HN N
O d
HO
O
N3 i) PhCOCl (2.2 equiv.), NEt3 , DMAP, CH 2Cl2 . b) (CH 3) 3SiOTf, ClCH2 CH 2Cl. c) NaOH (2 equiv.), MeOH. b) 4.7 N H2 SO 4 in MeOH.
FIGURE 4.19. Synthesis of AZT from azido diol intermediate.
O
O
HN
HO
O
N
HN N
O
O
O
i
+ H2N
N
N3
N H
HN
+
N
HN
N
N
H2N HO
O
O
N3
i) glycosyltransferases, pH 6.0, 50oC.
FIGURE 4.20. Enzymatic synthesis of 3 -azido-2 ,3 -dideoxyguanosine.
N H
198
4. Nucleoside Mimetics NH2
NH2
HO
HO
O
N
N
N
N
N
N
N
N
N
N
NH2
N
N HO
O
LiEt3BH
O DMSO/THF
H OH
TsO
OTs O
O
H
NH2 N
N
N
N HO
O
OH
FIGURE 4.21. Method for preparation of -3 -deoxynucleoside.
in moderate yield via an intramolecular radical ArC glycosylationlactonization reaction (Figure 4.29).67 Synthestic studies of unique class Tunicamycin antibiotics leading to the preparation of (+)Tunicaminyluracil, (+)Tunicamycin-V, and 5 -epiTunicamacyn-V were described by Myers et al.68 The key features are the development and application of a silicon-mediated reductive coupling of aldehydes, the allylic alcohols to construct the undecose core of the natural product, and the development of an NH2
NH2 N
O N
NH
NH
N HO
N O
OH
O
HO i
N O
N
NH2 ii
HO
N
N
O
OH
OH
i) 2,6-diaminopurine, E. coli BM-11 and BMT-4D/1A, K-phosphate buffer, 52o C, 26 h, 64%. ii) Adenosine deaminase (ADase), r.t., 16 h, 68%.
FIGURE 4.22. Enzymatic synthesis of 3 -deoxyguanoside.
NH2
4.1. Modified Nucleosides Cl
Cl N
N
Cl N
N
ii
N
N TrO
HO
TrO
OH OH
Cl N
iii
N
N
N
TrO
TrO
N
N
N
N
O
N
N v
iv
N
O
OBz OH NH2
Cl
N
N
N
O
O
OH OH
N
N
i
N
N
199
TrO
O
O
F
F OBz OR
OH
OBz
R = SO 2-Imid R= SO 2CF3
N
N
N
N
vi
TrO
NH2
NH 2
NH2
O
N
N
N
N
vii
TrO
F
O
N
N
N
N
viii
HO
F
O F
OCSOPh i) TrCl-iPrNH, DMF, 79%. ii) a) BzCl-Py, toluene. b) cat. Et3N, toluene, 70%. iii) a) SO 2Cl2-Py, CH 2Cl2, b) imidazole. or CF3SO2Cl, DMAP, toluene. iv) Et3.3HF, Et3N, 70 and 78%. v) NH 3-MeOH, toluene 98%. vi) ClC(S)(OPh), DMAP, CH3CN, 92%. vii) Ph2SiH2, AlBN, dioxane, 81%. viii) 80% AcOH, 100oC, 85%.
FIGURE 4.23. Preparation of antiviral 2 3 -fluoro dideoxyadenosine FddA.
efficient procedure for the synthesis of the tetrahalose glycosidic bond within the antibiotic (Figure 4.30). 4.1.3.1
Fused Heterocyclic Nucleosides
Selective and potent antiVaricella Zoster Virus (VZV) bicyclic furanopyrimidine deoxynucleosides were synthesized. The bicyclic formation was performed by
200
4. Nucleoside Mimetics FIGURE 4.24. Structure of potent anti-HIV -4 -substituted nucleosides.
O NH N
HO
O
O
R OH R = N3, CN
palladium-catalyzed coupling of aryl acetylenes with 5-iodo-2 -deoxyridine affording the desired fused furanenucleoside (Figure 4.31).69 Triciribine is a tricyclic nucleoside with antineoplasic and antiviral properties, synthesized in an improved fashion from 6-Bromo-5-cyanopyrrolo [2,3-d] pyrimidin-4-one intermediate. Series of transformations including Nglycoside coupling reaction afforded 4-amino-5-cyano-7-[2,3,5-tri-O-benzoyl-βD-ribofuranosyl] pyrrolo [2,3-d] pyrimidine that was then converted to the desired tricyclic nucleoside (Figure 4.32).70
4.2 C-Nucleosides These modified nucleosides are structurally distinct to their counterparts Nnucleosides because of the presence of a C-C linkage instead of C-N between O
O
NH
NH N O
O
O
i
N O
NH
NH O
N
ii
O HO
TBDMSO
O
O
TBDMSO
TBDMS = tBuMe2Si
O
HO
N O
+
TBDMSO 64%
i) DMDO, CH 2Cl2, –30oC. ii) Me 3Al (3 eq.), CH 2Cl2, –30 oC, 2h.
FIGURE 4.25. Ring opening of 4 ,5 -epoxynucleosides.
TBDMSO 5%
O
4.2. C-Nucleosides BnO
BnO
O
BnO
O
i
HOH2C
BnO
O
ii
OHC
O
O
iii
Br2C
O
OBn O
201
C H
OBn O
HC
O
C
O OBn O
OBn O
O BnO
BnO
O
iv
O
OAc
v
Et3SiC C
HC
O
NH
vi
C
OBn O
BnO
N
BnO
OAc
O
O
HC C BnO
OAc
i) (COCl)2, DMSO, Et3N, CH2Cl2. ii) CBr4, PPh3, CH2Cl2. iii) n-BuLi, THF. iv) n-BuLi, THF, then Et3SiCl. v) a) 70% AcOH, TFA. b) Ac 2O, Py. vi) N,O-bis (trimethylsilyl)acetamide, thymine, CH2Cl2, reflux, 1h, 96%.
FIGURE 4.26. Synthesis of 4 -C-Ethynyl-β-Darabino and 4 -C-Ethynyl-2 -deoxy-βDribopentofuranosyl pyrimidines. Ns N
TBSO
i
O
Br O
iii
O
ii
O
O
Ns N
O
Ns N
HO
O
Ns N
iv
O
O
O
Ns O
H N
O
N v
HN O H2 N
N
N H
HN
O
OH H2 N
N
OH
N H
i) TBAF, THF, 87%. ii) TEMPO, NaOCl, KBr, CH 2Cl2, 88%. iii) TMSBr, DMSO, MeCN. iv) NaOAc, H2O/MeCN, 45%. v) a) HSCH2CH 2OH, DBU, DMF, 46%. b) HCl, MeOH, 84%.
FIGURE 4.27. Synthesis of hypermodified base Queuine.
202
4. Nucleoside Mimetics OTMS
O
N
BnO O
BnO
OTMS
N
SPh
NH N
AcO
O
O i
MeO
RO
OPiv
ii
R = Ac R=H
MeO
BnO AcO AcO
O OAc O
OAc O
AcO AcO
CCl3
O
O
O
BnO
OPiv
NH OBn
NH
O
O
N
O
iii
MeO
OPiv
OH OH
HN
O CONH 2
O H N
O O
N
NH
O
O
O MeO
OH
i) NIS, TfOH, CH 2Cl2, –20o C. ii) NaOMe, MeOH, 77%. iii) TMS-OTf, CH 2 Cl2, –25oC, 16 h, 85%.
FIGURE 4.28. Synthesis of Capuramycin.
the furanoside and the heterocyclic aglycon. Their source could be either naturally occurring (pyrazomycin, showdomycin, formycin) or synthetic (thiazofurin), having in either case significant antitumor and antiviral activity. Also, some of them have been found in tRNA codons (pseudouridine) and others (tiazofurine and oxazofurine) designed as competitive inhibitors of cofactor nicotin adenin dinucleotide (Figure 4.33). An early approximation for the preparation of C-nucleosides proposed two basic possibilities depending on the nature of the atoms surrounding the C-C bond (Figure 4.34).71 1. If there is one heteroatom adjacent to the C-glycosidic bond, for example, tiazofurine, formicine, pyramicine.
4.2. C-Nucleosides
203
OR 3 OR 2
O CONH 2
O H N
HN
O O
N
NH
O
O
O MeO
OR 1
capuramycin R 1 = R 2 = R 3 = H i
R1 = R3 = TBDMS, R 2 = H
ii
R1 = R3 = TBDMS, R2 = C(S)OPh R1 = R3 = TBDMS, R2 = C(S)O-p-Tol iii
O O
Ph
O OR
O CONH 2
H N
O
HN
O
N
NH
O
O
O MeO
OR
R = TBDMS i) TBDMS-Cl, pyridine. ii) C 6H 5OC(S)Cl, DMAP, CH2 Cl2. iii) Bu3SnH, AlBN, PhMe, reflux
FIGURE 4.29. Chemical transformations of capuramycin
2. If there is no heteroatom adjacent to the C-glycosidic bond. Alternatively, other authors considers three general pathways for preparing Cnucleosides depending on the precursor employed as starting material.72 An early synthesis of modified C-nucleoside from naturally occurring pseudouridine was carried out via ring opening with ozone to generate an intermediate,
204
4. Nucleoside Mimetics O CH3
H 3C
Si O
BOMO
TBSO O O
NBoc
SePh H
O
O
N
O
CbzHN O AcHN
O CH2 TBSO
OTBS
O
i
O OH
BOMO CbzHN
OH
O
O TBSO O O
NPMB
H
O
N
O
AcHN O HO
OH
O OH
HO H2 N O
H O
O
AcHN HO HO HO
NH OH N
O
O HO
OH
i) triethyborate, Bu3 SnH, toluene, 0o C. 2 h. b) KF.H2 O, MeOH. 60%.
FIGURE 4.30. Key step for the synthesis of Tunicamycin antibiotic.
which was treated with thiosemicarbazone to afford 6-azathiopseudouridine. Treatment with iodomethane in acid medium produced the desired C-nucleoside as shown in Figure 4.35.73 The synthesis of the C-nucleoside pseudouridine was reported by Asburn and Binkley,74 involving the condensation between 5-O-acety-2,3-O-
4.2. C-Nucleosides
205 R
O I HN
H
O
R HN
HO
N
O
i
O
HO
N
O O
OH OH
R
O N
ii
HO
O
N O
OH i) Pd(PPh3)4, iPr2EtN, CuI, DMF, r.t, 19 h. ii) Et3N/MeOH. CuI, ∆ , 4h.
FIGURE 4.31. Synthesis of bicyclic furano pyrimidine.
isopropylidene-D-ribonolactone with 2,4-dibenzyloxypirimidin-5-il lithium to provide the condensation product, which was subjected to hydride reduction and hydrogenolysis to yield pseudouridine (Figure 4.36). Antitumor C-nucleoside Tiazofurine was synthesized by Robins et al.75 from 2,3,5-tri-O-benzoyl-β–Dribofuranosyl cyanide, which undergoes ring closure under conditions described in Figure 4.37. A new report for the synthesis of Tiazofurine is described, avoiding the use of H2 S gas, which is unsafe on large-scale production. The synthesis initiates with the preparation of 1-cyano-2,3-O-isopropylidene-5-O-benzoyl-β-Dribofuranose, which was reacted with cysteine ethyl ester hydrochloride to give thiazoline derivative in 90%. Further steps including oxidative aromatization under MnO2 in benzene and acetonide deprotection with iodide in methanol produced the desired C-nucleoside (Figure 4.38).76
206 NH2
4. Nucleoside Mimetics O
CN i
N
HN
N H
Cl
Br
N H
N
H 3C
CN
N iii
Br
v
Br
N
BzO
O
OBz OBz
H3C
NH2 CN
N
vi
O
OBz OBz
N
N
NH2
N
N
N
N
N
O
OBz OBz
BzO
CN
N
iv
N H
NH2
N
N
N
H3C
N
ii
N
BzO
CN
Br
Br N
Cl
CN
N
N HO
O
OH OH
i) NaNO2, AcOH, H2O, ii) POCl3. iii) BSA, CH3CN then 1-O-acetyl-2,3,5-tri-O-benzoyl-b-D-ribofuranoside, TMSOTf. iv) NH2NHCH3, EtOH, CHCl3. v) HCO2NH4, 10% Pd-C, EtOH, reflux. vi) NaOMe, MeOH, reflux.
FIGURE 4.32. Synthesis of tricyclic nucleoside Triciribine.
Another biologically important C-nucleoside known as showdomicine was prepared by Trumnlitz and Moffat.77 The aldehyde used as starting material was converted first to an α–hidroxyacid and then to α–ketoacid. Wittig reaction on this intermediate and Lewis acid catalysis produced ring closure (Figure 4.39). Pyrazine riboside derivative was synthesized by treatment of glycine riboside with formaldehyde and cyanide (Strecker conditions) to generate cyanide intermediate as a mixture of isomers. Sulfenylation and sodium methoxide treatment produce the C-nucleoside (Figure 4.40).78
4.2. C-Nucleosides O HN
O
O
O
O
O
O
NH2
NH
NH HO
HO
S
HO
OH
HO
tiazofurin
showdimicine
pseudouridine
O H N
NH2 H N
NH
N HO
N
O
OH
HO OH
HO
N
N N H
O
HO
O
HO
OH
N
O
HO
oxoformicine B
OH formicine
CO2H O
O
H2N
O OH
CO2H O
OH
MeO O
OH
NH
H 2N O
O
O
NH
H2N
207
O
HN
NH
O HN
NH
O
O Ezomycin B2
Malayamycin A
FIGURE 4.33. Biologically active C-nucleosides.
Analogs of antiviral C-nucleoside Formicine have been synthesized by using the palladium-mediated glycosidic reaction between the furanoid glycal and the iodinated heterocycle. Similar conditions were used for preparing the pyrimidine analogs (Figure 4.41).79 Radical cyclization of ribo-phenylselenoglycoside tethered with propargyl moieties on C-5 hydroxyl group afforded cyclic intermediates potentially useful for the
208
4. Nucleoside Mimetics NH
C HO
C
HO
O
O
C
HO
C
OH
a
HO
OH
b
O
O HN
FIGURE 4.34. C-nucleosides partial representations, with and without heteroatom attached to the Cglycosidic bond.
C
C
C
S H2N
NH
NH HN
O AcO
O
O
AcO
O
HO
i
O
HO
OAc
ii
NH
N HO
O
O
OH HO
OH
O HN iii
NH
N HO
O
O
HO
OH
i) O3. ii) NH2NHCNNH2=S. iii) MeI/H3O+
FIGURE 4.35. Preparation of 6azapseudouridine.
synthesis of C-nucleoside derivatives. Propargyl intermediate was prepared from ribo-phenylselenoglycoside via two-step sequence and then under radical reaction conditions (Bu3 SnH/AIBN) transformed to the cyclic intermediates in high yields. Further ring opening produced an aldehyde intermediate, which was subjected to a coupling reaction with 1,2-phenylenediamine to produce the pyrazine C-glycoside (Figure 4.42).80 Polyhalogenated quinoline C-nucleosides were synthesized as potential antiviral agents. The key step reaction for quinolin-2-one ring formation consisted in the condensation between 2-aminophenoneallose derivative with keteneylidene(triphenyl)-phosphorane in benzene under reflux to provide the desired 6,7-dichloroquinolin-2-one nucleoside in 50% yield (Figure 4.43).81
4.3. Carbocyclic Nucleosides
209
OBn OBn
HO
O
+ O
N
N
O N
N
OBn
HO
O
OBn
O
OH
Li O
O
O HN
NH
i,ii
O
HO
O
OH OH i) NaBH4. ii) a) H2, Pd-C. b) H3O+
FIGURE 4.36. Preparation of pseudouridine.
The Novel bicyclic C-nucleoside Malayamycin A from Streptomyces malaysiensis was elegantly synthesized from D-Ribonolactone, which was transformed to the target molecule according to the pathway indicated in Figure 4.44.82
4.3 Carbocyclic Nucleosides This class of modified nucleosides in which the furanose ring has been replaced by a cycloalcane ring (mainly cyclopentane) has been prepared by chemical or O NH2
NH2 BzO
CN O
OBz OBz
BzO i
C O
S
ii,iii
S
HO
N
O
OBz OBz HO
i) H2S, 4-DMAP. ii) ethylbromopyruvate. iii) NH3/MeOH.
FIGURE 4.37. Synthesis of tiazofurine.
OH
210
4. Nucleoside Mimetics O
EtO
BzO O
N
N
CN
S
S i
ii
BzO O
O
EtO
BzO O
O
O O
O
O
O
O
H2N N
S iii-iv
HO O
OH
OH
i) Cysteine ether ester hydrochloride/TEA. ii) MnO2/Ph, reflux. iii) 90% TFA. iv) MeOH/NH3
FIGURE 4.38. A new synthetic methodology for tiazofurine.
enzymatic methods. Besides their potent antitumor and antiviral activity for some of them, they have also shown high resistance to phosphorylases. The use of enzymes, particularly lipases, for protections and deprotections is an important strategy for preparing carbocyclic nucleosides. This approach has been advantageous especially for the resolution of enantiomeric forms, leading to high enantiomeric purity. Constrained three83 and four84 member ring carbocyclic nucleosides have been obtained by applying chemoenzymatic methodologies involving lipase for enantiomeric resolution and stereoselective deprotections. In the case of more abundant five-member rings, the use of lipases for enzymatic resolution and regioselective deprotections has been under intense study. Special attention has been paid to cyclopentenyl diacetates, which have been used as building blocks for the preparation of important carbocyclic nucleosides such as Neplanocin and Aristeromycin. To achieve this goal, the hydrolase enzyme acetylcholinesterase (EEAC)85 showed high efficiency for obtaining the desired enantiomer (1R,4S)-4-hydroxy-2-cyclopentenyl derivative in enantiomeric excess (ee) up to 96% (Figure 4.45).86,87 Racemic cyclopentenyl derivatives have been used as starting material in the preparation of the antiviral carboxyclic nucleoside (-)-5 -Deoxyaristeromycin. The
4.3. Carbocyclic Nucleosides CO2CH3 BzO
CHO O
BzO i,ii
OBz OBz
CO2CH3
CHOH O
C
BzO
iii
OBz OBz
O
O
OBz OBz O
CO2H CO2H
HO
211
O
iv
O
AcO
O
O
OH
HO
AcO
OAc
O NH v
HO
O
O
HO
OH
i) NaCN. ii) a) MeOH-H3O+. b) Me2SO-DCC. iii) Ph3P=CHCONH2. iv) Ac2O. v) a) NH3. b) EPP. v) H +.
FIGURE 4.39. Preparation of showdomicine.
key step reaction was the enzymatic resolution with Pseudomona sp lipase (PSL) of the racemic mixture affording the (+)-enantiomer, which was transformed chemically to the desired carbocyclic nucleoside (Figure 4.46). The separation of racemic carbocyclic nucleosides by enzymatic means has been reported as an alternative approach. Thus, racemic aristeromycin was treated with adenosine deaminase (ADA) to give (−)-carbocyclic inosine and pure destrorotatory enantiomer (Figure 4.47).88
4.3.1 Cyclopropane Carbocyclic Nucleosides Conformationally constrained cyclopropane nucleosides have been prepared following a chemoenzymatic approach.83 Thus, the racemic resolution of trans-1-(diethoxyphosphyl)difluoromethyl-2-hydroxymethylcyclopropane followed by acetate hydrolysis was carried out with porcine pancreas lipase (PPL) to yield (+)- and (−)-cyclopropanes in high enantiomeric excess. Further
212
4. Nucleoside Mimetics CN O H2N
TBDMSO
HN
NH2
O
O
O
i
TBDMSO
O
NH2
O
O
ii
O
TBDMS = tBuMe2Si
NH2 NO2
CN NH
O S
iii
N
TBDMSO
NH2
O
O
N O
TBDMSO
O
O
O
O
i) CH 2O, HCN. ii) 2-NO2C6H4SCl. iii) NaOMe. MeOH.
FIGURE 4.40. Synthesis of C-nucleoside by pyrazine ring formation.
transformation led to the preparation of the target cyclopropane nucleoside (Figure 4.48).
4.3.2 Cyclobutane Carbocyclic Nucleosides Lubocavir is a synthetic potent inhibitor of DNA polymerase, active against cytomegalovirus89 (Figure 4.49). The carboxyclic four-membered C-nucleoside Cyclobut-A was prepared following the Barton decarboxylation method. The method is based on the reaction between carboxylic acids with heteroaromatic compounds (Figure 4.50).90 Other carbocyclic oxetanocin analogs have been prepared from oxetanocin A91 3,3-diethoxy-1,2-cyclobutanedicarboxylate-92 and enantiomeric cyclobutanone intermediates93 as starting materials.
4.3.3 Cyclopentane Carbocyclic Nucleosides The Mitsunobu reaction has become a valuable alternative approach for preparing cyclopentane carbocyclic nucleosides. This has been demonstrated in the preparation of conformationally locked carbocyclic AZT triphosphate analogs under this
4.3. Carbocyclic Nucleosides
213
OTHP OTHP HO
O
N
THP N
N
N i
N
N
+
THP N
HO N
O
I
t-Bu(Ph)2SiO
t-Bu(Ph)2SiO i) Pd(dba)2, AsPh3, MeCN.
OMe OMe
OMe N
N N
N
N
N
OMe TrO
O
OMe
I
TrO
+
OMe TrO
O
O
i
53 %
30 %
OMe N
N
ii
OMe TrO
O
i) Pd(OAc)2, NaOAc, n-Bu4NCl, Et3N, DMF. ii) H2, Pd/C, ammonium formate, ETOH.
FIGURE 4.41. Palladium-mediated synthesis of C-nucleoside formycin analogs.
versatile condition.94 The standard procedure usually takes place with diethyl or diisipropylazocarboxylate (DEAD or DIAD) with triphenylphosphine (Ph)3 P in THF to yield carbocyclic purines or pyrimidines nucleosides in high yield (Figure 4.51).95
214
4. Nucleoside Mimetics O R
O
HO
SePh
O
O
i,ii
R
O
SePh
iii
+
Br O
R = Me R = TMS
O
O O
O
O
O H HO
N
O
iv
R
v
HO
O N
O
O O
O
i) NaH, ii) n-BuLi, TMSI or MeI. iii) n-Bu3 SnH. iv) SeO2-AcOH, 1,4-Dioxane. v) a) O3. b) DMS. 3) 1,2-phenylenediamine.
FIGURE 4.42. C-nucleoside derivative formation via radical cyclization.
Another example on the applicability of this method was observed in the preparation of the carbocyclic thymidine nucleoside. It is worth mentioning that the desired stereochemistry of the hydroxyl group is obtained also through the Mitsunobu reaction (Figure 4.52).96
4.3.4 Palladium Mediated Based on the widespread palladium-coupling methodologies, several dideoxy, carbocyclic and C-nucleosides have been efficiently prepared. For instance, the Cl
NH2
O Cl
O
i,ii
Cl O
O
TBDMSO
H N
Cl
O
O
O HO
O
i) Ph3P=C=C=O, PhH, reflux. ii) TBAF, THF, rt.
FIGURE 4.43. Quinolin-2-one C-nucleoside formation via Wittig reaction.
4.3. Carbocyclic Nucleosides
215 OMe N
OMe
O
O
O
HO
OMe
O
O
a
MeO O
O HO
N
b
OH
OH
O
O
O
O
OMe N O
OMe
c
OH
OMe
O
O
N
OMe
OH N
N
MeO
d
O
O
OMe
O
O
OMe OMe
N
N N
MeO e,f,g
h
O O
O
O
HO OH Si
Si O
N
MeO
OPMB
O
O
OPMB
Si
Si
FIGURE 4.44. Total synthesis of C-nucleoside Malayamycin A.
antiviral C-nucleosides 2 -deoxyformycin B was prepared by condensation reaction between the heterocycle iodide intermediate with the glycal, under Pd(dba)2 as palladium catalyst in 62% yield (Figure 4.53).97 Solid-phase synthesis of carbovir analogs under palladium catalysis was recently reported.98 The carbocyclic derivative was linked to the Wang resin and then coupled with chloropurines under Pd(0) catalyst (Figure 4.54). The Tsuji-Trost approach was used to prepare (−)-neplanocin A and its analog.99 This synthesis proceeds via an allylic rearrangement of the hydroxyl group from the (+)-allylic alcohol to the (−)-allylic acetate (Figure 4.55).
216
4. Nucleoside Mimetics OMe
OMe
N
N N
MeO i,j
N
MeO
l
k
O
O
OPMB
OPMB
HO
O
Br
MeO
H
MeO
H HO
N
O
N
O
m
n
OMe
OMe
N
O H
O
H
OPMB
N3
MeO
H
N
O
OPMB
HO
N
O
MeO
H
N
O
o
OMe
OMe N
O H
H
OPMB
N3
MeO
H
MeO
N
O
OPMB
N3
MeO
H
O
N
O
N
O
q,r
p
OMe
OMe O
N
O H
N3
N H
OPMB
OPMB
MeO
O
s,t
N3
MeO
H
N
u
O
H
MeO
O
NH O
OMe N
O H
NH
O H
OPiv
FIGURE 4.44. (Continued)
OPiv
4.3. Carbocyclic Nucleosides
217
O H2 N
NH
O
H
MeO
O
v,w,x
NH O NH
O H
OH
a) 2,2-dimethoxypropane, Na 2SO4, PPTS, 94%. b) 2,4-dimethoxy-5-iodopyrimidine, t-BuLi, 75%. c) L-Selectride, ZnCl 2, DCM, 86%. d) DIAD, Ph3P, THF, 91%. e) 70% AcOH, 85%. f) 1,3-dichloro-1,1,3,3-tetraisopropyldisiloxane, pyridine, 89%. g) NaH, PMBBr, DMF/THF, 84%. h) 1 N HCl, Dioxane, 88%. i) DMSO, (COCl)2, i-Pr2 NEt, DCM. j) Ph3PCH 3Br, NaHMDS, THF (36%, 2 steps). k) allyl bromide, NaH, DMF, 93%. l) Cl2 RuCHPh(PCy 3)2, DCM, reflux (89%). m) NBS, H 2O, THF. n) NaOH, THF. o) NaN 3, methoxyethanol (5:1, 41%, 3 steps for 14). p) Dess-Martin periodinate, DCM. q) NaBH 4, MeOH. r) NaH, MeI, DMF (93%, 3 steps). s) DDQ, H2 O, DCM (84%). t) Piv-Cl, DMAP, NEt3, pyridine. u) TMS-Cl, NaI, actonitrile (42%, 2 steps). v) PMe 3, H2 O, THF. w) trichloroacetylisocyanate, DCM. x) MeNH 2 , MeOH, H 2O (60%, 3 steps).
FIGURE 4.44. (Continued) HO
OAc
OAc
OH
OAc
i
A
OH
OH
(–)-Aristeromycin
OH
(+)
A
i) acetylcholinesterase (EEAC), buffer.
OH
OH
(–)-Neplanocin A
FIGURE 4.45. Enantiomeric resolution of prochiral cyclopentene diacetate. Me OPh
OAc
OPh i
(±)
A
OAc
(+)
OH
OH
(–)-5-Deoxyaristeromycin i) PSL, buffer.
FIGURE 4.46. Enzymatic resolution of racemic cyclopentene building blocks.
NH2 N HO
N
N
N
OH
NH2
N
i
HO
OH
N
N
N
OH
O
N
HO
+
OH
N
OH
OH
(+)
(±)
FIGURE 4.47. Enzymatic resolution of carbocyclic nucleoside. (EtO)2
P O
PPL
THF, 37oC
OAc
(EtO)2
OAc
CF2
P O
OH
CF2
+
(EtO)2
P O
OAc
CF2
PPL 30% iPr2O-buffer pH 7.3
(EtO)2
P O
OH
CF2
(EtO)2
P O
OH
CF2
O
O N
N N
(EtO)2
P O
CF2
NH
NH N
N
NH2
(EtO)2
P O
N
NH2
CF2
FIGURE 4.48. Chemoenzymatic syntheses of cyclopropane nucleosides.
NH N
4.3. Carbocyclic Nucleosides
219
FIGURE 4.49. Structures of carboxetan carbocyclic nucleoside.
O N
NH
N
N
OH
NH2
OH Structure of Lubocavir
Carbocyclic nucleoside Aristeromycin with antitumor and antiviral activity was prepared by condensation of the carbocyclic diacetate intermediate with the sodium salt of adenosine base under Pd(0) in 75% yield (Figure 4.56).100 Palladium-mediated coupling of purine base with carbocyclic acetates, carbonates, or benzoates led to a mixture of N-7 and N-9 isomers. The regioselectivity of purine alkylations depends on the size and nature of the ligands, being the most typical Ph3 P, BINAP, P(OMe)3 , P(OiPr)3 , P(OPh)3 . (Figure 4.57).101 Another straightforward methodology for preparing carbocyclic nucleosides involves the direct condensation of mesylated carboxyclic intermediate with the HON RO
O
RO S
C O N
CO2H DCC, THF r.t. dark
OR
S
OR
NH2 NH2
N
N
N
N RO
N
N H N
W-hv, 30-40oC
N
RO
OR OR
FIGURE 4.50. The Barton decarboxylation method for the preparation of carbocyclic Cnucleosides.
220
4. Nucleoside Mimetics Cl Cl N N
NH
+
BnO
OH OBn
i
N N H
NH N
NH2
NH2
N
BnO OBn i) DIAD, Ph3P, THF, r.t.
O
O I
PhOCN
I PhOCN
BnO O
N H
O
N
OH i,ii
BnO
HO
OH
i) Ph3P, DEAD, THF. ii) BCl3, CH2Cl2.
FIGURE 4.51. Synthesis of conformationally locked carbocyclic purine and pyrimidines under the Mitsunobu approach.
heterocyclic base in the presence of potassium carbonate and crown ethers as coupling conditions (Figure 4.58).102
4.3.5 Enzymatic Synthesis Likewise, carbocyclic nucleosides aristeromycin and neplanocin A can be biosynthetically prepared by using a mutant strain of S. citricolor as is observed in Figure 4.59. The cyclopropylamino carbocyclic nucleosides (−)-Abacavir is a potent antiHIV drug with promising results on clinical trials.103 An improved synthesis has been described by Crimmins et al.104 involving the treatment of key carbocyclic 2-amino-6-cloropurine intermediate with cyclopropilamine producing Abacavir along its parent anti-HIV carbocyclic nucleoside (−)-Carbovir (Figure 4.60). 4.3.5.1
Base Ring Formation
Another useful strategy used for preparing carbocyclic nucleosides involves the use of intermediates in which the amino group is already attached to the sugar
4.3. Carbocyclic Nucleosides
221 O NBz
BnO
OH
BnO
BnO i
N H
ii
OH OH
OH
O iii-iv
OH
O NH N
HO
O
OH
i) NaH, BnBr. ii) 9-BBN, H 2O 2/NaOH, 87 %. iii) PPh3, DIAD. iv) a) NaOH/MeOH. b) H 2, Pd/C, 90%
FIGURE 4.52. The Mitsunobu reaction for preparation of the carbocyclic thymidine nucleoside.
moiety and once the coupling reaction is achieved, a ring closure process takes place to generate the expected nucleoside. According to this procedure Roberts et al.105 prepared the potent antiviral inhibitor (−)-carbovir, which possesses similar activity than AZT against HIV in MT-4 cells. Thus, the starting material (±)2-azabiciclo [2.2.1] hept-5-en-3-one was submitted to microbial treatment with Pseudomona solanacearum to provide enantiomerically pure (−) isomer. The enantiomerically pure carbocyclic amine was then conjugated to 2-amino-4,6dichloropirimidine to produce the carbocyclic precursor which was ultimately cyclized to afford the desired (−)-carbovir (Figure 4.61). Anti-leukemia carboxylic nucleoside Neplanocin A has been synthesized by Marquez et al., under the ring closure approach mentioned above. Thus, condensation of pyrimidine intermediate with isopropylideneaminocyclopentenediol furnished intermediate, which was further cyclized to the purine base with
222
4. Nucleoside Mimetics OTHP OTHP THP N
N
N
HO
O
N
i
+
HO
N I
THP N
N N
OSi(Ph)2t-Bu
O
t-Bu(Ph)2SiO
O H N
HN
N HO
N O
R
R= OH R=H
i) Pd(dba)2, AsPh3, CH 3CN.
FIGURE 4.53. Palladium-mediated 2 -deoxyformycin B and 2 ,3 -dideoxyformycin B.
triethylortoformiate. Final conversion to adenine ring with ammonia and protecting group removal gave place to Neplanocin A (Figure 4.62).106 Likewise, this procedure was applied for the preparation of the close related pyrimidine analog by condensation of the previous carbocyclic amine with the unsaturated ether to produce the pyrimidine precursor who was transformed to thiopyrimidine and then to carbocyclic cytosine, as Figure 4.63 shows. This compound has been found to be active against leukemia type L1210 in vivo.107 An antiviral carbocyclic purine nucleoside was also reported108 by following a ring closure step for purine formation. Condensation between pyrimidine intermediate with carbocyclic amine afforded condensation product, which is activated with diazonium salt for amino introduction. Ring closure was achieved with triethyl orthoformate in acid medium (Figure 4.64).
4.4. Acyclic Nucleosides
223
HO O O OAr
O
BzO
X N
N
O O O
N H
O
Y
N
Pd(0) BzO X N
N
O O O
O
N
N
Y
FIGURE 4.54. Solid-phase synthesis of carbocyclic nucleosides under palladium catalysis.
4.3.6 Carbocyclic C-Nucleosides This class of C-nucleosides in which a methylene group replaces the furan oxygen ring does not show significant biological activity so far; however, there is an interest to synthesize C-nucleoside with natural heterocycle moieties in a stereocontrolled fashion. A recent stereocontrolled synthesis of carbocyclic C-nucleosides has been proposed involving as key starting material the cyano carboxyclic intermediate which was condensed to 9-deazapurine to produce saturated and unsaturated carbocyclic 9-deazapurine nucleosides (Figure 4.65).109
4.4 Acyclic Nucleosides Since the discovery of Acyclovir as an anti-herpes drug, important efforts have been made toward the synthesis of analogs of acyclovir and other acyclic nucleosides. A comprehensive review made by Chu and Cutler110 summarizes the major
224
4. Nucleoside Mimetics BnO
BnO
BnO
i
ii
AcO
HO O
OAc O
O
O
O (–)
(+)
(+)
O
X N HO
N
O
O
N N
Y
X = NH 2, Y = H X = OH, Y = H
i) Ac2O, DMAP. ii) PdCl2(MeCN)2, pBQ, THF.
FIGURE 4.55. Tsuji-Trost reaction for the preparation of neplanocin A.
achievements carried out for preparing acyclonucleosides defined as those heterocyclic compounds containing one or more hydroxyl groups on the alkyl side chain. At least three representative synthesis of acyclovir have been made, the first by Schaeffer et al.111 involving a condensation reaction of dichloropurine with ether chloride intermediate, and further purine transformation to generate 9-(2hydroxyethoxymethyl)guanine (acyclovir) (Figure 4.66). An improved version introduced by Barrio et al.112,113 consists of the initial reaction of 1,3-dioxolane with trimethylsilyl iodide to produce the side chain, NH 2 NH2 AcO
OAc
N N
N
+
i
AcO N Na
N
N
N
i) Pd(PPh3)4 (0.005 eq.), Et3N, THF, reflux
FIGURE 4.56. Palladium catalyzed synthesis of aristeromycin.
N
4.4. Acyclic Nucleosides
225
X N
N
X PO N
NH2
N
N
OP OP
N
N H
+
NH2
N i
NH2
N
N P = Ac, CO 2Me, CO P = Ac, X = Cl N9/N7 = 86:14
PO
P = CO2Me, X = Cl N9/N7 = 74:26
N
N
P = H, X = Cl N9/N7 = 85:15
X
P = Ac, X = NHcyclopropyl N9/N7 = 95:5 i) Pd(PPh3)4, THF/DMSO, 45oC 50-70%.
FIGURE 4.57. Palladium-catalyzed coupling with purine base.
which was then condensed with the halogenated purine to yield after hydrolysis and ammonolysis the target acyclovir (Figure 4.67). Robins and Hatfield114 employed a chemoenzymatic approach for preparing acyclovir consisting initially in the use of mercury salts and hexamethyldisilane (HMDS) and in the final step an enzymatic conversion. Thus, the procedure NH2
OBn
N
N
+
OMs O
N
NH 2
F
O
N H
i
F
N
N N
OBn N
O
O
i) K2CO3, 18-Crown-8.
FIGURE 4.58. Preparation of carbocyclic nucleosides with mesylated carboxyclic intermediates.
OP
OP OH HO OHC
O
HO
NH2 N N H
OH
OH
HO
OH
OH
NH2
NH2
N
N
N
OH
N
HO
N
N OH
N
N
HO
OH
N N
OH
Aristeromicin
Neplanocin A
FIGURE 4.59. Biosynthetic pathway of neplanocin A and aristeromicin. Cl N
N OAc
H2 N
N H
N
AcO
NH2
Cl N
N
+
N
N
H2 N
Cl
11%
65%
ii, iii
iii
O HN
H2 N
N
N
N
N
N
N
N
N AcO
AcO
i
N
N
H2 N
N
N
HO
HO
i) NaH, Pd(PPh3 )4 , 1:1 THF:DMSO. ii) cyclopropylamine, EtOH. iii) NaOH, H 2 O.
FIGURE 4.60. Synthesis of anti-HIV (-)-Abacavir and (-)-Carbovir.
4.4. Acyclic Nucleosides O
HO
O
NH
227
NH i
NH2 ii-vi
(+) –
(–)
Cl
O H2N
Cl
N
HN
vii-xi
H 2N
N
N
HO
(–)-carabovir
i) P. solanacearum NCIB 40249. ii)HCl-H2O. iii) (MeO)2CMe2. iv) Ac2O/Py. v) Ca(BH4)2/THF. vi) HCl-H2O/EtOH. vii) PrNEt, nBuOH. viii) 4-Cl-C6H4N2+ Cl-AcOH, AcONa/H2O. ix) Zn, AcOH/EtOH-H2O. x) (EtO)3CH/HCl. xi) NaOH/H2O.
FIGURE 4.61. Synthesis of (−)-Carbovir.
involves the condensation between 2,6-dichloropurine with the bromoether, affording regioisomer N-7 shown in Figure 4.68. Further amination and final transformation to guanine with the enzyme adenosine-deaminase produces the desired antiviral compound. The phosphonate acyclic nucleoside 9(2-phosphonomethoxyethyl)adenine (PMEA) was founded as a good antiviral analog with prolongated action.115 A regio-defined synthesis base on the purine ring formation was described involving the initial attachment of the phosphonate amine intermediate by nucleophilic substitution to the 5-amino-4,6-dichoropyrimidine base, and then ring formation followed by amination to produce the desired phosphonate acyclic adenine PMEA (Figure 4.69).116 The effectiveness of acyclovir as an antiviral drug encouraged different groups to synthesize more potent acyclic analogs. As a result of these efforts, the acyclic nucleoside 9-[(1,3-Dihydroxy-2-prpoxy)methyl]guanine (DHPG)117 was prepared and tested as antiviral nucleoside, showing similar potency as acyclovir against simple herpes but stronger against encephalitis and vaginitis herpes. Various report of DHPG were described, one of them involving the use of hexamethyldisilylasane (HMDS) as condensing agent (Figure 4.70).110 An alternative route for preparing DHPG involved the condensation reaction of acetylguanine base and triacetate derivative in the presence of ethanesulfonic
228
4. Nucleoside Mimetics Cl Cl
NH2
BzO NH2
N
i
ii
+
N O
Cl
N
NH2
N
NH
BzO
O
O
O NH2
NH2
Cl N
N
iv
iii
N
N
N
N
N
N
N
N
N
N
HO
BzO
BzO
OH OH O
O
O
O
i) EtN3/EtOH. ii) HC(OEt)3, Ac2O. ii) NH3/MeOH. iii) BCl3/CH2Cl2-MeOH
FIGURE 4.62. Synthesis of neplanocin A.
acid, at temperatures ranging from 155 to 160◦ C. As result two regioisomers were obtained from which one of those was converted to the desired antiviral compound Figure 4.71.110
4.5 Thionucleosides Nucleosides having the sugar ring oxygen replaced by sulfur are known as thionucleosides. The synthesis and therapeutic evaluation mainly as antiviral and anticancer drugs of these nucleoside mimics have been reviewed.118 A comparative analysis of thionucleosides and nucleosides showed that sulfur replacement in some cases produced equivalent or higher potency119,120 and do not undergo enzymatic cleavage of the glycosidic bond, although it has been also observed increased toxicity as in the case of β-4 -thiothymidine.121 Some thionucleosides displaying antiviral and/or anticancer activity are shown in Figure 4.72.
Cl NH2
BzO
EtO
N
i
ii,iii
+
NH
O
CONCO O
O
S
NH2
HN N
HN N
O
BzO
HO
iv
O
O
N
O
BzO
iv
O
O
NH2
HN O
OEt
BzO
O
O
OH OH
i) PhH. ii) DMF, NH4OH. iii) Lawesson. iv) NH3 liq. v) a) BCl3 /CH2Cl2-MeOH. b) Dowex H+
FIGURE 4.63. Synthesis of carbocyclic pyrimidine nucleoside. Cl
Cl NH2
HO
ii
+
N
H2N
Cl
N
H2N
N
i
N
NH
HO
OH
OH Cl
Cl N
N
Cl
NC6H4-Cl
NH2
N iii
N
H2N
NH
HO
H2N HO
N H
NH H2N HO
OH
N
N
iv
N H
N
OH OH
i) Et3N/EtOH. ii) 4-Cl-C6H4N2+Cl– , Na2CO3, AcOH/H2O. iii) Zn/AcOH. iv) CH(OEt)3-HCl/DMF.
FIGURE 4.64. Ring closure approach for preparation of carbocyclic purine.
230
4. Nucleoside Mimetics NH2 H N
N N
HO
HO t-BuO
EtO2C
OH
CN O
O H N
H N O
N
HO
N
t-BuO
O
NH
NH
O
OH OH
O
R = H, NH2
O H N
HO
NH N
R
R
R=H
FIGURE 4.65. Stereocontrolled syntheses of carbocyclic 9-deazapurine nucleosides.
Based on their structural features N-thionucleosides defined also as thioribosyl sugars are classified into four groups (Figure 4.73):
4.5.1 Preparation of Thioribofuranosyl Intermediates A number of approaches oriented to replace or insert a sulfur atom instead or besides the cyclic oxygen into the ribose ring have been described. One of the
4.5. Thionucleosides
231
Cl Cl i
C6H5CO 2CH2CH 2OCH2Cl
+
Cl
N
Cl N C6H5OO
N H
N
N
N
N
N
O
O N
HN
ii
H2 N
N
N HO
O
Acyclovir
i) Et3N. ii) NH 3.
FIGURE 4.66. First synthesis of Acyclovir.
I N
N
O
O
+
Me3SiO
Me3SiI
O
I
O
I N
N N Cl Me3SiO
N H
N
Cl
N
HN i,ii
N
HO
O
N
N
H2 N
O
Acyclovir i) K2CO 3. ii) NH 3.
FIGURE 4.67. Improved synthesis of acyclovir.
232
4. Nucleoside Mimetics Cl Cl AcO
N
N
O
N
N
i
+
Cl
N H
N
Cl
Br
N
N
AcO O O ii,iii
N
HN H2N
N
N
AcO O
i) Hg(CN)2-HMDS. ii) NH3. iii) adenosine-deaminase.
FIGURE 4.68. Acyclovir synthesis.
Cl NH2
N
Cl O
NH2
N
EtO
+
Cl
N
P
NH2
i
N
NH
O
O EtO
EtO
P
O
EtO
Cl
NH 2 N
N
N
N iii,iv
ii
N
N
N
O EtO EtO
P
O O
HO
P
O
HO
i) Et3N, EtOH, reflux. ii) diethoxymethyl acetate, 120oC. iii) NH3. iv) TMSBr, MeCN.
FIGURE 4.69. Synthesis of phosphonate acyclic adenine PMEA.
N
4.5. Thionucleosides
233
Cl Cl
N
N BnO
N
N
O
Cl
i
+
N H
N
H2 N
H2 N
N
N BnO
O
OBn
OBn O O
N
HN N
HN
ii
iii
H2 N N
N
H2 N BnO
N
N HO
O
O OH OBn DHPG
i) HMDS. ii) NaOMe, HSCH2CH 2OH. iii) H2, Pd-C
FIGURE 4.70. Synthesis of antiviral acyclic nucleoside DHPG. O N
HN AcHN
i,ii +
AcO
N H
N
OAc OCH2OAc
O N
N
HN
+
N
N
H2N HO
NH
N HO
O
NH2
N
O
O
OH OH DHPG i) EtSO3H, 155-160oC. ii) MeONa/MeOH
FIGURE 4.71. Alternative synthesis of DHPG.
NH2
NH.HCl
CN
N
HO
N N
N
O
N
HO
S
S HO
OH OH
OH
Thiotoyocamycin
Thioarabinofuranosylcytosine
Leukemia growth inhibitor
KB cell growth inhibitor
O
O N
N
N
N
H2 N HO
CH3
HN N
O HO
S
S
OH
OH
Thiothymidine
2'-Deoxy thioguanosine
Carcinoma growth inhibitor
Antiviral against HBV and HCMV
FIGURE 4.72. Some active N-thionucleosides. HO
S
B
HO
S
B
HO
B
HO
S OH OH
B
S
OH N-Isothionucleosides N-Thionucleosides
S
B
HO
S
B
HO
B
O
HO
O
HO S OH OH
S
OH
N-L-Thionucleosides
N-Thiooxonucleosides
FIGURE 4.73. Classification of N-thionucleosides.
B
4.5. Thionucleosides FIGURE 4.74. Early synthesis of thioribofuranosyl derivatives.
AcO
O OMe
S
235
OAc
i
BzS OH OH
OAc OAc
AcO
O OMe
S
OAc
i
OBz
OBz
BzS OBz
OBz
i) Ac2O/AcOH, conc. H 2SO4, 97%
earliest methods for preparing thioribosyl acetates was described by Reinst et al.122,123 involving as key steps the conversion of the 4-thiobenzoyl pyranoside into the thioribofuranosyl acetate (Figure 4.74). A short time later, another report introduced the use of sodium in liquid ammonia followed by benzoylation to yield tribenzoylated thioribofuranoside as a mixture of anomers (α:β, 1:3) (Figure 4.75).124 The thioribosyl derivative benzyl 3,5-di-O-benzyl-2-deoxy-1,4-dithio-Derythro-pentofuranoside has been prepared and used as glycosyl donor in various thionucleoside synthesis.125,126,127 The synthesis started from 2-deoxy-ribose, which was transformed to the methylbenzyl derivative by following a standard procedure and then treated with benzylmercaptan in acid to produce the dithiobenzylated derivative. The next step was to invert the hydroxyl group at 4position by using the Mitsunobu protocol to generate the intermediate with the desired stereochemistry. Finally, tosyl protection and NaI-BaCO3 treatment afforded the desired thiosugar (Figure 4.76).125
BzO
O
S
OBz
i,ii
BzS
OBz OBz
FIGURE 4.75. Preparation of benzoylated thioribofuranoside.
i) Na/aq. NH3. ii) BzCl/Py
OBz
236 HO
4. Nucleoside Mimetics HO
O OH
OMe
OH
O
ii
OMe
OH
BnS
iii
BnO
O
i
H
SBn
OBn
BnS
H
SBn
H
iv
H
H
v
OBn
OBn
OH
H
HO CH2OBn
BnS
SBn
OBn
BzO
CH2OBn
CH2OBn
SBn BnO
H
vi
BnS
H
O SBn
vii
OBn MsO
OBn CH2OBn
i) MeOH, HCl. ii) NaH, Bu4 NI, BnBr/THF. iii) BnSH, HCl. iv) PPh3 , PhCO 2 H, DEAD/THF. v) NaOMe/MeOH. vi) MsCl/Py. vii) NaI, BaCO3 , acetone
FIGURE 4.76. Synthesis pentofuranoside.
of
benzyl
3,5-di-O-benzyl-2-deoxy-1,4-dithio-Derythro-
4.5.2 Glycosidic Bond Formation The general methods for preparing N-thionucleosides are similar as for Nnucleosides. However, variations from slight to significant can be found especially in the preparation of four-ring thietanocin or thiolane analogs.126,127 Thus, according to a comprehensive review,118 the earliest reports for N-thionucleoside formation used chloromercury salt of purine and chlorine or benzoyl thioriboside as glycosyl donor, while more recently the silyl approach has been preferred (Figure 4.77).
4.5. Thionucleosides
237
NHBz N
N NHBz AcO
S Cl
+
N
N
AcO N
OAc OAc
N
N
i
S
N HgCl OAc OAc
i) toluene
Ref.122
Cl Cl
AcO
S Cl
+
N
N
N
N N
OAc OAc
N
N
N
AcO
S
HgCl
i) toluene, heat, 37%.
OAc OAc
Ref.128 FIGURE 4.77. Common glycosylation reactions for the preparation of thionucleosides.
4.5.3 Chloromercuration Promoted Coupling Reactions 4.5.3.1
Silylmediated Coupling Reactions
The preparation of potential anti-HIV N-Isothionucleosides was described starting from glucose. The key coupling reaction proceeds in low yield between the pyrimidine base and the mesyl tetrahydrothiophene derivative under potassium conditions (Figure 4.78).132 N-Thioxonucleosides are another class of N-thionucleosides tested as antiHIV agents. The conditions employed for performing the coupling reaction were TMSOTf as Lewis acid catalyst, affording a mixture of anomers (α:β, 1:2) in 64% (Figure 4.79).133 Thietane nucleoside was synthesized starting from the benzoyl thietane derivative, which prior to the coupling reaction was treated with peroxide to produce the
238
4. Nucleoside Mimetics NHR N
N NHR BzO
S OBz
N
N
+
N
N
i
BzO N
S
N HgCl
OBz
OBz i) TiCl4, EtCl2, heat.
Fig.129 NHOAc N N(TMS)OAc AcO
N
O
S OAc +
AcO
S
N
TMSO
OAc
AcO
i
N
OAc
AcO i) SnCl4, EtCl2, heat, 65%.
Ref.128 O R HN O TolO2CO
R
S OAc
TolO2CO
+
O TolO2CO
O
i
HN N H
TolO2CO i) a) HMDS, TMSCl, MeCN. b) TfOTMS.
Ref.130 FIGURE 4.77. (Continued)
N S
4.5. Thionucleosides
239 O
HN OTMS BnO
S SBn
N
O
i
N
+
BnO
S
N
TMSO BnO
BnO i) HgBr2, CdCO3, toluene.
Ref.121 Cl Cl TBDPSO
S
N
N OAc
N
N i
TBDPSO
S
N H
N
i) Et3AlCl.
Ref.131 FIGURE 4.77. (Continued) O O NH
BnO i
NH
+
N
BnO S
OMs
i) K2CO 3, DMSO, ∆, 15%
N H
N
N
+
O S
FIGURE 4.78. Preparation of N-Isothionucleoside.
O
240
4. Nucleoside Mimetics
O OAc TBDPSO
O
NHAc
NHAc N
TBDPSO
N
i
S
+
S
N
OTMS
N
N
O
+
O
O TBDPSO
N
S
NHAc
i) TMSOTf, CH2Cl2, 64%
FIGURE 4.79. Preparation of N-thioxonucleosides. O
O NH
NH
O BzO
S
BzO
i
N H
S
O
O BzO
N
O
S
ii
OBz
OBz
OBz i) TMSOTf, Et3N, ZnI2, toluene, 30 %.
FIGURE 4.80. Synthesis of thymidine thietane nucleoside. OTMS O N TBDMSO
NH S
N
OTMS TBDMSO
i
N
O
S
TBDMSO TBDMSO
SePh
i) PhSeCl 88 %.
FIGURE 4.81. Synthesis β-4 -thionucleosides based on electrophilic glycosidation of 4thiofuranoid glycols.
References
241
O O HN AcHN
N
i
SCH2OAc
+
N Ac
N
HN
OBn
N
N
N
AcHN BnO
OBn
+ 7 isomer
S
OBn
O
O N
HN ii
N
HN iii
AcHN AcO
N
N
H 2N
S
OAc
HO
N
N S
OH
i) (p-NO2C6H4)2P(O)OH. ii) (C 2H5)O-BF 3, Ac2O. iii) NH 3.
FIGURE 4.82. Synthesis of thio analog of DHPG.
sulfoxide derivative. Then under Lewis acid conditions a Pummerer rearrangement process takes place to produce in the presence of thymine the expected thietane nucleoside (Figure 4.80).127 More recently the stereoselective synthesis β-4 -thionucleosides based on electrophilic glycosilation of 4-thiofuranoid glycals was described. Thus, the condensation of TBDMS-4-thioglycal with silylated uracil in the presence of PhSeCl as electrophile furnished thionucleosides in 88% as a mixture of anomers (α:β; 1:4) (Figure 4.81).134 The thio analog of antiviral DHPG with comparable activity to DHPG against HSV1 and human cytomegalovirus was synthesized according to the figure shown below (Figure 4.82).110
References 1. 2. 3. 4.
H. Mitsuya, R. Yarchoan, and S. Broder, Science, 249, 1533 (1990). D.M. Huryn and M. Okabe, Chem. Rev., 92, 1745 (1992). H.Mitsuya and S. Broder, S. Proc. Natl. Acad. Sci. USA, 83, 1911 (1986). C. Simons, Nucleoside Mimetics, Ed. Gordon and Breach Science Publishers, (2001).
242
4. Nucleoside Mimetics
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5 C-Glycosides
These types of glycosides have attracted much attention, considering that many of them have demonstrated their effectiveness as therapeutic agents. The increasing significance of C-glycosides is that the conformational differences compared to O- or N -glycosides are minimal and that they are resistant to enzymatic or acidic hydrolysis since the anomeric center has been transformed from acetal to ether.1 A glycoside is defined as C-glycoside when what it is suppose to be the anomeric carbon of a sugar is interconnected to the aglycon, generating a new C-C bond. According to Levy and Tang2 the term C-glycoside describes those structures in which a common structural motifs the presence of carbon functionality at what would otherwise be the anomeric position of a sugar or derivative. Structurally C-glycosides can be constituted by aliphatic, or aromatic aglycon, and the sugar can be pyranose or furanose. A variety of natural product C-glycosides has been described. Examples of C-glycosides isolated from different plant genus and characterized spectroscopically are: Carminic acid, Aloin, Scoparin, Saponarin, and more recently Cucumerins (flavonoid phytoalexins)3 and C-glucosylxanthones4 and complex benzoquinone Altromycin B5 among others (Figure 5.1). Moreover, much effort and creativity have been devoted to the preparation of complex C-glycosides with potent antibiotics activity. That is the case of Aurodox6 , Lasalocid A,7 Herbicidin,8 and the hyperfunctionalized molecules Spongistatin9 and Palytoxin10 (Figure 5.2).
5.1 Synthetic Approaches for the Preparation of C-Glycosides Accordinng to comprehensive studies,2,11,12,13 the general strategies for C-glycosides can be overviewed as follows: r r r r
Electrophilic glycosyl donors Concerted reactions Wittig aproximation Palladium mediated reactions 247
OH
OH
O
OH
HO O
OH
O
CH3
OH COOH
HO
OH O
OH HO
OH OH
HO
OH
O OH Aloin
Carminic acid OH
OH
OH HO
HO
OH
O O
OH
HO
O
O
HO O
OH O
OCH3 HO
OH OH
O
OH
HO
O
OH
Saponarin
Scoparin
OH H3C
OH
HO
HO
O
OH
O O
OH
HO
O
OH
HO OH
O
OH
HO
O
OH
HO OH
OH
C-Glucosylxanthones
Cucumerin B
CH3
HO H3CO O
O OH
OH
H3CO2C CH3 O O
O
OH
O
O (H3C)2N
O CH3
H3C O
CH3
Altromycin B
FIGURE 5.1. Some naturally ocurring C-glycosides.
OCH3
OH CH3
5.1. Synthetic Approaches for the Preparation of C-Glycosides
Me Me
OH
OMe
H N
249
O
CH3 N
O
OH
O
O OH
O OH OH Aurodox CO2H
Me
Me
HO OH
CH2OH
O
O
Me O OH Me
Et
Lasalocid A O OH O
O
OH
OH
OH
HO OH
OH
O
H2N
OH
OH Me
HO
OH OH
OH
OH OH
OH HO
R
OH OH
OH
O
OH
HO
CH3 H3C
O OH
HO OH O
OH
O O
HO
OH
Me
OH
Me OH O OH
OH HO
OH
OH
OH OH
FIGURE 5.2. Complex C-glycoside antibiotics.
250
5. C-Glycosides OH
Me
OH
Me
O
R=
O N H
OH
N H
OH
Me Palytoxin
O HO OAc
OMe
O
O
O
O
AcO
HO O
O
HO
O
OH
OH
O Cl
OH OH
Spongistatin 1
FIGURE 5.2. (continued)
r r r r r r r r
Mitsunobu reaction Nucleophilic sugars or anomeric anions intermediates. Cross-metathesis reaction Samarium promoted reaction Ramberg-B¨acklund reaction Free radical approaches Exoglycals The tether approach
5.1.1 Electrophilic Glycosyl Donors 5.1.1.1
Glycosyl Donors Bearing Good Leaving Groups
A general approach for the C-glycosidic bond formation is based on nucleophilic carbon addition on the electrophilic center of a glycosyl donor. The most extensively used glycosyl donors divided in four main groups (good leaving groups, sugar lactones, glycals, and 1,2 anhydrosugars) are used as electrophilic donors
5.1. Synthetic Approaches for the Preparation of C-Glycosides O
O
R-M
251
R
PO
PO X P = protecting group M = Li, MgBr,
SnBu3
X = leaving group (I, Cl, Br, imidate, acetate and Lewis acid)
to generate C-glycosidic bonds when reacted with organocuprates, organotin, organozinc, cyanide, allylic Grignard, vinyl silyl reagents, and activated aromatic compounds. among others.11 Some of the reactions described that have been used for preparing useful intermediates or C-glycosides are shown in Figure 5.3. It is worth mentioning that for aryl C-glycosylations, there is a dependence on the electron density of the aromatic ring and the protecting groups at the glycosyl moiety.15 Moreover, depending on the reaction conditions, there is a competing parallel process that ultimately will drive the reaction either to the O- or to the C-glycoside formation. This affirmation was demonstrated in the preparation of C- and O-flavonoid glycosides by Oyama et al., which treated glycosyl fluoride with flavan under Lewis acid conditions. It was observed that BF3 .ET2 O and 2,6di-tert-butyl-4-methyl pyridine (DTBMP) resulted predominantly in the formation of the 5-O-β-glycoside, while if the reaction is carried out only with BF3 -Et2 O, the C-glycoside is obtained (Figure 5.4). 5.1.1.2
Other Electrophilic Glycosyl Donors
Additionally, the introduction of other electrophilic centers at the anometic position has extended the possibilities for preparation of C-glycosides by using electrophilic sugars. Some of these electrophilic sugars are lactols, anomeric esters, glycals, anhydrides, and lactones. O
OR
O
O PO
PO
Lewis acid R = TMS
R-M
O
O R
PO
PO
Lewis acid
OH
O R = TMS
PO
O
Nucleophile
O
Lewis acid
O
hydride
Nu
PO OH
O PO
Nu
OR2
OR2 RMgBr
O
R2O R 2O
O
R 2O
R
R2O
OR1
OR2
R 2O
OR1
Br
O
R2O
+
OR1 R
R1 = R2 = Bn, Me, silyl; α -selectivity
R = allyl, vinyl, benzyl, alkynyl; α -selectivity
R1 = Ac, or Bz, R2 = Bn, Me, silyl; β-selectivity
CO2Et R2
R2
OBn CO2Et
O
R1 BnO
OBn
O
R1 BnO
NaHMDS 5-crown-15
I
R2
OBn
OBn EtO2C
OBn CO2Et
O
R1 BnO
+
CO2Et OBn
CO2Et
R1 = OBn, R2 = H R1 = H, R2 = OBn
Ref.14 OBn
OBn
OBn O
O
OC(NH)CCl3
OBn
CH2NH2
LiAlH4
TMSCN
BnO
O
CN
BnO
BnO
OBn
OBn
OBn OBn
OBn
OBn
OBn O
BnO
OC(NH)CCl3
OBn
O
TMS ZnCl2 BnO
OBn
OBn
OBn OMe
OBn
OMe
OBn O
OC(NH)CCl3
O
OMe
OMe BnO
OBn OBn
BnO
OBn OBn
FIGURE 5.3. Preparation of C-glycosides or intermediates from electrophilic glycosyl donor with good leaving groups.
5.1. Synthetic Approaches for the Preparation of C-Glycosides
OBn
OBn
O + BnO
BnO
OBn
O
O
i
NH
O
253
BnO BnO
O
OBn
CCl3
i) ZnCl2.
OBn
OBn
OBn O
O
OAc
O
CN
CN
TMSCN +
BnO
BnO
OBn
40:50 OSiR3
OAc
O
OBn OBn
OBn
OBn AcO
BnO
OBn
OSiR3
AcO
OAc
AcO
O
O
i
Et
O
O
Et
OAc
AcO
O
i) SnCl4.
FIGURE 5.3. (continued) OAc
OAc O
H3 CO
OAc O
AcO AcO AcO i
OH
O
H3 CO F
AcO AcO AcO
O OH
OAc
+
O
H3CO
C- vs Oglycoside i) BF3-Et2O (4 equiv.) 1 h
94/6
i) BF3-Et2O (4 equiv.), DTBMP 1 h
8/92
AcO AcO AcO
O
OAc
O
OAc
FIGURE 5.4. C-glycosylations involving glycosyl donors with leaving group.
254
5. C-Glycosides OBn
OBn O
O
1) Me 2CuLi
Me
O 2) Ac2O/Py
BnO
BnO OBn
OAc OBn 60 %
OBn
OBn O
O
O
OH
MgBr
BnO
OBn
BnO
OBn
OBn
OBn
OBn
OBn
OBn O
O
O
RLi
Et3SiH BF3-Et2O
R
O
R
OH BnO
BnO
OBn
BnO
OBn
OBn
R = Me, alkynyl
16
Ref.
OMgBr
HO
O AcO
i +
O AcO
t-Bu
AcO OAc
AcO t-Bu
i ) ultrasound
FIGURE 5.5. C-glycoside formation with electrophilic sugars.
Some of the reactions carried out for preparing C-glycoside intermediates involving these alternative glycosyl donors are shown in Figure 5.5. In 1,2anhydrosugars the stereoselectivity is 1,2-trans type and involves a typical SN 2 process. On the other hand, glycals exhibit high stereoselectivity, and in glycosyl acetates the stereocontrol relies on the electronic and steric properties of the nucleophiles.
5.1. Synthetic Approaches for the Preparation of C-Glycosides
255 OMOM
OH OMOM
Me O O BnO
O
Me
CO2H i,ii,iii
CO2H
Me
CO2Me
O
BnO Me
HO OH
O
CH2OH
O
Me O OH i) (COCl)2, ii) n-BuLi. iii) LDA
Me
Et
FIGURE 5.6. Synthesis of Lasalocid A.
5.1.2 Concerted Reaction and Ring Formation This type of reactions includes sigmatropic rearrangements and cycloadition transformations. As an example of the applicability of the sigmatropic rearrangment for preparation o C-glycosydes, Ireland7 reported the synthesis of Lasalocid A, consisting in the coupling of acid derivative with protected glycal as a result of enolate addition and Claisen rearrangement. Series of transformation of this precursor will give place to Lasalocid A (Figure 5.6). To exemplify the effectiveness of cycloadditions for preparation of C-glycosides, Schmidt et al.17 prepared p-methoxyphenyl 2,3,4,6-tetraacetyl C-glucopyranose, by following a Diels-Alder approach. The reaction between heterodiene and dienophile produced cycloadduct that was successively transformed to give the desired product (Figure 5.7). Protected monosaccharide is reacted with Wittig ilide to produce a ring opening unsaturated intermediate, which was cyclized to produce a mixture of α,β C-glycosides. The α form could be converted to the β form under sodium methoxide conditions (Figure 5.8).18 Cation-mediated cyclization reactions of silyl enols ether-containing thioglycosides give bicyclic ketotetrahydrofurans. Treatment with sodium amalgam in buffered methanol yields the expected dihydropyran, which was transformed to the diol intermediate, and after separation converted to the bis-acetonides (Figure 5.9).19 Ring closure of polyalcohol has been proposed as a suitable strategy for preparing C-glycosides.20 Condensation between iodine pyranoside intermediate with
256
5. C-Glycosides OBn
BnO SPh PhS
O
OMe
+
O AcO AcO OMe OMe
OAc O
AcO AcO
OAc
FIGURE 5.7. The Diels-Alder reaction for C-glycoside formation. O O HO
H3C
i
O
O
OH ii
H3C
O O HO
OH
O
H 3C
OH
CO2Me HO OH
O
CO2Me
H3C
+
O O HO
OH
O OH
CO2Me
iii i) Ph2P=CHCO2Me. ii) KOH/MeOH. iii) MeONa/MeOH.
FIGURE 5.8. Wittig reaction for C-glycoside formation.
an aldohexose will result in the condensation product which undergoes ciclyzation to give the mixture of C-disaccharides shown in Figure 5.10.
5.1.3 Palladium-Mediated Reactions Heck-type reactions have been successfully assayed for preparing interesting C-glycosides. Such is the case of Vineomicinone B2 prepared by palladium catalyzed condensation between TBS protected glycal with antracene derivative.21 Further transformations will generate C-glycoside Vineomcinone B2 (Figure 5.11). Other palladium-mediated coupling includes Stille (palladium-catalyzed vinyl substitution),22 and Suzuki cross-coupling reactions. 23
5.1.4 Mitsunobu Reaction A Mitsunobu reaction is an additional useful reaction for preparing C-glycosides (Figure 5.12). When tetra-O-methyl glucopyranose is reacted with 1-naphtol in the
5.1. Synthetic Approaches for the Preparation of C-Glycosides SO2Ph
SO2Ph
SO2Ph O
OH
O i
O
257
ii
O
SPy
SPy
O
Ph
OTBDPS
OTBDPS
OTBDPS Ph
SO2 Ph O v
iii,iv
OH
vi
O H
O H OTBDPS
OTBDPS
OH
OH
OH
OH
OH
OH +
OH
OH O
O H OTBDPS
H OH
OTBDPS
OH
i) PhCH=CHCH2Br, CH2Cl2, 50% aq. NaOH, r.t. ii) AgOSO2CF3, MS, CH2Cl2, r.t. then DBU. iii) O 3, CH2Cl2, –78oC, then PPh3, –78oC to r.t. iv) NaBH4, MeOH, 0oC. v) 6% Na(Hg), Na2HPO 4, MeOH, 0oC. vi) OsO4, NMO, 9:1 acetone-H2O, r.t.
FIGURE 5.9. Formation of tetrahydrofurans and application to the synthesis of 2-octulopyranosides.
presence of Mitsunobu conditons (diethylazidodicarboxylate and triphenylphosphine), the resulting product is the O-glycoside, which is rearranged with BF3 Et2 O to the corresponding C-glycoside.24
5.1.5 Nucleophilic Sugars Anomeric carbons are considered electrophilic sites by nature; however, it is possible to invert this reactivity by using metallic bases. The resulting carbanion character is known as umpolung reactivity and allows the species to behave as nucleophiles. A variety of glycosyl donors have been converted to lithium or stannane glycosyl anions (Figure 5.13).11
258
5. C-Glycosides CHO
I
OR
OR
OR i
O
+
RO
OR OR
OR OR
O
RO
RO
OR
OR
OR
OR
OR
RO
OR
OTBDMS OR OR
OR
O RO RO
RO
O
OR
OR +
RO
OR OR
O
O RO OR
OR OR
RO i) n-BuLi, THF
FIGURE 5.10. C-disaccharide formation from aldohexoses.
OH RO OH
O
Me
Me
OR CO2Me
O
i) Pd(Ph3)2Cl2/DIBAL/THF
OH
OH RO OH
O
Me
Me
OR CO2Me
i) Pd(Ph3)2Cl2/DIBAL/THF
O
OH
FIGURE 5.11. Synthesis of Vineomicinone B2 methyl esther.
5.1. Synthetic Approaches for the Preparation of C-Glycosides
259
OH OMe MeO MeO
O
OMe
i
OH +
O
MeO MeO
OMe
O
OMe OMe ii
MeO MeO
O OMe
OH
i) DEAD, Ph3P. ii) BF3.Et 2O.
FIGURE 5.12. Mitsunobu reaction for aromatic C-glycoside formation.
By using this possibility, the synthesis of the C-glycosyl asparagine analog has been completed by Kessler and coworkers.25 The transformation of the stannane to the lithium donor was followed by the coupling reaction with the aldehyde glutamic acid derivative to provide the β-D-linked C-glycoside. Removal of Boc protecting group and dehydroxylation reaction under Barton-McCombie condition provided the target molecule (Figure 5.14). Another accomplishment following this umpolung strategy was the preparation of the aromatic C-glycoside shown in Figure 5.15. Hence, lithium glycal (obtained from glycal treatment with lithium diisopropylamide) was reacted with quinolic ketal to yield addition product, which was transformed to the aromatic C-glycal.26,12 Aldol condensations between glycosyl donors containing active methylene carbons with glycosyl acceptors have been also proposed as suitable approaches for preparing C-disaccharides. Martin et al,27 described a procedure for preparing
BnO
BnO BnO BnO
i
BnO BnO
O OLi
O
Li
OH Cl
ii
BnO BnO BnO
O
SnBu3
OH i) BuLi-LiN. ii) Bu 3SnLi.
FIGURE 5.13. Preparation of lithium and stannane glycosyl anions.
260
5. C-Glycosides OBn O
BnO BnO
OBn i
SnBu3
O
BnO BnO
NHAc
Li
NHLi
NBoc2 OBn OH OHC
CO2Me 73%
O
BnO BnO
NBoc2
NHAc
CO2Me
OBn OH ii 67%
BnO BnO
O
NHAc
NBoc2 CO2Me
i) a) MeLi. b) BuLi. ii) a) MgClO4. b) deoxygenation.
FIGURE 5.14. Preparation of C-analogs of glycosyl asparagines from anionic glycosyl donors.
(1,6)- and (1,1)-linked C-disaccharides based on the nitroaldol condensation between the glycosylnitromethane peracetate with the galactose-derived aldehyde to provide after dehydration, reduction of the double bond, and and radical denitration the desired C-disaccharide (Figure 5.16).
5.1.6 Cross-Metathesis Reaction Cross-metathesis reaction is an emerging methodology for C-C bond formation. The air stable Grubbs ruthenium complex28 has become an attractive catalyst for the olefin cross methatesis reactions and has been also applied successfully for the preparation of pseudosaccharides. The coupling reaction between C-allyl α-D-galactopyranoside with 4-acetoxystyrene led to the formation of the crossmetathesis product (Figure 5.17).29
5.1.7 Samarium Promoted Reaction The synthesis of a C-glycoside analog of α-1,3-mannobiose has been reported via SmI2 -promoted C-glycosilation. The general approach is based on the Barbier-type
5.1. Synthetic Approaches for the Preparation of C-Glycosides MeO MeO Me
O
261
OMe
OMe
Li +
Me
O OH
TBSO OTBS
O
TBSO OTBS
HO
OMe OMe
i
Me
O
Me
ii
O
OH TBSO
TBSO
OTBS
OTBS i) DIBAL/CH2Cl2. ii) POCl3/Py.
FIGURE 5.15. C-glycoside formation using lithium glycal nucleophilic donor. CHO OAc O
O
O O
+
O
AcO AcO
OH O
i,ii
HO HO
NO2
OAc
OH
O
OH
OH HO
O
OH
i) KF, MeCN, DCH-18-crown-6. ii) a) Ac2O, Py, CHCl3. b) NaBH4, MeOH, CH2Cl2, 0oC. c) Bu3SnH, AlBN, reflux. d) NaOMe, MeOH. e) H3+O.
FIGURE 5.16. C-disaccharide formation with glycosyl donors containing active methylene carbons. OAc
Ph
Ru
Cl
OAc OAc O AcO
PCy3 Cl
PCy3
+
OAc OAc O AcO
CH2Cl2, reflux
OAc
OAc
OAc
FIGURE 5.17. Cross-metathesis reaction for C-glycoside formation.
262
BnO
5. C-Glycosides
OBn O
OBn O
AcO
i
BnO BnO
+ BnO
BnO BnO
SO2(2-Pyr)
OMe
O
OBn O
BnO
OAc OBn O
BnO OMe
(Imid)SCO BnO ii
BnO BnO
OBn O
OAc OBn O
BnO OMe
i) a) SmI2 (2.8 eq), THF, 20oC. b) (Imid)2CS (15 eq), CH3CN, reflux, 35% ii) F5PhOH, Ph3SnH, AlBN, toluene, reflux, 65%.
O
O
SO2Ph
BnO
OMe
HO O
BnO
O
O
BnO
OMe
O
OBn
i
Si OBn
OBn
BnO
OBn
OH
OBn
OBn
i) SmI2, PhH, HMPA, 60oC. b) aq. HF.
FIGURE 5.18. Samarium promoted C-glycosylation.
coupling30 and involves the use of pyridyl sulfone glycosyl donor with a sugar aldehyde in the presence of SmI2 as catalyst. This procedure has been exploited successfully for the preparation of disaccharides under the tether approach (Figure 5.18).31
5.1.8 The Ramberg-B¨acklund Reaction This novel procedure introduced by Franck et al. is becoming a practical and versatile approach for the preparation of biologically active C-glycosides such as aromatic,5 aminoacids,32,33 or glycerolipids.34 The reaction sequence for C-glycoside formation consists of the initial S-glycoside formation, transformation to the sulfone derivative, Ramberg-B¨acklund rearrangement involving sulfone extrusion, and hydrogenolysis (Figure 5.19). Another C-disaccharide was prepared by transformation of benzylated exoglycal to the iodide derivative, which in turn was coupled with the sulfur glycosyl donor. Further transformation to the sulfone and Ramberg-B¨acklund rearrangement produced the unsaturated disaccharide, which was finally reduced under Perlman conditions to provide disaccharide in 70% yield (Figure 5.20).35
5.1. Synthetic Approaches for the Preparation of C-Glycosides
263
RO
RO O
RO RO
i
S
R
OR
ii
O
RO RO
S R O O
OR
RO
RO O
RO RO
iii
OR
O
RO RO
R
R
OR
H
i) mCPBA, Na 2HPO 4/CH 2Cl2, 77%. ii) KOH/Al2O 3, CBrF2CBrF2/tBuOH, 50oC. iii) H 2, Pd(OH) 2/EtOAc.
FIGURE 5.19. The Ramberg-B¨acklund approach for C-glycoside formation.
BnO
O
BnO BnO
I ii
OBn
OBn
BnO
BnO
BnO BnO BnO
O
SH OBn
O
BnO BnO
i
O
BnO BnO
BnO
BnO
OBn
BnO Z
O
iii
OBn
BnO
O
O
BnO BnO
OBn
OBn
BnO
OBn
OBn
HO iv
HO HO HO
HO O
OH O
OH
OH i)a) 9-BBN. b) Ph3 P, I2, Imid. 81%. ii) K 2CO 3, then oxidation. iii) KOH, CCl4 , tBuOH, 60o C. iv) H2, Pd(OH) 2, 70%.
FIGURE 5.20. Synthesis of C-isotrehalose.
5.1.9 Free Radical Approach This approach is based on the generation of free radical at the anomeric carbon by using glycosyl donors, which are subjected to stannous treatment of free radical conditions that in turn will react with mainly exoglycals to produce a C-glycosidic linkage. The general methods leading to anomeric radicals formation are summarized in Figure 5.21:36
264
5. C-Glycosides O
O
X RO m
RO m
n
a) Bu3SnH (Hg-hν or
n
∆)
X = NO2, I, Br, Cl, SeAr, SAr b) Bu3SnSnBu3H (Hg-hν) X = NO2, I, Br, Cl, SeAr, SAr
c) (C2H5)3B (air) or N-acetoxy-2-thiopyridone (W-hν) X = TeAr d) Ester of N-Hydroxy-2-thiopyridone (W-hν) X = COOH e) (Diacyloxyiodo)arenes (Hg-hν or ∆) X = COOH f) Hg-hν X = COBu-t etc g) W-hν X = Co(dmgH)2Py
FIGURE 5.21. General methods leading to anomeric radicals formation.
The coupling reaction between acetobromoglucose and the unsaturated lactone shown in Figure 5.22 will result in the C-disaccharide formation, where a free radical mechanism promoted by a mixture of AlBN-Bu3 SnH is involved.37 Anomer radicals may also generate rearranged products as a result of 1,2migration particularly for the case of acetoxy and phosphate groups. This feature has been exploited successfully for preparing 2-deoxy sugars from commercially available sugars Figure 5.23.38 OAc
HO
OAc
OH
HO
OH
O i
Br +
AcO
AcO O
AcO
OAc
O
O AcO
i) AlBN, Bu3SnH.
FIGURE 5.22. Free radical coupling reaction.
OAc O
5.1. Synthetic Approaches for the Preparation of C-Glycosides OR
OR
O
O
RO
X
RO
265
RO
OR
OR
RO 70-92 %
X = Br R = OAc, OBz, OPO3(Ph)2
FIGURE 5.23. Synthesis of 2-deoxy sugars by reductive 1,2-migration of glycosyl bromide.
5.1.10 Exoglycals Exoglycals have been described as another possibility for preparing C-glycosyl derivatives. The term exo-glycal is given to those unsaturated sugars with exocyclic double bonds. The most representative of these compounds are 1,2- and 5-6unsaturated sugars (Figure 5.24).39 They were first prepared by reacting lactones with ethyl isocyanoacetate and subsequent hydrogenolysis40,41 (Figure5.25). This reaction has not been exploited extensively due to sugar oxazole formation. More recently two methods were reported for direct olefination of lactones. One is based on phosphorous Wittig-type reaction42 and the other by direct methylenation using the Tebbe reagent43 (Figure 5.26). Alternative methods for the preparation of exoglycals includes β-elimination of halides44,45 dehydration, Grignard nucleophilic addition, sulfone extrusion (Ramberg-B¨acklunnd olefination),46 and tosyl hydrazones (Bamford-Stevens conditions)47 among others (Figure 5.27). The synthesis of several C-disaccharides by using exoglycals has been described. Such is the case of the preparation of C-disaccharide by reaction of two molecules of the C-methylene intermediate under Lewis acid conditions (Figure 5.28). The reaction was proposed to proceed via oxonium cation.48 A 1,3-dipolar cycloaddition of exomethylene sugar with glycosyl nitrone has been proposed as an approach for the formation of amino-C-ketosyl disaccharides (Figure 5.29).49
OR O
R
O OR
FIGURE 5.24. 1,2- and 5,6- unsaturated sugars.
R
266
5. C-Glycosides O
O O
O
O
ii
O
NHCHO
O
O
COOEt
O
i
O
O
O COOEt
O O
NHCHO O
O
i) a) EtOOCCH 2NC, KH. b) AcOH. ii) a) H 2, Pd/C b) H 2O.
FIGURE 5.25. First synthesis of 1,2-unsaturated sugar.
Cl
O
R
O
O
R
i
Cl O
O
O
O
i) P(NMe2 )3 , CCl4 , −30-0oC.
O
TBSO
O
Al
+
O
O
H2 C
Me Me
O
TBSO Cp
i
Ti Cl
Cp
i) THF, Tol, −40oC.
FIGURE 5.26. Early methods for preparation of exoglycals.
O
O
5.1. Synthetic Approaches for the Preparation of C-Glycosides
267
OAc OAc
OAc OAc AgF, Py
O CH2I
AcO
O AcO OAc
OAc
OAc OAc
OAc OAc Br
O
AgF, Py
O AcO
AcO
CN
OAc
OAc OAc O
O
CN
OAc
OAc OAc
1) NaBH 4 2) TsCl, Py
O AcO
AcO
OAc
OAc
Z isomer
BnO
BnO O
BnO BnO R = H, Ph
O S OBn O
i
O
BnO BnO
R
R
OBn R = H (72%) R = Ph Z/E 88:12 (56%)
i) KOH, CCl4, tBuOH, H 2O.
AcO
AcO AcO AcO
O CHNNHTs NHPht
i
AcO AcO
O NHPht
CH2
NaH, dioxane, reflux 74%.
FIGURE 5.27. Alternative methods for the preparation of exoglycals.
5.1.11 The Tether Approach Various approaches for C-glycoside construction are comprehensively reviewed, focusing mainly on the methylene formation.50 The strategies presented are based on the concept that a nucleophilic anomeric donor is condensed with an exomethylene sugar to produce a C-disaccharide linkage.51 According to this strategy methyl
268
5. C-Glycosides BnO O
BnO BnO
BnO BnO BnO
CH3
i
O
OBn BnO
OBn
O
BnO BnO
OH
OBn
BF3.Et2O, CH 3CN, 66%.
FIGURE 5.28. Preparation of C-disaccharide from exoglycals.
R3 R4 BnO
Me
OBn R1 O R2
+ +
BnO BnO
N
i
R4 BnO
O OBn
Glc, Gal, Man
R3
O−
OBn R1 O
O NMe
R2
OMe
O BnO
OBn OBn OMe
i) PhCH3 , reflux.
FIGURE 5.29. Dipolar cycloaddition of exoglycals.
OH
OBn BnO BnO
O O
OBn
SePh Si
O
i
HO HO
O OH OH
O
OBn
O HO
OMe
OH OMe
i) a) Bu3SnH, AlBN, PhH, 60oC. b) HF, THF. c) H2,Pd/C, MeOH, AcOEt.
FIGURE 5.30. C-glycoside construction under the tether approach.
α-C-isomaltoside was prepared from the silaketal connected precursor as shown in Figure 5.30. The tether approach considers the preliminary formation of a temporary attachment usually involving a silyl protecting group, as tether which is cleaved after formation of the desired C-C bond. The general conditions involve the use of selenoglucopyranosides52 or phenylsulfoxides37,53 as glycosyl donors. An important application of this methodology can be seen in the preparation of O-C mixed sulfated trisaccharide (Figure 5.31).13
5.1. Synthetic Approaches for the Preparation of C-Glycosides O
Ph SePh OH +
O O
O
Ph
O
O
O
O
i
O
269
O
OH
O
OMe O
O
OMe
SePh Si
O
OBn O
Ph
O
O
ii
iii,iv
OH O O
BnO
OMe
O
OH
O
O
BzO
O
OBz
BzO
OBn
O
OBn
O
OBn O
O
OMe
OBn
O
HO
OBn
OH
OH
O
O
O
O
HO
vii, viii, ix
O
O
NaO 3SO OH
OH
OBn OMe O
O
vi
OBz
v
OH
O
O
BzO
OBz Br
O
OMe
OBz
BzO
HO
O
HO
OH OMe O
OBn
OH
HO OH
i) a) BuLi; Me2SiCl2 (4.4 equiv.), THF, −78oC to 20oC. b) imidazole, THF, r.t. ii) Bu3SnH (2 equiv.), AIBN, PhMe, 110oC, 17 h. then Bu4NF, THF, r.t., 60%. iii) BnBr, NaH, DMF, 100%. iv) NaBH 3CN, HCl, 70%. v) AgOTf, collidine, MS. 80%. vi) MeONa/MeOH, 97%. vii) Bu 2SnO, MeOH. viii) SO3/ Me3N, 70%, 3 steps. ix) H2, Pd/C, 100%.
FIGURE 5.31. Preparation of sulfated C-trisaccharide under the tether methodology.
270
5. C-Glycosides
References 1. P.S. Belica, and R.W. Franck, Tetrahedron Lett. 39, 8225 (1998). 2. D.E. Levy, and C. Tang, The Chemistry of C-Glycosides, Pergamon Press: Oxford (1995). 3. D.J. McNally, K.V. Wurms, C. Labb´e, S. Quideau, and R.R. Belanger, J. Nat. Prod. 66, 1280 (2003). 4. P.M. Pauletti, I. Castro-Gamboa, D.H. Siqueira-Silva, M.C. Marx-Young, D.M. Tomazela, M.N. Eberlin, V. da Silva-Bolzani, J. Nat. Prod. 66, 1384 (2003). 5. P. Pasetto and W. Franck, J. Org. Chem. 68, 8042 (2003). 6. R.E. Dolle and K.C. Niclolaou, J. Am. Chem. Soc. 107, 1691 (1985). 7. R.E. Ireland, R.C. Anderson, R. Badoub, B. Fitzsimmons, S. McGarvey, S. Thaissivongs, and C.S. Wicox, J. Am. Chem. Soc., 105, 1983 (1983). 8. F. Emery and P. Vogel, Tetrahedron Lett. 4209 (1993). 9. L. Paterson and L.E. Keown, Tetrahedron Lett. 38, 5727 (1997). 10. M.D. Lewis, J.K. Cha, and Y. Kishi, J. Am. Chem. Soc. 104, 4976 (1982). 11. Y. Du, R.J. Linhardt, and I. Vlahov, Tetrahedron 54, 9913 (1998). 12. (a) M.H.D. Postema, C-glycoside Synthesis; CRC Press: Boca Rat´on (1995); b) M.H.D. Postema Tetrahedron 48, 8545 (1992). 13. P. Sina¨y, Pure & Appl. Chem. 69, 459 (1997). 14. J. Gervay, and M.J. Hadd, J. Org. Chem. 62, 6961 (1997). 15. K. Oyama and T.J. Kondo, Org. Chem. 69, 5240 (2004). 16. E. Calzada, C.A. Clarke, C. Roussin-Bouchard, and R.H. Wightman, J. Chem. Soc. Perkin Trans 1, 717 (1995). 17. R.W. Schmidt, B. Frick, B. Haag-Zeino and S. Apparao, Tetrahedron Lett. 28, 4045 (1987). 18. J.M. Lancelin, J.R. Pougny, and P. Sina¨y, Carbohydr. Res. 136, 369 (1985). 19. D. Craig, M.W. Pennington, and P. Warner, Tetrahedron 55, 13495 (1999). 20. R.R. Schmidt and P. Shorma, Carbohydr. Res. 14, 1353 (1985). 21. M.A. Tius, J. Gomez-Galano, X. Gu, and J.H. Zaidi, J. Am. Chem. Soc. 113, 5775 (1991). 22. A. Abas, R.L. Beddoes, J.C. Conway, P. Quayle, and C.J. Urch, Synlett, 1264 (1995). 23. B.A. Johns, Y.T. Pan, A.D. Elbein, and C.R. Johnson, Carbohydr. Res. 136, 369 (1985). 24. T. Kometani, H. Kondo, and Y. Fujimori, Synthesis 1005 (1988). 25. F. Burkhart, M. Hoffmann, and H. Kessler, Angew. Chem. Int. Ed. Engl. 36, 1191 (1997). 26. K.A. Parker and C.A. Coburn, J. Am. Chem. Soc. 113, 8516 (1991). 27. O.R. Martin and W. Lai, J. Org. Chem. 58, 176 (1993). 28. (a) P. Schawab, M.B. France, J.W. Ziller, and R.H. Grubbs, Angew. Chem., Int, Ed. Engl. 34, 2039 (1995). (b) M.H.D Postema, J.L. Piper, and R.L. Betts, J. Org. Chem. 70, 829 (2005). 29. R. Roy, R. Dominique, and S.K. Das, J. Org. Chem. 64, 5408 (1999). 30. T. Maz´eas, J.M. Skrydstrup, and J.M. Beau, Angew. Chem, 107, 990 (1995). 31. S.L. Krintel, J. Jim´enez-Barbero, and T. Skrydstrup, Tetrahedron Lett., 40, 7565 (1999). 32. A. Dondoni and A. Marra, Chem. Rev. 100, 4395 (2000). 33. Y. Ohnishi and Y. Ichikawa, Bioorg. Med. Chem. Lett. 12, 997 (2002). 34. G. Yang, R.W. Franck, R. Bittman, P. Samadder, and G. Arthur, Org. Lett. 3, 197 (2001). 35. F.K. Griffin, D.E. Paterson, and R.J. Taylor, Angew. Chem., Int. Ed. 38, 2939 (1999). 36. H. Togo, W. He, and Y. Waki, and M. Yokohama, Synlett 700 (1998). 37. A. Chenede, E. Perrin, E.D. Rekai, and P. Sina¨y, Synlett 420 (1994).
References
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38. B. Giese, K.S. Gr¨oninger, T. Witzel, H.G. Korth, and R. Sustmann, Angew. Chem. Int. Ed. Engl., 26, 233 (1987). 39. C. Taillefumier and Y. Chapleur, Chem. Rev. 104, 263 (2004). 40. K. Bischofberger, R.H. Hall, and A.J. Jordaan, Chem. Soc. Chem. Commun. 806 (1975). 41. R.H. Hall, K. Bischofberger, S.J. Eitelman, and A.J. Jordaan, Chem. Soc. Perkin Trans. 1, 743 (1977). 42. Y. Chapleur J. Chem. Soc. Chem. Commun. 449 (1984). 43. C.S. Wilcox, G.W. Long, and H. Suh, Tetrahedron Lett. 25, 395 (1984). 44. M. Brockhaus and J. Lehmann, Carbohydr. Res. 53, 21 (1977). 45. S.J. Eitelman, R.H. Hall, and A.J. Jordaan, Chem. Soc., Chem. Commun. 923 (1976). 46. F.K. Griffin, D.E. Paterson, P.V. Murphy, and R.J.K. Taylor, Eur. J. Org. Chem. 1305 (2002). 47. M. Toth and L. Somsak, J. Chem. Soc., Perkin Trans. 1, 942 (2001). 48. L. Lay, F. Nicotra, L. Panza, G. Russo, E. Caneva, J. Org. Chem. 57, 1304 (1992). 49. X. Li, H. Takahasi, H. Ohtake, and S. Ikegami, Tetrahedron Lett, 45, 3981 (2004). 50. G. Casiraghi, F. Zanardi, G. Rassu, and P. Spanu, Chem. Rev. 95, 1677 (1995). 51. B. Vauzeilles, D. Cravo, J.-M. Mallet, and P. Sina¨y, Synlett, 522 (1993). 52. A.J. Fairbanks, E. Perrin, and P. Sina¨y, Synlett 679 (1996). 53. D.S.T. Mazeas, O. Doumeix, J.-M. Beau, Angew. Chem. Int. Ed. Engl. 33, 1383 (1994).
6 Glycoconjugates
Carbohydrates covalently attached to proteins and lipids produce three types of glycoconjugates: proteoglycans, glycoproteins, and glycolipids. Although in the first two cases the types of linkages are the same, chemically proteoglycans behave as polysaccharides and glycoproteins having much less carbohydrate content as proteins. The third important class of glycoconjugates, constituted by a carbohydrate residue covalently attached to a lipidic component, has been classified into four types depending on the lipidic nature: glycoglycerol, glycosyl polyisoprenol pyrophosphates, fatty acid esthers, and glycosphingolipids.1 The most common monosaccharides residues found in glycoconjugates are D-galactose, D-mannose, N-acetyl-D-glucosamine, N-acetyl-D-galactosamine, Lfucose, D-xylose, and sialic acids (Figure 6.1).
6.1 Biological Function and Structural Information Glycoproteins and glycolipids are major components of the outer surface of mammalian cells. The former have been implicated in several essential events such as immune defense, viral replication, cell-cell adhesion, inflammation and cell growth, while the latter in cell-cell recognition, growth, differentiation, and interaction with proteins of viral and bacterial pathogens. It is attributed to the hepatic Gal2 /GalNAc-binding receptor as the first recognition discovery of carbohydrates as biological signals.2 Subsequently, Man6-phosphate receptor for lysosomal enzymes and Man-receptor from alveolar macrophages were reported and investigated.3,4 In the cellular immune system, some specific glycoproteins are implicated in the folding, quality control, and assembly of peptide-loaded major histocompatibility complex antigens and the T cells receptor complex. Furthermore, the oligosaccharides linked to glycoproteins provide protease protection, ER-associated retrograde transport of misfolded proteins, loading of antigenic peptides into MHC I class I, and influence the range of antigenic peptides generated in the endosomal pathway for presentation by MHC class II.5 272
6.1. Biological Function and Structural Information OH OH
OH OH
OH OH O
O OH
HO
273
O OH
HO
HO HO
OH
OH
NHAc β-D-mannose
β-D-galactose
OH OH
N-acetyl-β-D-glucosamine
OH
OH O
O OH
HO
O
H 3C
OH
OH
HO OH
HO OH
NHAc
β-D-xylose
α-L-fucose
N-acetyl-β-D-galactosamine
OH
OH OH
HO
O H2 N
COOH
HO α-L-sialic acids
FIGURE 6.1. Monosaccharides residues of glycoproteins.
In addition, enveloped viruses such as human immunodeficiency virus (HIV) evades immune response by exploiting the host glycosylation machinery to protect potential antigenic epitopes.6 They also use the host secretory pathway to fold and assemble their often heavily glycosylated coat proteins. Another important fact to mention is that normal cells and tumor cells have evident differences in glycoprotein content on their cell membranes. Altered glycoproteins of the tumor membranes such as Thomsen-Friedenreich (T antigen) are tumor-associated antigen and belong to the class of O-glycoproteins.7−9
6.1.1 Classification of Glycocoproteins Based on the type of the glycosidic bond formed between the sugar and the protein residues, glycoproteins are divided in N - and O-glycans. The first type involved the glycosidic linkage between asparagine and N -acetylglucosamine and the second involves an O-glycosidic linkage between the sugar residue (fucose, galactose, N acetylgalactosamine, and N -acetylglucosamine) and the oxygen in the side chain serine, threonine, or hydroxyl lysine.
274
6. Glycoconjugates
It is known that N-linked glycans contain the pentasaccharide Manα1-6(Manα13)Manβ1-4GlcNAcβ1-4GlcNAc as a common core, and they have been classified into four main groups on the basis of the structure and the location of glycan residues added to the trimannosyl core: oligomannose, complex, hybrid, poly-Nacetylglucosamine (Figure 6.2).10 First type Manα1−2Manα1 6
Manα1
3
6 Manβ1−4GlcNAcβ1 4GlcNAc Asn 3
Manα1−2Manα1 Manα1−2Manα1 2 Manα1
Second type NeuNAcα2−6Galβ1−4GlcNAcβ1 NeuNAcα2−6Galβ1−4GlcNAcβ1 NeuNAcα2−6Galβ1−4GlcNAcβ1 NeuNAcα2−3Galβ1−4GlcNAcβ1 NeuNAcα2−6Galβ1−4GlcNAcβ1
Fucα1 GlcNAcβ1 6 4 Manα1 2 6 6 4 Manβ1−4GlcNAcβ1 4GlcNAc Asn 3 4 Manα1 2
Third type Manα1 6
Manα1
3 Manα1
6 Manβ1−4GlcNAcβ1 4GlcNAc Asn 3 6 4
NeuNAcα2-3Galβ1-4GlcNAcβ1
GlcNAcβ1
4 2 Manα1 GlcNAcβ1
Fucα1
Fourth type GlcNAcβ1
Fucα1
NeuNAcα2−3(Galβ1−4GlcNAcβ1-3)oGalβ1-4GlcNAcβ1 6
Manα1
2 6 4 6 Manβ1−4GlcNAcβ1 4GlcNAcβ1 Asn 3
NeuNAcα2−3(Galβ1−4GlcNAcβ1-3)mGalβ1-4GlcNAcβ1 NeuNAcα2−3(Galβ1−4GlcNAcβ1-3)nGalβ1-4GlcNAcβ1 4 2 Manα1 NeuNAcα2−6Galβ1-4GlcNAcβ1
FIGURE 6.2. The four groups of N-linked glycans.
6.1. Biological Function and Structural Information Core 1
GalNAcβ1−3GalNAcα
Core 2
GlcNAcβ1−6GalNAcα
Galβ1−4 GlcNAcβ1 Core 3 Galβ1−4 GlcNAcβ1
275
6 GalNAcα−Ser(Thr) 3
Galβ1−4GlcNAcβ1 Core 4 Galβ1−4GlcNAcβ1
6 Galβ1−4GlcNAcβ1−3GalNAcα−Ser(Thr) 3
Galβ1−4(GlcNAcβ1−3Galβ1−4)n-GlcNAcβ1 Core 5 Galβ1
6 GalNAcα−Ser(Thr) 3
Galβ1−4GlcNAcβ1 Core 6 Galβ1−3GlcNAcβ1
6 Galβ1−3GlcNAcβ1−3Galβ1−3GalNAcα-Ser(Thr) 3
FIGURE 6.3. Core structures in O-linked glycans.
O-glycans do not present common core structures and until now they have been classified in at least six groups according to different core structures (Figure 6.3).
6.1.2 Recognition Sites There are two main classes of glycosidic linkage depending on the type of glycosidic bond formed between the sugar residue and the protein: the O-linked glycans involving the amino acids serine, threonine, and hydroxyl lysine, and N -linked glycans involving the amino acid asparagine in the form of tripeptide with sequence AsnXSer (where X is any amino acid except proline). Thorough studies with sugar analogs indicate that presumably the most important of the substituents is the equatorial OH-group on carbon 3. Also important is the OH-group on carbon 4 which can be either axial or equatorial depending on the glycoprotein. Regarding C-2, there is certain tolerance; however, the size of the group should not be too large. Finally, C-6 and the anomeric carbon apparently do not play significant roles in the binding (Table 6.1).11
276
6. Glycoconjugates
TABLE 6.1. Sugar requirements for three different glycoproteins. Rat hepatic
Chicken hepatic
Detrimental
α ≈ β large substituents tolerated, negative group Enhancing
Tolerable
Eq. N-Ac enhance binding
Eq. N-Ac enhance binding
No effect by N-Ac
1
2
MBP-A
3
Eq. OH required
4
Axial OH required
Eq. OH required
5
Eq. OH required
Large subst. accepted
6.1.3 Structural Information of Glycoproteins A better understanding about the conformation of glycoproteins has been reached by using NMR, molecular dynamics (MD), and in some cases X-ray diffraction techniques. The high motion of oligosaccharides mainly across the glycosidic linkage (Figure 6.4) has limited the unambiguous conformational determinations in glycoproteins. However, the conformations from the MD simulations are in good agreement with the values from NMR studies. It has been observed that ω-angle prefers Gauche conformation by solvation effects with φ-angle largely determined by the anomeric effect, and the ψ-angle highly influenced by nonbonded interactions.12 The linkage between the sugar residue and the amino acid asparagine (N-linked glycans) is planar along the C1-NH-C=O glycosidic linkage and flexible along the CO-CH2 -CH- bonds (Figure 6.5). Based on the considerations that N-glycosidic linkages are rigid for the amide group and flexible for the side chain angles, the conformational motion of the glycoproteins depends on the flexibility of the asparagine side chain. This flexibility will have considerable effect on the volume occupied by the sugar and the shielding effects of the carbohydrate over the protein surface. OH O
HO HO HO
ω
O O
HO HO
ψ
HO
φ
OH O
O HO HO
OH
FIGURE 6.4. Angles of rotation of carbohydrates.
6.2. Carbohydrate Binding Proteins
FIGURE 6.5. Planarity of the Asn-GlcNAc glycosidic linkage.
OH O
HO
277
H N
HO NHAc
O
Hydrogen bond and van der Waals interactions showed for some cases stacked conformations, and distances across a carbohydrate residue (from O-1 to O-4) of ˚ and for the first three residues of the core of an N-linked oligosaccharide 5.4 A ˚ from head to tail.12 extend to approximately 16 A
6.2 Carbohydrate Binding Proteins Carbohydrate binding proteins are defined as those proteins that interact through noncovalent bonds with carbohydrates. Of particular interest are Lectins. which bind reversibly to mono- and oligosaccharides with high specificity, and are apparently devoid of catalytic activity.13 Carbohydrate binding proteins are widespread macromolecules found in virus, bacteria, plants, and animals and act as recognition determinants including clearance of glycoproteins from the circulatory system, control of intracellular traffic of glycoproteins, recruitment of leukocytes to inflammatory sites, adhesion of infectious agents to host cells, and cell interactions in the immune system in malignancy and metastasis.13 Depending on the affinity shown toward the type of monosaccharide, they can be classified in mannose, galactose/N-acetylgalactosamine, N-acetylglucosamine, L-fucose, and N-acetylneuraminic acid. Due to their high specificity, lectins specific for galactose do not recognize glucose or mannose, nor N-acetylglucosamine with N-acetylgalactosamine, but mannose-specific animals lectins do recognize fucose. Lectins also exhibit high specificity for di-, tri-, and tetrasacharides and some interact only with oligosaccharides. Moreover, different lectins specific for the same oligosaccharide may recognize different regions of its surface. Some of the lectins and their affinity ligands are shown in Table 6.2. High-resolution studies involving the protein sequence determination and threedimensional analysis gave insight about the structure and molecular interaction between the sugar ligands and the proteins. As result of this structural analysis, it was observed on the basis of common structural features that lectins fall into three main categories: 1. simple, 2. mosaic or multidomain, 3. macromolecular assemblies.
278
6. Glycoconjugates
TABLE 6.2. Lectines and affinity ligands. Family Legume (plant lectins)
Lectin concanavalin
Abbrev ConA
Ligand MeαMan, MeαGlc Manα3(Manα6)Man
Erithina corallodendron
EcorL
Galβ4Glc
Fava bean
Favin
MeαMan
Griffonia simplicifolia
GSIV
Fucα2Galβ3(Fucα4)GlcNAc
Red kidney bean
PHA
Complex pentasaccharide
Lathyrus ochrus
LOL I,II
Manα3Manβ4GlcNAc, complex octasaccharide
lentil
LCL
MeαMan, MeαGlc
pea
PSL
Manα3(Manα6)Man
Peanut
PNA
Galβ4Glc
Soybean
SBA
Biantennary pentasccharide
cereal
Wheat germ
WGA
NeuAc(α2-3)Galβ4Glc GlcNAcβ4GlcNAc sialoglycopeptide
Amaryllidaceae
Snow drop
GNA
MeαMann mannopentaose
Moraceae
Artocarpus integrifolia
Jacalin
MeαGal
Galectins (animal lectins)
Human heart
Galectin 1
Galβ4GlcNAc octasaccharide
Rat liver
Galectin 2
Galβ4Glc
Simple lectins are most of known plant lectins (Legume, Cereal, Amaryllidaceae, Moraceae, Euphorbiaceae), animal lectins (galectins or formely S-lectins), and Pentraxins, and contain a nonidentical small number of subunits of molecular weight below 40 kDa. Mosaic or multidomain include viral hemagglutinins and animal lectins C- (endocytic lectins, collectins, selectins), P-, and I type. Their molecular weight is variable and is formed by different protein domains, only one of them having the carbohydrate binding site. Macromolecular assemblies are common in bacteria and usually present in the form of fimbriae, which are filamentous, heteropolymeric organelles present on the surface of the bacteria.14 Most plants lectins recognize and interact with terminal nonreducing units of oligo- and polysaccharides, glycoproteins, and glycolipids. Anomeric preference is an important finding observed for different carbohydrate binding proteins, for instance, all mannose/glucose binding lectins display great preference for the α-anomeric forms;15 however, lectins from Ricinus communis bind preferentially to β-galactosidases while other lectins make no difference in binding to anomers of GalNAc and GlcNAc. A considerable amount of structural information about carbohydrate binding proteins such as the complete amino acid sequences for various lectins is available.13,16
6.2. Carbohydrate Binding Proteins
279
Asp 80 Ser 211
OH
Asp 83
Gly 213
O HO
O
OH Gly 104
W2
OH O OH
OH
OH
W1
Asn 127
NH O
W3
Glu 129
W4 Leu 212
Ile 101 Asn 41
FIGURE 6.6. Gal(β1→3)GalNAc in the combining site of peanut agglutinin.
6.2.1 Combining Sites Lectins combine with carbohydrates mainly through weak forces such as hydrogen bonding, coordination with metal ions, and hydrophobic interactions. The hydrogen bridge interaction is established between the carbohydrate hydroxyl groups and the amino groups. Additionally, contacts between the carbohydrate and the protein are mediated by water bridges (Figure 6.6).17 Although carbohydrates are essentially polar molecules, there is a significant nonpolar or hydrophobic interaction that occurs between the N-acetyl group of amino sugars and the glycerol moiety of neuraminic acid, with the aromatic amino acids phenylalanine, tyrosine, and tryptophan. In the combining site of wheat germ agglutinin with sialyllactose, several van der Waals contacts stabilize the orientation of the sugar ring through nonpolar stacking interactions with the aromatic side chain of Tyr64, and Tyr66 that interacts through nonpolar with the glycerol tail of the N-acetyl neuraminic acid (Figure 6.7).18 Several classes of lectins are ion-dependent for their functional interaction with the ligands. Divalent ions such as calcium and magnesium participate in the stabilization of the amino acid positions that interact with the sugars. The Ca2+ ion establishes a coordination bond with the carbonyl group of asparagine and with one carboxylate oxygen of an acidic amino acid. The Mn2+ does not coordinate any residues that interact directly with the protein, but is involved in fixing the Ca2+ .position (Figure 6.8).19,20 In the interaction of Concanavalin A with the branched trisaccharide Man(α16)[Man(α1-3)]Man, several hydrogen bond contacts between the hydroxyl group of the sugar and the amino acid residues are observed. Some of these interactions are
280
6. Glycoconjugates Tyr 66
OH Tyr 64
OH HO
OH O
O Ser 62
OH
OH
O
OH
O
N
OH
H
OH
Tyr 73
H
O H
HN
Ser 114
O O
O
OH Ser 43
Glu 115
FIGURE 6.7. Sialyllactose in the combining site of wheat germ agglutinin.
bifurcated or involve water and contribute importantly in the recognition process (Figure 6.9).13,21 Carbohydrate binding proteins are classified in two types: calcium-dependent (C-type glycoproteins), and thiol reagent-dependent (S-type). The former are structurally more diverse (although the binding region known as carbohydrate recognition domain CRD is highly conserved) and more specific to organs and tissues, while the latter are structurally more conserved and are more widespread among the organs and tissue examined.22 Other carbohydrate binding proteins that do not Asp
NH2 O
Glu
O OH
O Ca
OHO
H O
2+
O As
O H
n
OH NH2
O
O
Glu
FIGURE 6.8. Mannose binding protein C with bound mannose.
6.3. Glycopeptide Synthesis
281
O Thr 15 Tyr 12
CH3
N H
O H H
Tyr 100
O
HO
O H H
O
H O
O
O
O
OH
O
N
Asp 16
OH
O
O H H
O
H
O
OH Leu 99
N H
O
O HO
O
O H O
H
O
H
H 2N
N H
H
Asp 14
NH2 NH
O Asp 208
O
Arg 228
H N O
FIGURE 6.9. Trimannoside binding site of Concanavalin A.
fall into this two categories are fibronectin and laminin, serum immunoglobulins, mannose-phosphate receptor, viral hemagglutinins, and serum amyloid protein. Another important class of carbohydrate binding proteins are known as Selectins (classified as E-, P-, and L-selectins) and are defined as nonenzymatic and nonimmune proteins involved in the leukocyte recruitment to sites of inflammation.2324 It has been found that the tetrasaccharide sialyl Lewis x is the recognition molecule and the use of synthetic sialyl Lewis x confirmed the hypothesis that sulfation increases the affinity for L-selectins.25
6.3 Glycopeptide Synthesis The design of glycopeptides requires a combination of sugar and peptide chemistry, being a substantial part the installation of the O- or N -glycosidic bond26,27 The synthetic approach is in principle designed on the basis of the glycosidic bond required. Thus, while in the case of O-glycopeptides, the synthetic methods relies on the common strategies for the preparation of O-glycosides, for the preparation
282
6. Glycoconjugates O
Fmoc
H H Asn Leu N
H Asn Leu N
COOBzl
O O
BzO BzO
COOBzl
i
CH2 O
CH2
O
BzO BzO
O OBz
OBz i) Morpholine
FIGURE 6.10. Peptide protecting group Fmoc and removal conditions.
of N -glycopeptides the strategy of choice involves the coupling between the amino glycosyl donor with aspartate in the presence of a condensing agent or by enzymatic catalysis. Compatibility between the protecting groups and the glycosidic bond when they are subjected to different reaction conditions such as acid or base conditions is a sensitive issue. For instance, it is known that the glycosidic bond in acetals is acid–sensitive; however, in the case of O-glycosyl serine and threonine, they conversely present base-sensitivity. The introduction of selective protecting groups for amino acid functionalities that can be cleaved under mild conditions without affecting the glycoside bond or protecting groups attached to the sugar moiety is a feasible approach. Widely employed protecting groups used for this purpose is the Fmoc protecting group (9-fluorenyl)methoxycarbonyl), Pyroc (2(pyridyl)ethoxycarbonyl), and Aloc (allyloxycarbonyl) for the peptide and Mpm (4-methoxy-benzyl ether) for the sugar region. The conditions needed for the cleavage of the mentioned protecting group in the presence of other functionalities are indicated in Figure 6.10.28,29 The synthesis of N-α-FMOC amino acid glycosides was carried out from O’Donnell Schiff bases or from N-α-FMOC amino protected serine or threonine and the appropriate glycosyl bromides under Koenigs-Knorr modified conditions.30 The α-FMOC-protected glycosides were incorporated into 22 encephalin glycopeptides analogs (Figure 6.11).
RO RO RO
O O O OR
R = Ac, Bz
RO RO RO
OH N-FMOC O
O O OR
OH N-FMOC
AcO O
AcO AcO
OAc
AcO O AcO
O OAc
AcO AcO AcO
O O
O O O OAc
FIGURE 6.11. N-α-FMOC-amino acid glycosides.
OH N-FMOC
OH N-FMOC
6.3. Glycopeptide Synthesis Mpm
OMpm OMpm
OMpm OMpm
OMpm
O
H3 C
O MeO OAc OAc HO O O AcO OAc
N3
OMpm
O
H3 C
Br
O
283
OAc OAc O O O AcO OAc
i
NHAc
OMpm O N3 NHAc
Teoc
Cl3C
OAc OAc OAc
O
COOH
OAc v
O
OAc OAc O O O AcO OAc
NH2 NHAc CCl3
OAc OAc H 3C
O
O
ii-iv
H3 C
O
H N
O
O
O OAc
OAc OAc O O O AcO OAc
O
OAc O
NH H N
NHAc
C O
O O
i) NEt4Br. ii) CAN. iii) Ac2 O, Py. iv) H2 , Raney-Ni. v) carbodiimide-HOBt, CHCl3.
FIGURE 6.12. Synthesis of glycopeptide Lewisa .
Pyroc is another protecting group useful in peptide chemistry. It is stable to acids, bases, and hydrogenolysis, but sensitive to morpholine. The allylic protecting group Aloc is also stable to acid, base, and can be removed under of Pd(0) catalysis or weak base as morpholine.29 A tumor-associated antigen Lewisa was synthesized by applying a combination of compatible sugar and peptide protecting groups. For this method the azide group was used as anomeric amine precursor (Figure 6.12).30 Enzymes has been useful for peptide elongation using an engineered subtilisin and disaccharide bond formation with glycosyltransferase as shown in Figure 6.13.31 A novel chemoenzymatic synthesis of Ee1 Calcitonine glycopeptide analog having natural N-linked oligosaccharides such as disialo biantennary complex
284
6. Glycoconjugates Cbz-Ala-Ser-OCH3
HO HO
Cbz-Ala-Ser-Gly-Ala-NH2
O
i
O
+
HO HO
NH2-Gly-Ala-NH2
OH
O O OH
OH ii,iii
OH O
NH2-Ala-Ser-Gly-Ala-NH2
O HO
HO OH
O O OH
i) Thiosubtilisin mutant, pH = 9, 50oC. ii) H2, Pd/C. iii) UDP-Gal β1-4-GalTase.
FIGURE 6.13. Chemo-enzymatic synthesis of glycopeptide.
type as model compound for glycoprotein has been described. Natural oligosaccharides were next added by a transglycosylation reaction using endo-β-Nacetylglucosaminidase from Mucor hiemalis (Figure 6.14).32 According to Sears & Wong33 there are three basic approaches for preparing glycopeptides with complex glycans: (1) a converged method consisting in the independent preparation of the sugar and peptide components, and final assemble, (2) the preparation of the sugar attached to an amino acid using glycopeptide chemistry and simultaneous peptide-linked to a glycal, (3) solid-phase synthesis of the glycopeptide and chemoenzymatic elaboration of the glycal (Figure 6.15).
GlcNAc H-Cys-Ser-Asn-Leu-Ser-Thr-Cys-Val-Leu-Gly-Lys-Ser-Gln-Glu-Leu-His-Lys-Leu-Gln-Thr-Tyr-Pro-Arg-ThrAsp-Val-Gly-Ala-Gly-Thr-Pro-NH2
Asn(GlcNAc)3 -eCT NeuAc-Gal-GlcNAc-Man NeuAc-Gal-GlcNAc-Man
Man-GlcNAc-GlcNAc H-Asn-OH
GlcNAc
Endo-M phosphate buffer pH 6.25 8.5 %
H-Asn-OH
NeuAc-Gal-GlcNAc-Man NeuAc-Gal-GlcNAc-Man
Man-GlcNAc-GlcNAc H-Cys-Ser-Asn-Leu-Ser-Thr-Cys-Val-Leu-Gly-Lys-Ser-Gln-Glu-Leu-His-Lys-Leu-Gln-Thr-Tyr-Pro-Arg-ThrAsp-Val-Gly-Ala-Gly-Thr-Pro-NH2
FIGURE 6.14. A transglycosylation reaction for preparation of glycopeptide.
6.4. Glycoprotein Synthesis
285
A) +
HO
Activated oligosaccharide
B)
Glycopeptide
Peptide
NHP CO2H Oligosaccharideamino acid
SPPS Glycopeptide
C)
NHP CO2H
SPPS
Oligosaccharideamino acid
Enzymatic elaboration Glycopeptide
FIGURE 6.15. Proposed general approaches for glycopeptide synthesis.
6.4 Glycoprotein Synthesis Glycoproteins are essential macromolecules involved in a wide range of functions related to cellular recognition processes. Natural glycoproteins usually exist as a mixture of glycoforms and are found difficult to isolate for their structural characterization and for understanding more about their function.34,35 As mentioned, glycoproteins can be obtained by fermentation process, however this natural approximation produce a population of many different glycoforms as result of the participation of many glycosidases and transferases for a given protein, although the mixture can be useful for preparing homogeneous core which in turn might be reelaborated enzymatically.33 The synthetic preparation of glycoproteins can be considered to some extend glycopeptide chemistry, although the complexity is undoubtedly superior. The synthesis of glycoproteins has received considerable attention, most of it involving a combination of chemical and enzymatic methods.35,36−41 A general strategy proposed by Duus et al.42 considers the assembly of glycosylated amino acid building blocks in solid-phase peptide synthesis according to the general figure shown in Figure 6.16.
286
6. Glycoconjugates
A OH O PGO
O Aan Aa6Aa5Aa4Aa3Aa2Aa1
linker
OH
1)
O PGO
LG
+ promoter
1)
deprotection
2) 2)
O
deprotection +
HO
+ enzyme
Nu
O HO O HO
O
O O HO
O Aan Aa6Aa5Aa4Aa3Aa2Aa1
linker
B O PGO
1) Activation
O
X
PGO
X
2) Aa5-Aan
PGHN +
HN Aa3Aa2Aa1
O
2)
Aan
Aa6Aa5 OCHN
Y
O HN Aa3Aa2Aa1
linker
linker
FIGURE 6.16. Strategies for glycopeptide synthesis.
According to a comprehensive review the strategies described so far for chemical glycoprotein synthesis are (a) indiscriminate glycosylation, (b) chemoselective and site-specific glycosylation (c) site-selective glycosylation.43
6.4.1 Indiscriminate Glycosylation This nonselective approach consists of the preparation of sugars bearing functionalities that under proper conditions may react with a protein. Some of the sugar derivatives used for this purpose are shown in Figure 6.17.
AcO
O
a)
(i) (H2N) 2CS
AcO
O
AcO
MeO–
S
(ii) ClCH2CN
NH
O
CN
S
OMe
Br
Lys
H2N
(CH2)4 Protein
AcO
Lys
NH
O S
N H
(CH2)4 Protein
Ref.44 Lys
b)
HO
O
H2N
(CH2)4
Lys
Protein
HO
OH
OH
NaBH3CN
Protein
(CH2)4
N H
Ref.45
c)
HO
HO
O
O
HNO2
O
+
NH2
O
N2
Tyr Protein Tyr Protein
HO
HO
O N
O
N HO
Ref.46 d)
HO
O
HO
(Im)2CS
O
NH2
O
NCS
O
Lys
H2N
(CH2)4
Protein
S HO
Lys
O O
N H
N H
(CH2)4
Ref.47 FIGURE 6.17. Indiscriminate glycoprotein syntheses.
Protein
O O
HO
e)
HO
O
L-Glu-pNA
O
HO
H N
pNA
O
O N
(i) BOP, imd (ii) Pd, H2
OH
(iii) as for (d)
HO
NC6H4NCS
O
O Lys
HO
(CH2)4
H2N
O
Protein
N S
Lys
N H
NC6H4NH
O
(CH2)4
Protein
Ref.48 N2H4
HO
f)
HO
R = OMe
O O
O
HNO2
O
R = NHNH2
(CH2)8COR
(CH2)8CON3
Lys
H2N
(CH2)4
Protein
HO
O O
H N
(CH2)8
Lys
(CH2)4
Protein
O
Ref.
49
O (i) Hal oxidation
HO
g)
O HO
(ii) NaOH(aq.)
O
OH
Lys
Cl H2N
O-Na+
(CH2)4
Et3N
OH O Lys
HO
OH
NH
(CH2)4
Protein
O Lys
(CH2)4
HO HO
h)
Protein
HO O
O NH2
OH
EDC
O HN
OH
O
Ref.50,51 FIGURE 6.17. (Continued)
Asp, Glu
(CH2)1,2
Protein
Protein
6.4. Glycoprotein Synthesis O
O HO
i)
Lys
NH2(CH2)2NH2
O
R = OMe
O
(CH2)8COR
OEt
EtO
H2N
(CH2)4
Protein
R = NH(CH2)2NH2
O HO
289
O Lys
O O
NH(CH2)2 HN
(CH2)8
N H
(CH2)4
Protein
O 52
Ref.
FIGURE 6.17. (Continued)
6.4.2 Chemoselective and Site-Specific Glycosylation This approach intends to direct selectively the glycosidic linkage by using chemical and enzymatic tools. Such selectivity has been attempted under a strategy coined with the term chemoselective ligation, and some enzymes involved in this strategy are galactose oxidase,53 horseradish peroxidase Examples of these step reactions are indicated in Figure 6.18.
6.4.3 Site-Selective Glycosylation This possibility implies the choice of site selectivity on the glycan. In order to reach this goal a combined site-directed mutagenesis and chemical modification has been performed.62,63 This strategy involves the introduction of cysteine as chemoselective tag at preselected positions within a given protein and then reaction of its thiol group with glycomethanethiosulfonate (Figure 6.19).
6.4.4 Enzymatic Synthesis Three basic strategies are considered for obtaining glycoproteins following an enzymatic approach: the elaboration of glycans through the use of glycosyltransferases,64−67 the trimming of glycans by purification of glycoform mixtures through selective enzymatic degradation,68 and alteration of glycans or glycoprotein remodelation, consisting in combined trimming of existing glycan structures followed by elaboration to alternative ones. Theses methods were used for preparing an unnatural glycoform of ribonuclease B by using endoH degradation and elaboration with galactosyltransferase, fucosyltransferase, and sialyltransferase system to construct an sLex glycoform.69 Other approaches for the assembling of peptides are the “native peptide ligation”70 and endoglycosidasecatalyzed transglycosylation.32 Recent advances on glycoprotein synthesis proposes and in vitro approaches involve the following sequential steps: (a) remodeling of recombinant glycoproteins
290
6. Glycoconjugates Protein
O
a)
HO
R O
HO
Protein
O
X
X
NH 2
N R
X = O or N
OH
e.g.
O O
HO AcHN
O
54-56
Ref.
O I
b)
HO O
HO
HO
PtO2, H2
O
N3
HO H N
O
I
NH2
EEDQ
O Cys Protein
HO
HS
O
Cys
H N
Protein
S O
Ref.57,58 Cys
S
NO2
Protein
2
N
c)
HS
HO
HO O
O
SH
S
S
NO2 N
Cys
HO O
Protein
S
S
Ref.59 FIGURE 6.18. Chemoselective and site-specific glycoprotein syntheses.
by using glycosidases and glycosyltransferases: (b) ligation of synthetic glycopeptides by enzymatic or chemical methods: (c) intein-mediated coupling of glycopeptides to larger proteins expressed as intein-fusion proteins: (d) ligation of glycopeptides to larger proteins containing N-terminal cysteine expressed as TEV
O
O
O
(i)
PO
PO
Pd, H2
O
d)
O
N3
O HO
then HMDS, ZnCl2
NH2
N
(ii) deprotect
O
Cys
O
Cys
O
Protein
Protein
HO
HS
S
O
N O
60
Ref.
Cys Protein
HO
e)
O
HO Y
NaSSO 2CH 3
O
O
X
HS
S
CH3
O X = S or O(CH2)2S
Cys
HO O
Protein
X
S
Ref.61-62 FIGURE 6.18. (Continued) HO
O
O
HO
X
S O
or
O
H N
I
Cys
site directed mutagenesis
O
Protein
Protein
HS Cys
HO O
Protein
X
S
X = NHC(O)CH2 or S or O(CH 2)2S
FIGURE 6.19. Site-selective glycoprotein syntheses.
CH3
292
6. Glycoconjugates
FIGURE 6.20. Strategies for glycoprotein synthesis in vitro.
protease cleavable fusion proteins: (e) in vitro translation; and (f) pathway re-engineering in yeast system to produce human–type N-lynked glycoforms (Figure 6.20).71
6.5 Synthesis of Antigenic Glycoconjugates The preparation of complex glycoconjugates has been a current strategy for the design of synthetic vaccines and usually involves the preparation of the oligosaccharide moiety, which provides the immune specificity by chemical or enzymatic methods, and further attachment through a linker with an immunogenic protein. There has been a continuous effort for developing glycoconjugates containing antigens such as MBr1 antigen Globo-H, the blood group determinant and ovarian cancer antigen Lewis y , N3 antigens associated with gastrointestinal cancer, the adenocarcinoma antigen KH-1, and the small cell lung carcinoma antigen fucosyl GM1, among others (Figure 6.21), as promising alternatives to develop potentially useful carbohydrate-based anticancer vaccines accessible for clinical program. The synthetic approach becomes justified if we consider that cancer and normal cell growing in tissue culture generally show minimal level of expression of such antigens.72 The chemical synthesis of most of these complex oligosaccharides represents a formidable challenge and requires a convenient combination of strategies that
OH
OH O
OH
HO
OH O
O O
OH
OH O O
O NHAc
O H3C
OH
OH
OH
O
OH O
HO
OH
O OH
OH O
HN
HO
C15H31 C13H27
O OH OH
MBr1 antigen / Globo-H
OH CH3
O
OH CH3
O OH
OH
OH OH O
OH O
HO
O
O
O H3C OH
O
OH OH
OH O
O NHAc
O
OH OH O O
OH
O NHAc
OH
OH
OH O
OH O
O HO
O
OH
KH-1 antigen
HN
C15H31 C13H27
R=
OH
OH CH3 O O
OH OH
OH OH O
OH O
HO
O
O
O H3C
O
OH
OH
HN
C15H31 C13H27
O NHAc OH
OH
OH Lewisy blood group determinant
OH O
HO
O OH H3C
O OH
OH OR OR'
OH O O NHAc
O
OH OH O O NHAc
OH O OH
O HO
OR OH
OH
OH O OH OH
major N3 antigen (R = α-fucose, R' = β-Gal) minor N3 antigen (R' = α-fucose, R = β-Gal)
FIGURE 6.21. Carbohydrate structures of tumor-associated antigens.
294
6. Glycoconjugates
OH
OH O
HO O
OH
OH O
O
O O
H3C
OH
OH
O NHAc
OH
OH O
O
O OH
HO2C
OH O HO
HN
C15H31 C13H27
O OH OH
O OH HO HO
Fucosyl GM1
NHAc
HO
FIGURE 6.21. (Continued)
allowed suitable manipulations using appropriate protecting groups, glycosyl donors, acceptors, and coupling reactions conditions. For instance, the synthesis of glycolipid KH-1 was achieved by Desphande et al.72 based on the glycal methodology (Figure 6.22). Likewise, the synthesis of the water-soluble galactosphingolipid analog that binds specifically to recombinant gp 120 was prepared by condensation of Cglucosyl aldehyde with Wittig reagent affording the oxazolidone which was transformed into the C-glycosylamino acid. By following a subsequent standard protocol represented in Figure 6.23 the target glycolipid was constructed.73 Glycoside ceramides are important molecules involved in apoptosis or active cell death. In leukemia cell lines C2 ceramide induces apoptosis via the sphingomyelin pathway. It has been observed that α-galactosylceramides having more than 10 carbons in fatty acid chain have immune stimulatory activities. Thus, the α-Gal-C2 was synthesized by direct glycosylation of C2-Cer with galactosyl fluoride donor in the presence of silver perchlorate as condensing agent (Figure 6.24).74 The convergent synthesis is a procedure consisting in the parallel preparation of fragments or building block that will be connected through a coupling reaction, prior deprotection. This procedure was applied successfully for preparation of glycosylphosphatydil inositols (GPI), which are involved in the attachment of glycoproteins with eukaryotic cells (Figure 6.25).75 The potential of carbohydrates as antibiotics, antiviral, and anticancer substances has been established.76,77 Besides, it has been demonstrated their involvement in fertilization, embryogenesis, regulation of the immune system tissue repair, neuronal development, intracellular pathways, and cancer transformation, among others.12 There is an increasing understanding of how carbohydrates behave biologically between normal and disease states and with this accurate information, novel carbohydrates and therapeutic approaches are developed.78 For instance, novel glycoside sulfates have been reported as novel potentially useful drugs (Figure 6.26).76,77
O
OBn O
O O
O OH
OAc OBn O O OAc NHSO2Ph
OBn O HO
O HO
OBn O
OAc OBn O
OBn O
O NHSO2Ph
O BnO
OAc
F H3C
O
OBz OBz CH3
OBz CH3
O
O OBn
O O O
O O
H3C
O
OH
OBn
OBn OBn O
OBn O
OAc OBn O O OAc NHSO2Ph
O
OH
O
OBn OBn O O
OBz CH3
O NHSO2Ph
OBn
O O
H3C
O
OH
OBn
OAc OBn O O OAc NHSO2Ph
O
OH
O
OBn OBn O O
O NHSO2Ph
OBz CH3 OBn
O O
H3C OH
O
SEt
OAc
OAc
OAc OBn O
OBn O
O OBn
OBn OBn O
OBn O
O
O BnO
OBz CH3
O
O
OBn O
OAc OBn O
iii
OH
O
OAc
O OBn OBn O
OBn O
O
O BnO
OBz CH3
O
O
OBn O
OAc OBn O
ii
OH
O
i
OBn
OBn
OAc OBn O O OAc NHSO2Ph
O
O
OBn OBn O O
O NHSO2Ph
OH
O BnO
OAc
R OAc
NHC(O)C15H27
OH N3
R=
C13H27
HO OBn
C13H27
O
iv,v
OBn
KH-1
i) Sn(OTf), PhMe/THF (10:1), 4 Å MS. ii) a) DMDO, CH2Cl2. b) EtSH, CH2Cl2, H+ (cat.). c) Ac2O, Py, CH2Cl2. iii) MeOTf, Et2O/CH2Cl2 (2:1) 4 Å M.S. iv) a) H2/Pd-CaCO3, palmitic anh. EtOAc. v) a) Na/NH3, THF, then MeOH. b) Ac2O, Et3N, DMAP, CH2Cl2. c) MeONa, MeOH.
FIGURE 6.22. Synthesis of KH-1 antigen.
296
6. Glycoconjugates PPh3+
OBn OBn O
O
BnO
OBn OBn O
i
HN
+
O
O OBn OBn O
O
iii
O
BnO
OBn OBn O
iv
BnO
BnO
N H
OBn
N H
OBn OBn OBn O
OBn BocHN
OBn BocHN
v
OH vi
O
BnO
OH O O
HO
OBn BocHN
NH(CH2)13CH3
OH +H N 3
O
NH(CH2)13CH3 O
i) BULi, THF. ii) TsNHNH, NaOAc, DME, H 2/cat. iii) a) Boc2O, Et3N, DMAP. b) CSCO 3, MeOH. iv) Jones. v) EDC, HOBt, tetradecylamine. vi) a) TFA. b) H2/Pd-C.
FIGURE 6.23. Synthesis of galactosphingolipid analog.
O OBn OBn
HN HO
(CH2)12CH3
+
O BnO OBn
OH i,ii
OH
OH
O
O HO
HN HO
O
OH O
OH
OBn OBn O
ii
O
BnO
H
OBn
O
(CH2)12CH3 OH
i) AgClO4, THF, MS, 2h. ii) Na/NH3, 2h.
FIGURE 6.24. Synthesis of glycosylceramide.
F
6.5. Synthesis of Antigenic Glycoconjugates
297
O
N H
H N O
O
O
P
O
OH O
O HO HO OH
HO
O O
HO HO
O HO HO
OH O HO O HO
O H3 N
O O HO
HO O
C15H31 OH OH
O H2NH2CH2CO
P
BnO
N H
H N O
O
BnO BnO
O OH OH
+
OBn O
BnO BnO BnO
O O O BnO BnO
OBn O
BnO O BnO
O BzCHN
O MBnO
O BnO O
C15H31 OBn OBn
FIGURE 6.25. Retrosynthesis for the preparation of GPI-anchored peptide using convergent synthesis.
It has been mentioned that carbohydrate-based agents such as glycoproteins and polysaccharides obtained from synthetic routes is an emerging and promising strategy for the preparation of vaccines.79−81 This possibility has become available due the remarkable progress for the chemical and enzymatic preparation of oligosaccharides.
298
6. Glycoconjugates O
N H
H N O
O
O
P
O
OH O
O HO HO OH
HO
O O
HO HO
O HO HO
OH O HO O HO
O H3 N
O O HO
HO O
C15H31 OH OH
O H2NH2CH2CO
P
BnO
N H
H N O
O
BnO BnO
O OH OH
+
OBn O
BnO BnO BnO
O O O BnO BnO
OBn O
BnO O BnO
O BzCHN
O MBnO
O BnO O
C15H31 OBn OBn
FIGURE 6.25. (Continued)
Recent developments on carbohydrate chemistry made possible the design and escalation of new immunogenic carbohydrates. A newly developed synthetic carbohydrate attached to a protein carrier was reported by Verez-Bencomo and Fern´andez-Santana, and currently administrated against Haemophilus influenzae type b disease. The chemical synthesis leading to the oligomeric polyribosylribitol phosphate is described in Figure 6.27.82
SO3–
-O2C
O
HO HO
SO3– O
SO3–
-O2C
O
O NHAc HO
O OH
SO3– O O
O OH
NHAc
Chondroitin sulfates
O N
OH
NH
O
HO HO
HO3SO
HO
N
O
SO3– O
N
NH2
OH
O
OH
O
OH OH O
tetrahalose-2-sulfate
OH OH
OH
ribonucleoside monosulfate
OH
O O
HO HO
HN
(CH2)24CH3 OH
SO3–
(CH2)13CH3 OH C-glycoside KRN7000 Me
HO HO HO
O O
O O HO AcHN CO OH HN
O
O
HO
OH HO
CONH2 O O O O P O OH O NHAc
HO HO
Me O O
OH
OH
Menomycin A
SO3– Na+ O
HO R3O R3O
OR2 O OR1
R1 = oleoyl R1 = linoleoyl R1 = palmitoyl R1 = linoleoyl
R2 = palmitoyl R2 = palmitoyl R2 = palmitoyl R2 = palmitoyl
R3 = H R3 = H R3 = H R3 = palmitoyl
FIGURE 6.26. Novel glycoside sulfates and phosphates as potential drugs.
AcO
OAc
O
RO
HO OBn OBn OBn OAll
+
AcO
OAc
i,ii
RO
BnO
O
O
OR
OBn OBn OBn OAll
O
O OBn OBn OBn OR
iii-iv
R1O
R = Ac R=H
OBn
R = CH2CH=CH2; R1 = H R = CH=CHCH3; R1 = H
v-vii
BnO
O
O
OBn OBn OBn OH
O Et3 BnO
vi-vii
O
O
P O
N3
O
O
OR
O
P
X
O
O
O
O
O +Na–O
OR
OR
viii-xi
RO RO
P O OH
OBn OBn OBn OH
O Et3NH+ –O
NH+ –O
OR OR OR O O P O– Na+
O
O
OR
OR OR OR OH
X = N3; R = Bn X = NH2; R = H
O
HO HO
O
O
O
+Na–O
H N
N
P
O
O
O
OH
OH OH OH O O P
O– Na+
O
O
OH
7
O O
S O
O
O
N H
Protein 20-25
i) BF3Et2O, CH2Cl2. ii) CH3ONa, CH3OH. iii) BnCl, BuSnO, NaH, Bu4NI. iv) tBuOK, DMSO, 100oC. v) PCl3, imidazole, CH3CN. vi) N3(CH2)2O(CH2)2OH, I2. vii) AcOH-H2O, 80oC. viii) PivCl, Py. ix) Py-H2O. x) H2, Pd-C, EtOH-H2O-EtOAc-AcOH, 1.5 atm. xi) cation exchange resin on Sephadex SP-C25.
FIGURE 6.27. Synthetic carbohydrate conjugate vaccine Quimi-Hib.
OH OH OH OH
References OH OH OH OH OH OH O O O HO O O O NHAc OHO H3 C O OH Globo H HO OH OH
OHOH
HO
AcHN OH O O OH HO
H 3C O
OH O OH
CO2 H O
HO
STn
OH OH Tn O HO AcHN O
O
OH O
O
HO AcHN
OH HNAc
301
H N
O
O N H
O O OH OH OH OH OH OH OH O O O O HO O O O O O NHAc OH H3 C OH O AcHN OH HO OH OH O O O Lewisy OH OH OH OH
H N
O N H
H N O
H N
Linker
S O Carrier protein
TF
FIGURE 6.28. Various tumor antigenic agents coupled to a linker developed as potential synthetic vaccine.
Another alternative therapeutic strategy for inducing immune response through the use of synthetic carbohydrate vaccines has been proposed by Danishefsky et al., involving the attachment of different tumor antigenic agents (Globo H, STn, Tn, Lewis y ), coupled to a linker and this to a protein carrier (Figure 6.28).83
References 1. J.F. Robyt, Essentials of Carbohydrate Chemistry, Springer-Verlag, New York, Inc. 1998, 279. 2. A. Morell, R.A. Irvine, I. Sternliev, I.H. Scheinberg, and G. Ashwell, G. J. Biol. Chem. 1968, 243, 155. 3. H.D. Fischer, A. Gonzalez-Noriega, W.S. Sly, and D.J. Morre, J. Biol. Chem. 1980, 255, 9608. 4. P. Stahl, P.H. Schlesinger, E. Sigardson, J. Rodman, Y.C. Lee, Cell 1980, 19, 207. 5. P.M. Rudd, T. Elliot, P. Cresswell, I.A. Wilson, and R.A. Dwek, Science 2001, 291, 370. 6. I.N. Reitter, R.E. Means, and R.C. Desrosiers, Nature Med. 1998, 4, 679. 7. G.F. Springer, Science 1984, 224, 1198. 8. J. Samuel, A.A. Noujaim, G.D. MacLean, M.R. Sureshand, and B.M. Longenecker, Cancer Res. 1990, 50, 4801. 9. M. Fukada, Biochim. Biophys. Acta, 1985, 780, 119. 10. R. Kornfeld, and S. Kornfeld, Annu. Rev. Biochem. 1985, 54, 631. 11. Y.C. Lee, FASEB J. 1992, 6, 3193–3200. 12. R. Dwek, Chem. Rev. 1996, 683. 13. H. Lis and N. Sharon, Chem. Rev. 1998, 98, 637. 14. W. Gaastra and A.-M. Svennerholm, Trends. Microbiol. 1996, 4, 444. 15. I.J. Goldstein, H.C. Winter, R.D. Poretz, In Glycoproteins, Elsevier 1997, 403–474. 16. W.I. Weis and K. Drickamer, Annu. Rev. Biochem 1996, 65, 441.
302
6. Glycoconjugates
17. R. Ravishankar, N. Ravindran, A. Suguna, A. Surolia and M. Vijayan, Curr. Science, 1997, 72, 855. 18. N. Sharon, Trends Biochem. Sci. 1993, 18, 221. 19. W.I. Weis, and K. Drickamer, Annu. Rev. Biochem. 1996, 65, 441. 20. N. Sharon, and H. Lis, Essays Biochem. 1995, 30, 59. 21. J.H. Naismith and R.A. Field, J. Biol. Chem. 1996, 271, 972. 22. K. Drickamer, J. Biol. Chem. 1988, 263, 9575-9560. 23. F. Fukumori, N. Takeuchi, T. Hagiwara, H. Ohbayashi, T. Endo, N. Kochibe, Y. Nagata, and A. Kobata, J. Biochem. 1990, 107, 190. 24. L.A. Lasky, Annu. Rev. Biochem. 1995, 64, 113. 25. S. Hemmerich, H. Leffler, and S.D. Rosen J. Biol. Chem. 1995, 270, 12035. 26. H. Kunz, Angew. Chem. Int. Ed. Engl. 1987, 26, 294. 27. H. Garg and R.W. Jeanloz, Adv. Carbohydr. Chem. Biochem. 1985, 43, 135. 28. H. Kunz, Pure & Appl. Chem. 1993, 65, 1223. 29. H. Kunz and C. Unverzagt, Angew. Chem. Int. Ed. Engl. 1984, 23, 436. 30. J. M¨arz and H. Kunz, Synlett 1992, 589. 31. C.H. Wong, M. Schuster, P. Wang, and P. Sears, J. Am. Chem. Soc. 1993, 115, 5893. 32. M. Mizuno, K. Haneda, R. Iguchi, I. Muramoto, T. Kawakami, S. Aimoto, K. Yamamoto, and T. Inazu, J. Am. Chem. Soc. 1999, 121, 284. 33. P. Sears and C.-H. Wong, Science 2001, 291, 2344. 34. P.P. Deshpande, H.M. Kim, A. Zatorski. T.K. Park, G. Raguphathi, P.O. Livingston, D. Live and S.J. Danishefsky, J. Am. Chem. Soc. 1998, 120, 1600. 35. C.R. Bertozzi, D.G. Cook, W.R. Kobertz, F. Gonzalez-Scarano, M.D. Bednarski, J. Am. Chem. Soc., 1992, 114, 10639. 36. L.M. Obei, C.M. Linardic, L.A. Karolak, and Y.A. Hannun, Science 1993, 259, 1769. 37. J. Xue, N. Shao, and Z. Guo, J. Org. Chem. 2003, 68, 4020-4029. 38. U. Kempin, L. Henning, D. Knoll, P. Welzel, D. M¨uller, and J. Markus, van Heijenoort, Tetrahedron, 1997, 53, 17669. 39. S. Loya, V. Reshef, E. Mizrachi, C., Silbertein, Y. Rachamim, S. Carmeli and A. Hizi, J. Nat. Prod. 1998, 61, 891. 40. A. Persidis, Nature Biotechnology 1997, 15, 479. 41. T. Buskas, Y. Li and G.-J. Boons, Chem. Eur. J. 2004, 10, 3517. 42. J.Ø Duus, P.M.St. Hilaire M .Meldal, and K. Bock, Pure. Appl. Chem. 1999, 71, 755. 43. (a) B. G. Davis, Chem. Rev. 2002, 102, 579. (b) C.R. Bertozzi and L.L. Kiessling, Science 2001, 23, 2357. 44. Y.C. Lee, C.P. Stowell, and M.J. Krantz, Biochemistry 1976, 15, 3956. 45. G.R. Gray, Arch. Biochem. Biophys. 1974, 163, 426. 46. C.R. McBroom, C.H. Samanen, and I.J. Goldstein, Methods Enzymol. 1972, 28, 212. 47. D.H. Buss and I.J. Goldstein, J. Chem. Soc. C 1968, 1457. 48. C. Qu´etard, S. Bourgerie, N. Normand-Sdiqui, R. Mayer, G. Strecker, P. Midoux, A.C. Roche, and M. Monsigny, Bioconjugate Chem. 1998, 9, 268. 49. R.U. Lemieux, D.R. Bindle, and D. A. Baker, J. Am. Chem. Soc. 1975, 97, 4076. 50. W.O. Baek and M.A. Vijayalaksmi, Biochim. Biophys. Acta 1997, 1336, 394. 51. K.-Y. Jiang, O. Pitiot, M. Anissimova, H. Adenier,and M.A. Vijayalakshmi, Biochim, Biophys. Acta. 1999, 1433, 198. 52. V.P. Kamath, P. Diedrich, and O. Hindsgaul, Glycoconjugate J. 1996, 13, 315. 53. G.A. Lemieux and C.R. Bertozzi, TIBTECH 1998, 16, 506. 54. S.E. Cervigni, P. Dumy, and M. Mutter, Angew. Chem. Int. Ed. Engl. 1996, 35, 1230. 55. Y. Zhao, S.B.H. Kent, and B.T. Chait, Proc. Natl. Acad. Sci. USA, 1997, 94, 1629.
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56. P. Durieux, J. Fernandez-Carneado, and G. Tuchscherer, Tetrahedron Lett. 2001, 42, 2297. 57. N.J. Davis and S.L., Flitsch, Tetrahedron Lett. 1991, 32, 6793. 58. L.A. Marcaurelle and C.R. Bertozzi, J. Am. Chem. Soc. 2001, 123, 1587. 59. W.M. Macindoe, A.H. van Oijen, and G.-J. Boons, Chem. Commun. 1998, 847. 60. I. Shin, H.-J. Jung, and M.R. Lee, Tetrahedron Lett. 2001, 42, 1325. 61. B.J. Davis, R.C. Lloyd, and J.B. Jones, J. Org. Chem. 1998, 63, 9614. 62. B.G. Davis, M.A.T. Maughan, M.P. Green, and A. Ullman, Tetrahedron: Asymmetry 2000, 11, 245. 63. B.G. Davis, R.C. Lloyd, and J.B. Jones, Bioorg. Med. Chem. 2000, 8, 1527. 64. J.C. Paulson, R.L. Hill, T. Tanabe, and G. Ashwell, J. Biol. Chem. 1997, 252, 8624. 65. S. Tsuboi, Y. Isogai, N. Hada, J.K. King, O. Hindsgaul, and M. Fukuda, J. Biol. Chem. 1996, 271, 27213. 66. C. Unversagt, Tetrahedron Lett. 1997, 32, 5627. 67. R.A. Geremia, E.A. Petroni, L. Ielpi, and B. Herissat, Biochem. J. 1996, 318, 133. 68. B. Friedman, S.C. Hubbard, and J.R. Rasmussen, Glycoconjugate, J. 1993, 10, 257. 69. K. Witte, P. Sears, R. Martin, and C.-H. Wong, J. Am. Chem. Soc. 1997, 119, 2114. 70. G.G. Kochendoerfer and S.B.H. Kent, Curr. Opin. Chem. Biol. 1999, 3, 665. 71. C.-H. Wong, J. Org. Chem. 70, 4221 (2005). 72. P.P. Deshpande, H.M. Kim, A. Zatorski, T.K. Park, G. Raguphathi, P.O. Livingston, D. Live, and S.J. Danishefsky, J. Am. Chem. Soc. 1998, 120, 1600. 73. C.R. Bertozzi, D.G. Cook, W.R. Kobertz, F. Gonzalez-Scarano, and M.D. Bednarski, J. Am. Chem. Soc. 1992, 114, 10639. 74. L.M. Obei, C.M. Linardic, L.A. Karolak, and Y.A. Hannun, Science 1993, 259, 1769. 75. J. Xue, N. Shao, and Z. Guo, J. Org. Chem. 2003, 68, 4020–4029. 76. U. Kempin, L. Henning, D. Knoll, P. Welzel, D. M¨uller, J. Markus, van Heijenoort, Tetrahedron, 1997, 53, 17669. 77. S. Loya, V. Reshef, E. Mizrachi, C. Silbertein, Y. Rachamim, S. Carmeli, and A. Hizi, J. Nat. Prod. 1998, 61, 891. 78. A. Persidis, Nature Biotechnology 1997, 15, 479. 79. T. Buskas, Y. Li, and G.-J. Boons, Chem. Eur. J. 2004, 10, 3517. 80. P.H. Seeberger, R.L. Soucy, Y.-U. Kwon, D.A. Snyder, and T. Konemitsu, Chem. Commun. 2004, 1706. 81. S. Bay, V. Huteau, M.-L. Zarantonelli, R. Pires, J. Ughetto-Monfrin, M.-K. Taha, P. England, and P. Lafaye, J. Med. Chem. 2004, 47, 3916. 82. V. Verez-Bencomo, et al., Science 2004, 305, 522. 83. S.J. Danishefsky and J.R. Allen, Angew. Chem. Int. Ed. 2000, 39, 836–863.
7 Hydrolysis of Glycosides
The glycosidic bond might be degraded by chemical and/or enzymatic agents. Comparative studies revealed that chemical hydrolysis is nonspecific and on the other hand the enzymatic is regio and stereospecific. The glycosides are chemically susceptible to acid conditions, and only in some cases to basic conditions. In general, the acid sensitivity is attributed to the sugar moiety and the basic nonstability to the aglycon nature.
7.1 Acidic Hydrolysis When a glycoside is subjected to acid conditions, a process called acetolysis takes place. This phenomenon is more clearly seen on O-glycosides, where even weak acid conditions can be sufficient for O-glycoside breakage. Some simple glycosides such as β methyl-2,3,4,6-tetra-O-methyl-D-glucopyranose are hydrolyzed under diluted HCl conditions to yield a hydroxy-2,3,4,6-tetra-Omethyl-D-glucopyranose. Likewise β ethyl-glucopyranose is hydrolyzed to a mixture of anomers (Figure 7.1). In general, S-glycosides are more resistant than their counterparts O-glycosides to an acidic medium; however, the former can be hydrolyzed under the conditions described in Figure 7.2. Disaccharides can be readily hydrolyzed under weak acidic conditions, producing their constitutive monomers in equivalent quantities (Table 7.1). Depending on the strength of the hydrolytic conditions, polysaccharides undergo fragmentation, producing oligosaccharides, disaccharides, and monomers. The degradation degree relies on acid concentration, branching, and solubility. Thus, cellulose, being the most abundant natural polisaccharide in nature, requires high acidic concentrations in order to be fully degraded to glucose. On the contrary, some other polysaccharides at lower concentrations produce dimers and monomers (Table 7.2). Partial hydrolysis is important in certain cases in which disaccharides are not either affordable materials or easily obtained ones through synthetic means. Such 304
7.1. Acidic Hydrolysis OMe O MeO MeO
OMe
HO
OMe O
i
MeO MeO
OMe OH O
HO
OMe OH
OH O
i
OH OEt
HO
HO
OH O
+
OH OH
HO
HO
OH
i) HCl dil.
FIGURE 7.1. Acid hydrolysis of simple O-glucosides.
OAc O
SPh
OAc O
i
AcO
OH
AcO AcO
305
OAc
AcO
OAc
i) NBS/acetone-H2O.
FIGURE 7.2. Hydrolysis of thioglycosides.
TABLE 7.1. Acid hydrolysis of disaccharides. Disaccharide
Hydrolysis product
(+)-sucrose
D-(+)-glucose D-(−)-fructose
(+)-lactose
D-(+)-glucose D-(+)-galactose
(+)-cellobiose
D-(+)-glucose D-(+)-glucose
TABLE 7.2. Acid hydrolysis of polysaccharides. Polysaccharide
Partial hydrolysis
Total hydrolysis
cellulose laminarin curdlan quitine manan pululan
1,4-cellobiose 1,3-laminaribiose 1,3-laminaribiose 1,4-N-acetyl glucosamine 1,4-mannobiose 1,4-maltotriose
D-glucose D-glucose D-glucose 2-amino-2-deoxy-D-glucose D-glucose D-glucose
OH
306
7. Hydrolysis of Glycosides
is the case of 1,3-laminaribiose synthetically obtained in poor yields (9.5%),1 but readily available from polysaccharide curdlan.2
7.2 Basic Hydrolysis Some glycosides have been shown to be partially sensitive against basic conditions, besides their naturally high acid sensitivity. It is been experimentally found that three classes of O-glycosides might be subject to basic hydrolysis:3 1. phenolic glycosides 2. enolic glycosides 3. β-substituted alcohol glycosides
7.2.1 Phenolic Glycosides A typical example of phenolic glycoside decomposition under basic conditions is observed in the treatment of salicin with barium hydroxide giving as result a cyclic acetal and the release of the aglycon (Figure 7.3).
7.2.2 Enolic Glycosides Within this type of glycosides, the three varieties to be considered are (1) 4hydroxycoumarins, (2) purine and pirimidin glycosides,and (3) simple enols (Figure 7.4).
7.2.3 β-Susbstituted Alcohol Glycosides Glycoside picrocine is hydrolyzed in diluted potassium hydroxide solution, through a mechanism that involves an intermediate carbanion formation to give a conjugated unsaturated product and glucose as breakage product (Figure 7.5). Contrary to acid hydrolysis of disaccharides where degradation products are their constitutive units, in most of the cases for basic conditions, nonsugar derivatives are produced as result (Table 7.3).
OH O OH
O
OCH3 O
OCH3
O i
HO
OH
+
OH
OH OH
OH
i) Ba(OH)2.
FIGURE 7.3. Basic hydrolysis of phenolic glycosides.
7.2. Basic Hydrolysis H3C
OH
OH
O OH
N
O
O
NH
O
OH O
OH
N
OH
OH
a
OH
CH3
OH
O
N
b
O
O
O
O
OH OH
c
OH
FIGURE 7.4. Basic hydrolysis of enolic glycosides.
OH
OH
O
O
O
OH OH
OH
CHO OH
OH
O
OH
CHO OH
OH O
OH
OH
+ CHO
OH OH
FIGURE 7.5. Basic hydrolysis of β-substituted alcohol glycosides.
TABLE 7.3. Degradation products of disaccharides under basic conditions. Disaccharide cellobiose gentobiose lactose maltose
Hydrolysis conditions (KOH)
Temperature (◦ C)
Product
1.5 N 2N 0.2 N 0.15 N
50 50 100 25
lactic acid lactic acid D-galactose fenilhydrazone of D-mannose
307
308
7. Hydrolysis of Glycosides
7.3 Enzymatic Hydrolysis β-Glycosides are the natural substrates for hydrolytic enzymes known as βglycosidases. So far, at the biochemical level, the rule of most of glycosidases is not totally well understood. However, some of them have been related to feeding, detoxification processes, or even as a defense mechanism against herbivorous pathogens through releasing of tiocyanates, cianides, and phytohormones. It is been established that there is an specific glycosidases for each aldopyranose, being the sugar composition responsible for the recognition pattern. Some of the best-studied hydrolyses are the β-glycosidases and among them β-glucosidases, β-glucuronidases, β-cellulase, β-glucanasas, β-quitinases, all of them with important biological and economical implications.4
7.3.1 β-Glucosidases There is strong evidence indicating that their action is mainly directed toward the defense mechanism and growth regulation. For instance, cyanogenic glycosides are hydrolyzed, for the releasing of cyanide ions as a defense mechanism against animals. In humans the equivalent of β-glucosidase is called glucocerebrosidase (with low genomic homology to the plant counterpart) and catalyzes the degradation of glucosylceramide inside lysosome. The lack or deficiency of this enzyme produces the Gaucher disease characterized by accumulation of esphyngosylglucosides and glucosylceramides.
7.3.2 β-Glucanasas, β-Quitinases The natural substrates for these oligosaccharide hydrolytic enzymes are laminarin and quitine, respectively, being present in fungi, yeast, and insects. Some of the processes related to the activity of these enzymes are seed degradation, cellular elongation control, growth regulation, pollen growth regulation, digestion, and fertilization. Moreover, within the context of the defense mechanisms, these enzymes can be able to digest the fungi cellular wall and also to release oligosaccharides that induce the production of antimycotic substances called phytolexines.
7.3.3 β-Cellulase Cellulose is the most abundant natural polisaccharide on earth. Cellulitic enzymes, particularily cellobiohydrolases CBHI, CBHII, EGI and EG II found in fungi Trichoderma reesei, have been thoroughly studied for determing the threedimensional structure, the genomic sequence, receptors, and substrate specificity.
7.3.4 β-Glucuronidase In animals this enzyme is responsible for the detoxification processes, coupling mainly aromatic compounds and eliminating them as glucuronides. In plants there is not detectable β-glucuronidase activity; however, the development of the
7.3. Enzymatic Hydrolysis
309
CBH I and CBH II
= 1,4-glucopyranosyl
= 1,4-galactopyranosyl
= hydrolytic site
= reduction terminal
FIGURE 7.6. Enzymatic specificity on low–molecular-weight substrates.
GUS gene fusion containing E. coli β-glucuronidase has been widely used as a gene marker.5 Transgenic plants containing exogenic information fused to the βglucuronidase gene marker can be conveniently monitored by using fluorogenic o histochemical glucuronides.
7.3.5 Glycosidase Enzymatic Activity Detection Detection can be achieved not only qualitatively, but also quantitatively; for doing so, high- and low-molecular-weight substrates have been designed. Claeyssens6 demonstrated hydrolytic specificity of cellulases CBH I and CBH II through the use of synthetic fruorogenic substrates containing the highly fluoroescent coumarin umbelliferone or p-nitrophenol, in the form of O-glucosides. The cleavage of the glycoside releases the chromophore, which can be easily measured in a fluorometer or spectrophotometer. The synthetic design of mono-, di-, tri-, and tetrasaccharides attached to the mentioned chromophores have been of great advantage to determine the specificity during enzymatic cleavage (Figure 7.6).
7.3.6 Regarding β-1,4-Glucanases (EG) The utilization of polysaccharides covalently attached to dyes has been reported. The complex Ostatin Brilliant Redhydroxyethylcellulose (OBR-HEC) is applied as a specific substrate for EG, Remazol Brilliant Blue-xylan (RBB-X) the specific substrate for β-1,4-xylanases. Likewise, β-1,3-glucanases are detected by using an electrophoresis technique on polyacrilamide gels utilizing laminarin as substrate. The generated fragments are reacted further with azoic stain 2,3,5-triphenyltetrazolium to produce a color
310
7. Hydrolysis of Glycosides CH3
RO
OR O
RO
O
O
O
N O
H2N R = glucose, galactose, glucucronic acid, N-acetylglucosamine.
FIGURE 7.7. Fluorescent O-glycosides.
complex.7 Despite their high sensitivity, this method cannot distinguish between endo and exo glucanase.
7.3.7 Fluorescent O-Glycosides As mentioned before, fluorogenic aglycons are very useful molecules to monitor enzymatic activity. In principle, the fluorescent compound does not exhibit fluorescence in the glycoside form and exerts its fluorescence when released as a result of the enzymatic activity (Figure 7.7). Some of the fluorescent compound widely used for enzymatic detections are umbelliferone, fluoresceine, and resorufin, having been coupled to most of the biologically important sugars as O-glycosides. The generated fluorescence is quantified in fluorometers constituted basically by a radiation source and two monocromatic mirrors (f1 and f2). The first one selects the light for producing fluorescence activation, and the second transmits selectively fluorescence emission. A detector will measure the intensity of the fluorescence generated (Figure 7.8).
source
sample f1
f2
detector
FIGURE 7.8. Basic diagram of fluorometer.
OR
7.3. Enzymatic Hydrolysis
311
FIGURE 7.9. Absorption glycosides. O2N
OR
R = glucose, galactose, glucuronic acid, N-acetylglucosamine.
7.3.8 O-Glycosides Measured by Absorption Quantification of enzymatic activity following absorption detection is based on the use of synthetic p-nitrophenol in the form of O-glycosides as substrate (Figure 7.9). The release of the aglycon from the sugar moiety produces slight yellow color measured as absorbance.
7.3.9 Histochemical O-Glycosides Generally, a histochemical substrate is to be considered as a good candidate, should be such that in the form of O-glycosides it is water-soluble and when the enzyme hydrolyzes the glycosidic bond releases the aglycon, which precipitates immediately. A compound that closely fulfills these requirements is 5-bromo-4-chloro-Nacetyl-3-indoxyl, which has been attached to most of the biologically important monosaccharides. Although this is commercially available, it is highly sensitive, producing an easily detectable blue precipitate. It shows some diffusion before the monomers undergo dimerization in the presence of oxygen, to produce the blue indigo precipitate (Figure 7.10). O Cl
Cl
O
OH Ac N
Br
Br
i
N Ac
N Ac
Br HO leuco form
Cl
O Ac N
Br ii
N Ac
Br O
Cl
indigo blue precipitate i) glycosidase. ii) O2.
FIGURE 7.10. 5-Bromo-4-chloro-indoxyl aldopyranose hydrolysis.
Cl
312
7. Hydrolysis of Glycosides FIGURE 7.11. Phenylazonaphtol glucuronides as histochemical substrates.
CH3
CH3 N N CO2H OO OH OH OH
Alternatively, phenylazonaphtols O-glycosides (Figure 7.11) known as Sudan glucuronide has been tested as histochemical substrate for enzymatic detection of gene marker β-glucuronidase in transgenic plants.8,9 The water-soluble Sudan glucuronide releases the fenilazo naphtol stain after enzymatic hydrolysis, which can be seen in the sites of enzymatic activity as red crystals. The mechanism and stereochemistry of enzymatic hydrolysis may occur with either inversion or retention of the configuration at the anomeric center. The first type of hydrolysis is carried out by the called inverting glycosidases, and the second by retaining glycosidases, being the vast majority of β-glucosidases of the latter type. This has been proved through NMR studies, by measuring the chemical shift and magnitude of the coupling constant of the anomeric carbon. The most accepted Glu O
O
H
O
O
OH
O
H
inversion
OR O O
O
NH2
O
Glu
O
OR
O
O H
Glu
O H
O
O
retention
OH
FIGURE 7.12. Schematic representation of retention and inversion hydrolysis mechanism.
References
313
mechanism involves protonation of substrate, carboxylate participation attached to enzyme, intermediate formation glycoside-enzyme, and displacement as shown in Figure 7.12.4
References 1. 2. 3. 4. 5. 6.
P. B¨achli,and E.G. Percival, J. Chem. Soc. 1952, 1243. L.-X. Wang, N. Sakairi, and H. Kuzuhara, J. Carbohydr. Chem., 1991, 10, 349. C.E. Ballou, Adv. Carbohydr. Chem., 1954, 9, 59. A. Esen, β-Glucuronidase, Biochemistry and Molecular Biology, ACS, 1993, 7. R.A. Jefferson, S.M. Burges, and D. Hirsh, Proc. Natl. Acad. Sci. USA, 1986, 83, 8447. M. Clayssens, H. Van Tildeburgh, P. Tomme, T., Wood, and S. McRae, Biochem. J., 1989, 261, 819. 7. S.Q. Pan, X.S. Ye, and J. Kuc, Anal. Biochem., 1989, 136, 182. 8. N. Terryn, M. Brito-Arias, G. Engler, C. Tire, R. Villarroel, M. van Montagu, and D. Inze, Plant Cell, 1993, 5, 1761. 9. E. Van der Eycken, N. Terryn, J.L. Goemans, G. Carlens, W. Nerinckx, M. Claeyssens, J. Van der Eycken, M. Van Montagu, M. Brito-Arias, and G. Engler, Plant Cell Report 2000, 19, 966.
8 Nuclear Magnetic Resonance of Glycosides
8.1 NMR of O-Glycosides Nuclear magnetic resonance (1 H, 13 C NMR), X-ray diffraction, and mass spectrometry are considered among the most important analytical methods for structural elucidation. Characterization by means of 1 H, 13 C NMR, mono- and bidimensional spectroscopy is a powerful tool for structural assignment of simple and complex glycosides. Pioneering studies1−4 on simple monosaccharides were essential for understanding through the chemical shifts and coupling constants the conformational behavior of sugars. Some basic considerations derived from the referred studies mentioned above that apply to simple saccharides are Pyranoside rings of the D-series generally prefer to assume conformation 4 C1 and those of the L-series the conformation 1 C4 . The anomeric proton usually resonate at lower field than methine protons, whereas methylene protons resonate at somewhat higher fields. In D-pyranoses with 4 C1 conformation, the α-anomer resonance is downfield compared to the β-anomer, and the value of the coupling constant between H-1 and H-2 at three bond distance 3 J1−2 determine if the anomeric proton is equatorial or axial, and therefore if the glycoside is α or β. Usually for axial-axial interactions, the observed values are 8-10 Hz and for axial-equatorial or equatorial-equatorial 23 Hz. Thus for β-glucose, 3 J1,2 = 8 Hz, 3 J2,3 = 3 J3,4 = 3 J4,5 = 10 Hz, H-1 appears as doublet, and H-2, H-3, H-4 appear as 10 Hz triplets, and H-5 as double double doublet as it is coupled to the two H6s. The α-galactose presents 3 J1,2 = 3 Hz, 3 J2,3 = 10 Hz, 3 J3,4 = 4 Hz, 3 J4,5 < 1 Hz. H-1 appears as 3 Hz doublet, H-2 and H-3 as double of doublets, H-4 as doublet, and H-5 as triplet for coupling with two H6s. The different possible arrangements are for better understanding represented in Newman proyection (Figure 8.1). Equatorial protons are positioned at lower field than chemically equivalent axial protons except in those cases were there is a carbonyl group adjacent to H-equatorial, or when there is a synaxial interaction with H-axial, in which a deshielding effect is observed.1c
314
8.1. NMR of O-Glycosides
O1 O2
H2
H1
O5
O3
C3
O2
J = 8 Hz
H2
H3
C4
O3
C1
H2
eg. Glc H2/H3;Glc H3/H4
β-Gal H1/H2
Glc H4/H5;Gal H2/H3
H3
C4
H1
C1
O2
H2
O1
O5 C3
J = 4 Hz
J = 3 Hz
eg. Man H2/H3
eg. α-Glc H1/H2
J = 10 Hz
β-Glc H1/H2
O2
315
α-Gal H1/H2
Gal H3/H4
Man H3/H4;Man H4/H5
C6 H4
O4
H5
O5
O1
C3
H2
J = 1 Hz
O2
H1
O5
O1
C3
H2
J = 1 Hz
eg. α-Gal H4/H5
eg. β-Man H1/H2
O2
H1
O5 C3
J = 1.7 Hz eg. α-Man H1/H2
FIGURE 8.1. Newman projections showing the arrengements of hydrogens in 4 C1 and 4 C1 chair conformations and the expected coupling constants.
The magnitude of coupling constant 3 JH-H besides torsion angle dependence may be affected by other factors such as substituent electronegativity, bond length, and bond distance. Solvent effects on 3 J(HH) appear to be relatively minor, except in cases where solvent-induced conformational changes occur.5 The 13 C chemical shift may also reveals along with de 1 H NMR the anomeric configuration, but the one bond 13 C-1 H coupling constants can be remarkably useful to determine the anomeric configuration in pyranoses. For instance, the 1 JCH for the α-anomer is 170 Hz and for the β-anomer 160 Hz, being for the L-isomer the reverse.6 The chemical shift values of the ring protons are dependent of the groups attached to the hydroxyl groups. For instance, a characteristic shift of ring-proton resonances to lower field occurs when the hydroxyl group is esterified with acetyl, sulfate, or phosphate where normally downfield shifts of ∼0.2-0.5 ppm are observed. If the protecting group is acetate, for nonaromatic solvents C-6 resonates at lower field, followed by C-2, C-4, and at highest field the 3-acetoxyl signal.4 The proton magnetic resonance of 4,6-O-benzylidene pyranosides have been measured and the values of the coupling constants J1,2 , J1,3 , J2,3 , and J3,4 support the assignment of the chair conformation to the pyranoid ring.2 The coupling constants 3 JH-H values on saturated systems can be predicted by applying the Karplus equation,7 which correlates the dihedral angle θ values with the magnitude of the coupling constant 3 JH-H . 3
JH-H = A + B cosθ + C cos2θ
where θ is the dihedral angle between H1-C1-C2-H2, A = 4.22, B = −0.5, and ˚ C = 4.5 Hz for C-C bond distance 1.543 A.
316
8. Nuclear Magnetic Resonance of Glycosides Ha Hb Ha
3
JH-H
(Hz)
9
FIGURE 8.2. Relationship between coupling constant and torsion angle.
Hb
8 7 6 5 4
Ha Hb
3 2 1 0
30
60
90 120 150 180 torsion angle (θ)
Coupling constants for vicinal protons at three bond distances are two or three times bigger when they are eclipsed or antieclipsed (0◦ or 180◦ ) to each other than when they are synclinal or gauche (60◦ ) (Figure 8.2). Karplus analysis is more accurate when comparative studies are performed between structurally similar compounds. For the study of conformational differences between structurally similar molecules the Karplus equation adopts the form of 3
JH-H = K cos2θ
where K is dependent on H1-C1-C2-H2 fragment, when θ is having values between 50 and 70◦ , or 110 and 130◦ , slight variations are observed, while for values close to 0, 90 and 180◦ , no observable changes are detected. The effect of the relative orientation and electronegativity of substituents on the magnitude of 3 J(aa), 3 J(ae), and 3 J(ee) has been predicted by a simple set of additivity constants. The step followed in the derivation of the additivity constants considers that antiperiplanar substituents exert a negative and gauche substituents a positive effect on J. The resulting data were fitted equation 3 J = 3 J0 + J (x), where 3 J0 represents the reference value. Some of the additivity constants J (x) for a given substituent are given in Table 8.1.5 More recently, a computer program known as ALTONA was developed for the calculation of dihedral angles from 1 H NMR. This program calculates plots of H-C-C-H diedral angles from proton-proton NMR vicinal coupling constants using an empirically generalized Karplus-type equation, which takes into account the
8.1. NMR of O-Glycosides
317
TABLE 8.1. Additivity constants J (x) for a substituent X. X H,C I,S Br N N3 Cl O F
J (ae)(x) or J (ee)(x) X anti
X gauche
J (aa)(x) X gauche
0.0 −0.3 −0.9 −1.1 −1.4 −1.2 −1.8 −2.5
0.0 +0.1 +0.3 +0.3 +0.4 +0.4 +0.5 +0.7
0.0 −0.3 −0.7 −0.6 −1.1 −1.0 −1.4 −2.0
electronegativity and the orientation of the substituents attached to the considered fragment.8 The NMR spectra of fully acetylated 1-thioaldopyranosides having the configurations β-D-xylo, α-L-arabino, β-D-ribo, β-D-gluco, and β-D-galacto were determined in different solvents, observing that the H-1 signal in these derivatives appears ∼0.35 ppm to higher field than its position in the 1-oxygenated analogs.9 Also, detailed studies of 1 H NMR spectra of a series of hexopyranosyl halides have been accomplished. The first-order assignments revealed several stereospecific dependencies, mainly upon the orientation of the halogen substituent with respect to the pyranose ring and the relative orientation of other substituents attached to the ring.3b,10,11 1 H and 13 C chemical shifts and J-coupling patterns for common D-aldohexoses, D-aldopentoses, and some methyl monosaccharides are described in Tables 8.2 and 8.3.12,13 A wide number and variety of O- and to a lesser extent C-glycosides islolated from natural sources have been reported and their NMR analysis described. The chemical shifts and coupling constants of some of them are described just as representative examples in Table 8.4. Nuclear Overhauser effects (NOE) is a dipole-dipole relaxation experiment and has been one of the most useful experiments for the structural assignments of glycosides on the basis of shielding and deshielding effects.19 Glycosylation sites can be identified by comparison of 1 H NMR spectral data of the peracetylated and the nonprotected sugar, since free OH groups causes significant downfield shift (in the range of 1 to 0.5 ppm). The approach known as “structural-reporter-group” has been introduced to identify individual sugars or sequences of residues and can be used to identify structural motifs or specific sugars and linkage compositions found in relevant databases.13 For complex molecules the interpretation is often problematic, especially due the presence of internal motion. Some of the difficulties encountered for NMR structural assignment for oligosaccharides are20 The limited number of C,H dipolar couplings measured across a single bond The distribution of C,H bond vectors is not isotropic due to the geometry of the pyranose ring.
318
8. Nuclear Magnetic Resonance of Glycosides
TABLE 8.2. 1 H chemical shifts and couplings (3 JH-H ) of D-aldohexoses and aldopentoses measured at 400 MHz in D2 O. Compound
H-1
H-2
H-3
H-4
H-5
H-6a
H-6b
α-glucose
5.09 3.6 4.51 7.8 5.16 3.8 4.48 8.0 5.05 1.8 4.77 1.5
3.41 9.5 3.13 9.5 3.72 10.0 3.41 10.0 3.79 3.8 3.85 3.8
3.61 9.5 3.37 9.5 3.77 3.8 3.56 3.8 3.72 10.0 3.53 10.0
3.29 9.5 3.30 9.5 3.90 1.0 3.84 1.0 3.52 9.8 3.44 9.8
3.72
3.72 2.8 3.75 2.8 3.70 6.4 3.70 3.8 3.74 2.8 3.74 2.8
3.63 5.7, 12.8 3.60 5.7, 12.8 3.62 6.4 3.62 7.8 3.63 6.8, 12.2 3.60 6.8, 12.2
β-glucose α-galactose β-galactose α-mannose β-mannose 1H
3.35 4.00 3.61 3.70 3.25
chemical shifts and couplings (3 JH-H ) of D-aldopentoses measured at 400 MHz in D2 O.
Compound
H-1
H-2
H-3
H-4
H-5a
H-5b
α-xylose
5.09 3.6 4.47 7.8 4.40 7.8 5.12 3.6 4.75 2.1 4.81 6.5 4.89 4.9 4.74 1.1
3.42 9.0 3.14 9.2 3.40 9.8 3.70 9.3 3.71 3.0 3.41 3.3 3.69 3.6 3.81 2.7
3.48 9.0 3.33 9.0 3.55 3.6 3.77 9.8 3.83 3.0 3.98 3.2 3.78 7.8 3.53 8.5
3.52
3.58 7.5 3.82 5.6 3.78 1.8 3.54 2.5 3.82 5.3 3.72 4.4 3.71 3.8 3.84 5.1
3.57 7.5 3.22 10.5, 11.4 3.57 1.3, 13.0 3.91 1.7, 13.5 3.50 2.6, 12.4 3.57 8.8, 11.4 3.58 7.2, 12.1 3.15 9.1, 11.7
β-xylose α-arabinose β-arabinose α-ribose β-ribose α-lyxose β-lyxose
3.51 3.83 3.89 3.77 3.77 3.73 3.73
Due to the flexibility of the glycosidic bond that connects the different sugars moieties, different alignment tensors can be observed. More recently the use of a novel procedure known as “residual dipolar coupling” has been introduced by Tian & Prestegard as an alternative approach for studing the conformational and the motional properties of oligosaccharides.21 The approach is based on the solution for each ring of an order matrix that combines different types of couplings, 1 DCH , 2 DCH , and DHH . Dipolar couplings arise from through space spin-spin interactions and are dependent of both internuclear distance (r) and an angle between the magnetic field and the internuclear vector (θ) as described by the equation (3 cos2 θ − 1) Dij = ξij (1/r3 ) 2
8.1. NMR of O-Glycosides TABLE 8.3.
13
319
C chemical shifts of some aldoses
Compound
C-1
C-2
C-3
C-4
C-5
C-6
α-glucose β-glucose α-galactose β-galactose α-mannose β-mannose α-arabinose β-arabinose α-ribose β-ribose
92.9 96.7 93.2 97.3 95.0 94.6 101.9 96.0 97.1 101.7
72.5 75.1 69.4 72.9 71.7 72.3 82.3 77.1 71.7 76.0
73.8 76.7 70.2 73.8 71.3 74.1 76.5 75.1 70.8 71.2
70.6 70.6 70.3 69.7 68.0 67.8 83.8 82.2 83.8 83.3
72.3 76.8 71.4 76.0 73.4 77.2 62.0 62.0 62.1 63.3
61.6 61.7 62.2 62.0 62.1 62.1
where ξ ij is a constant that depends on the properties of nuclei i and j. Direct measurements of dipolar interactions can be achieved by dissolving molecules in oriented media such as crystals composed of bicelles or phage. Despite the fact that molecular tumbling remains fast in these media, the sampling of orientations are no longer isotropic, and consequently the dipolar couplings do not average to zero and splittings are observed between the dipolar coupled spin pairs. The knowledge of the molecular geometry of a fragment and the measurement of five or more interdependent residual couplings from the fragment allows the determination of the Saupe order matrix elements (Sij) from a set of linear equations relating dipolar couplings to the known geometry factors and the unknown order tensor elements. Dresid α Si j cos θi cos θ j ij
where θij are the angles between the internuclear vectors. Determination of the Saupe order matrices for individual rigid fragments of a molecule allows both structural characterization and assestments of internal motions between fragments.10 NMR studies carried out by De Bruyn,22 using as models series of disaccharides, provided valuable information about conformational behavior from the chemical shifts and the torsion angles present around the glycosidic bond (Figure 8.3). Also it has been reported that the 13 C chemical shifts for the glycoside and the aglycone carbon can be directly correlated with one of the torsion angles psi (ψ) defined by the bonds C(1)-O(1)-C(4)-H(4).19 The sign of θ and ψ has been previously calculated through the method known as hard sphere exoanomeric effect23 which predicted the relative stability of the different conformers around the torsion angles, considering the bond length, bond angle, and atomic size. It has been observed that for a number of disaccharides there is a variation of the chemical shifts as a function of ψ, compared with the values of their corresponding monosaccharides (Table 8.5).
320
8. Nuclear Magnetic Resonance of Glycosides
TABLE 8.4. 1 H chemical shifts and couplings (3 JH-H ) of natural O- and C-glycosides Natural glycoside O
O
HO
H-3
H-4
H-5
4.63 d(8.0)
3.17 dd (8.0, 9.0)
3.36 t (9.0)
3.26 t (9.0)
3.30 m
5.04 d (7.5)
3.50 dd (9.0, 7.5)
3.44 m
3.38 t (9.0)
3.44 m
3.71 dd (5.5, 12.3), 3.91 dd (2.0, 12.3)
15
4.32 d (8.0)
3.59 dd (8.0, 10.0)
3.54 br dd (3.0, 10.0)
3.63 br d (3.0)
3.58 dq (1.0, 6.0)
1.21 d
16
4.88 d (10.0)
5.35 t (10.0)
3.49 m
3.49 m
3.33 m
3.58 dd (5.5, 12.5), 3.78 m
17 Zou et al
3.47 dd (1.9, 9.2)
3.66, t (9.2)
3.76 dd (2.8, 9.2)
5.21 br s
3.37 d (13.1), 3.88 dd (1.8, 13.1)
O 6
6'
14
O
O
HO 4 HO
Ref
H-2
O HO
H-6, H-6’ 3.66 dd (6.0, 12.0); 3.89 dd (2.0, 12.0)
H-1
5 2
3
OH 1
Glc OH
HO
HO
6
6'
O
O
O
HO 4 HO
5 2
3
OH 1
Glc O
HO 1
2 HO 3
O
OH 5
6
Fuc
OH
OH
O
O
6'
O
6
HO HO
4
OH
1
5
O
2
4 3
HO
O
Glc O
OH
OH
CH3 5
1
O 3
4
O
Ph O
HO
OH 2
18 Diaz et al
5.10 5.41 5.38 5.36 5.41 5.41 4.63 4.73 4.63 4.51 — —
3.56 3.55 3.56 3.57 3.59 3.58 3.37 3.37 3.37 3.32 — —
H2
3.80 3.80 3.77 3.76 3.68 3.69 3.52 3.54 3.54 3.52 — —
H3
3.47 3.47 3.47 3.45 3.42 3.42 3.42 3.42 3.42 3.42 — —
H4 3.86 3.86 4.02 4.02 3.72 3.74 3.46 3.49 3.49 3.50 — —
H5 3.85 3.78 3.82 3.82 3.74 3.77 3.75 3.73 3.73 3.75 — —
H6a 3.78 3.78 3.82 3.82 3.74 3.77 3.75 3.73 3.73 3.75 — —
H6b 5.45 4.81 5.24 4.67 5.23 4.66 5.45 5.23 4.74 4.67 5.23 4.67
H1 3.64 3.39 3.63 3.36 3.58 3.28 3.65 3.73 3.44 3.29 3.50 3.27
H2
1 = kojibiose; 2 = nigerose; 3 = maltose; 4 = soforose; 5 = laminaribiose; 6 = cellobiose; 7 = glucose
α-1 β-1 α-2 β-2 α-3 β-3 α-4 α-5 β-5 β-6 α-7 β-7
H1
TABLE 8.5. Chemical shifts of disaccharides and anomers of glucopyranose. 3.83 3.59 3.86 3.64 3.97 3.77 3.87 3.92 3.74 3.60 3.71 3.45
H3 3.47 — 3.67 3.64 3.64 3.62 3.47 3.52 3.49 3.65 3.36 3.35
H4 4.03 — — 3.48 3.93 3.60 3.87 3.88 3.49 3.58 3.82 3.82
H5
3.85 3.90 — — 3.82 3.92 3.84 3.85 3.90 3.97 — —
H6a
3.76 3.56 — — 3.82 3.77 3.77 3.79 3.74 3.82 — —
H6b
8.1. NMR of O-Glycosides 321
322
8. Nuclear Magnetic Resonance of Glycosides FIGURE 8.3. Torsion angles around the glycosidic bond. O O
O
ψ
θ
The development of Karplus relationship for three-bond C-O-C-C spin-coupling constants by Bose et al.24 suggests that 3 JCOCC obeys a Karplus relationship similar to that observed for 3 JHH ,3 JHC , and other vicinal spin-coupling constants. However, the precise form of this relationship that is the shape and amplitude of the Karplus curve is unknown. Also in this work, 3 JCOCH values have been measured to asses the phi (φ) and the psi (ψ) torsion angles (Figure 8.4) and Karplus relationships have been reported for this vicinal coupling.25 Comparative conformational studies using a combination of NMR spectroscopy and molecular mecanics of lactose disaccharide (βGal[1-4]Glc) and its C-analog showed that for the former the population in solution is about 90% syn and 10% anti, while for the latter the conformation is more flexible in the forms 55%, 40%, and 5% syn, anti, gauche-gauche, respectively.26 1 H NMR spectra of oligosaccharides follows in many cases complex patterns due to extensive overlap within the region δ 3.0-4.2. However, the use of pyridine-d5 improves the signal dispersion, increasing the resolution especially in overcrowded regions. The localization of anomeric protons is a valuable tool for recognizing the number of monosaccharide residues. A number of one- and two-dimensional methods provide thorough information to assert the complete assignment unambigiously. One-dimensional NMR analysis provides useful information about the chemical shifts and scalar couplings of well-resolved signals such as anomeric protons (δ 4.4-5.6) and methyl groups for 6-deoxy monosaccharides (fucose, quinovose, ramnose) at (δ 1.1-1.3). The effect on the proton chemical shift of glycosylation is a typical deshielding of the proton across the glycosidic bond and the two neighboring positions of the aglycone. This behavior is due to repulsion between hydrogens and to the effect of the lone pair of the oxygen to the hydrogens.27
CH2OH
CH2OH
O φ C1 C2
HO HO
JC1,C4´,
3
OH
JC2,C4´,
3
ψ
H1 H4
couplings sensitive to 2
O
C5´ C4´ C3`
O
OH
HO
φ
JC4´,H1
O
couplings sensitive to 2
JC1,C3´,
3
JC1,C5´,
3
JC1,H4´
ψ
FIGURE 8.4. Couplings sensitive to φ and ψ torsion angles.
8.1. NMR of O-Glycosides
323
Conformational analysis on more complex glycosides is based mainly on the inter-residue 1 H-1 H Nuclear Overhauser effects (NOE).28 and also 13 C-1 H longrange coupling constants across the glycosidic linkage for studying the preferred conformation of oligosaccharides in solution. Selective irradiation of the anomeric proton reveals inter-residual contacts with aglycone protons. In this way 1→2, 1→3, 1→4, and 1→6 combinations as well as −α and −β linkages may be determined.29 Long-range 1 H-1 H couplings involving four bonds between anomeric and aglycone protons (4 JHCOCH ) are usually very small that could be detected but not measured.30 Two-dimensional NMR is a reliable method for determining inter-ring connectivity. Through space dipolar interactions between the anomeric and the trans glycosidic proton can be detected in the form of NOE signals and represent the basis for linkage and sequence analysis.31 Also, the interglycosidic connectivities are established on the basis of long-range (3 JCH ) by HMBC studies.27 The usefulness of this method has been later demonstrated in a number of structural elucidations.32 Bidimensional homonuclear techniques such as the TOCSY experiment have been useful for the NMR characterization of the naturally occurring complex glycosides such as glycoresin tricolorin E,33 allowing the total assignment of the sugar region, including the anomeric protons for each of the 4 monosaccharides established (Figure 8.5). Likewise, the complete 1 H and 13 C assignments of a synthetic octasaccharide fragment of the O-specific polysaccharide of Shigella dysenteriae type 1 by using 2D TOCSY at 600 MHz was described. In the contour plot it is possible to observe the connectivity between the sugar units and the detailed assignment of the protons.34 Moreover, a 2D selective TOCSY-DQFCOSY experiment for identification of individual sugar components in oligosaccharides is described, assuming that unambiguous sequential assignment of the proton signals for individual components is reached.35 High-resolution 1 H NMR spectroscopy has been applied in the structural analysis of glycoproteins. The initial efforts to assign all the anomeric and nonanomeric protons were done by using spin decoupling and nuclear Overhauser spectroscopy.36 Nuclear magnetic resonance of carbohydrate related to glycoconjugates has been analyzed. One of the first high-resolution studies was reported back in 1973 on intact glycolipids in a 220-MHz magnet.37 Subsequent studies on underivatized and permethylated glycosphingolipids in dimethylsulfoxide-d6 and chloroform, respectively, allowed one to assign all the anomeric protons and a number of nonanomeric proton resonances.38 Early studies on high-resolution NMR. spectra of glycans chain in D2 O allowed one to assign the anomeric and nonanomeric protons as well as the coupling constants of sugar residues found in glycoproteins.36,39 More recently, the complete resolution of acetyl protected sialic acid glycopeptides was achieved by using NOESY and DQF-COSY technique.6 For the NMR-analysis of carbohydrate-protein complexes the transfer nuclear Overhauser effect (trNOE) experiment seems to be a promising alternative.40
324
8. Nuclear Magnetic Resonance of Glycosides
FIGURE 8.5. Expanded region of TOCSY spectrum for characterization of tricolorin E.
Recent advances on conformational analysis of oligosaccharides allows to determine the inter-residue interactions based on the dihedral angles φ and ψ along the interglycosidic linkage.41 In this connection, recent conformational advances on E-selectin-sialyl Lewisx complex have led to the determination of the bioactive conformation of the silayl Lewisx tetrasaccharide.42
8.2. N-Glycosides
325
NMR spectroscopy of glycoproteins has been achieved by using a combination of homo- and heteronuclear experiments at natural abundance.43 Increased refinement is possible when a 15 N-labeled sample was used and the mobility of the glycan chain could be assessed by the measurements of 13 C line widths obtained from the high-resolution HSQC spectra.41
8.2 N-Glycosides The conformational analysis of N-glycosides has been extensively studied on the basis of chemical shifts and coupling constant determinations mainly around the C-N linkage. Torsion angles symbolized as χ for furanosides rings are also dependent on the Karplus equation, and similarly plays an important rule for the conformational analysis of 5-member rings.44 For purines the angle χ is formed between O4 -C1-N9-C4 atoms, and O4 -C1-N1-C2 for pyrimidines. When torsion angles O4 -C1 N9-C4 for purines, and O4 -C1-N1-C2 for pyrimidines are eclipsed, then χ = 0◦ . Positive angles of χ occurs for rotation clockwise for N9C4 for purines and N1-C2 for pyrimidines. The conformation syn in nucleosides corresponds to the angle χ = 0 ± 90◦ , and anti to 180 ± 90◦ (Figure 8.6). Regarding furanoside rings, there are different nonplanar conformations possibly assumed in terms of five endocyclic torsion angles symbolized as v0 , v1 , v2 , v3 , v4 , corresponding to the bonds O4 -C1 , C1 -C2 , C2 -C3 , C3 -C4 , and C4 -O4 . The two most common conformations founded are the envelope (E), referring to 4 atoms on the plane, and twist (T) for 3 atoms on the plane. The puckering of the furanoside rings of nucleosides is explained by Sorenssen et al.45 Unmodified nucleosides are present as an equilibrium between the C-3 -endo conformation, located around P = 18◦ , and the C-2 -endo conformation centered around P = 162◦ (Figure 8.7). Besides the torsion angle described for the N-glycosidic bond, there are for the case of oligosaccharides, additional torsion angles symbolized as ω,ω ,φ,φ ,ψ,
O
O
HO
N O
OH OH anti
N
HN
NH O
O HO
N O
OH OH syn
NH2
NH2
HO
N O
N N
N
N
N
N HO
O
OH OH anti
FIGURE 8.6. Syn-anti conformations for purines and pyrirmidines.
OH OH syn
326
8. Nuclear Magnetic Resonance of Glycosides OH
B O
3 2T 2E
3
E
0o
OH
342
o
18o
North
OH
4E
O B
B
oE
O
270o
90o
198o 3E
South 180
o
E
1E
162o
o 2
E
2
3T OH
B O
FIGURE 8.7. Pseudorotacional cycle of the furanoside ring in nucleosides.
and ψ corresponding to the bonds P-O5, P-O3 , O5 -C5 , O3 -C3 , C5 -C4 , C4 O3 , respectively (Figure 8.8). The vicinal coupling constants at 3 bond distance are dependent of the dihedral angle θ, and the relationship determined by the Karplus equation. 3
JHH = A cos 2θ − B cos θ + C
where A, B, and C are constants and their values are given in Table 8.6.
ω
P O
φ ψ
O
O P
N
χ
OH
FIGURE 8.8. Torsion angles for oligosaccharides.
8.2. N-Glycosides
327
TABLE 8.6. Karplus A, B, C constant values for nucleotide molecular fragments. torsion angle HO-CH-CH-OH H-C-C-H H-C-O-H
H-C-O-P
sugar ring ψ φ φ φ φ
J (Hz) J1 2 ,
J2 3 ,
J4 5 , J4 5 J2 OH2 J3 OH3 J5 OH5 J3 P J5 , J5
J3 4
A
B
C
10.2 9.7 10.4
0.8 1.8 1.5
0 0 0.2
18.1
4.8
0
TABLE 8.7. 3 J2 3 (Hz) values for furanoside ring in nucleosides. Nucleoside β-D-ribonucleosides pyrimidine (anti) pyrimidine (syn) purine (anti) purine (syn) β-D-deoxyribonucleosides pyrimidine (anti) pyrimidine (syn) purine (anti-syn) C-nucleoside pyrimidic C-nucleoside puric
3 J +3 1 2 J3 4
3J 23
(Hz)
(Hz)
9.9 (± 0.2) 10.3 (± 0.2) 9.7 (± 0.3) 9.6 (± 0.3)
5.3 (± 0.2) 6.2 (± 0.2) 5.2 (± 0.1) 5.5 (± 0.2)
10.6 (± 0.2) 11.0 (± 0.1) 6.3 (± 0.1) 10.6 (± 0.3) 10.1 (± 0.3)
6.7 (± 0.2) 8.0 (± 0.1) 6.3 (± 0.1) 5.2 (± 0.2) 5.0 (± 0.2)
The exchange of –OH for -OPO3 does not affect sensibly the Karplus relationship; therefore, the values are valid for both nucleosides or oligonucleosides. However, as mentioned, 3 J there is a dependence of other factors such as bond length, bond angle, electronegativity, and substituent orientation. Some of the values reported for ribose and deoxyribose are described in Table 8.7. The analysis of the C-Nucleosides β-pseudouridine (β–ψ) and α-pseurouridine (α–ψ) in aqueous solution have been described and the observed coupling constants given in Table 8.8.1b TABLE 8.8. Coupling constant (Hz) for β- and α-pseudouridine at 30◦ Coupling constant J61 J1 2 J2 3 J3 4 J4 5 B J4 5 C J5 B5 C
β–ψ 0.8 5.0 5.0 5.2 3.2 4.6 −12.7
α–ψ 1.3 3.3 4.2 7.9 2.4 5.7 −12.7
328
8. Nuclear Magnetic Resonance of Glycosides
References 1. (a) R.U. Lemieux and A.R. Morgan, Can. J. Chem., 43, 2199 (1965). (b) G. Kotowycz and R.U. Lemieux, Chem. Rev., 73, 669 (1973). (c) R.U. Lemieux and J.D. Stevens, Can. J. Chem., 43, 2059 (1965). 2. B. Coxon, Tetrahedron, 21, 3481 (1965). 3. (a) L.D. Hall, Adv. Carbohydr. Chem., 19, 51 (1964). (b) L.D. Hall, J.F. Manville, and N.S. Bhacca, Can. J. Chem., 47, 1 (1969). 4. D. Horton, and J.H. Lauterbach, Carbohydr. Res., 43, 9 (1975). 5. C. Altona, and C.A.G. Haasnoot, Organic Magnetic Resonance, 13, 417 (1980). 6. E. Breitmaier, Structure Elucidation by NMR I Organic Chemistry 3th Ed. John Wiley & Sons pp 46 (2002). 7. M. Karplus, Chem. Phys., 11, 30 (1959). 8. C.M. Cerda-Garc´ıa-Rojas, L. G. Zepeda, and P. Joseph-Nathan, Tetrahedron Computer Methodology, 3, 113, (1990). 9. C.V. Holland, D. Horton, M.J. Miller, and N.S. Bhacca, J. Org. Chem., 32, 3077 (1967). 10. G. Hajdukovic, M.L. Martin, P. Sina¨y, and J.R. Pougny, Organic Magnetic Resonance 7, 366 (1975). 11. D. Horton and W. N. Turner, J. Org. Chem. 30, 3387 (1965). 12. K. Bock and H. Thøgerson, Annual Reports on NMR Spectroscopy Ed by G.A Webb, Academic Press 13, 37 (1982). 13. J. Ø Duus, C.H. Gotffredsen, and K. Bock, Chem. Rev., 100, 4589 (2000). 14. A. Delazar, M. Byres, S. Gibbons, Y. Kumarasamy, M. Modarresi, L. Nahar, M. Shoeb, and S. D. Sarker, J. Nat. Prod. 67, 1584 (2004). 15. G. Bohr, C. Gerh¨auser, J. Knauft, J. Zapp, and H. Becker, J. Nat. Prod. 68, 1545 (2005). 16. S.O. Lee, S. Z. Choi, S. U. Choi, K. C. Lee, Y. W. Chin, J. Kim, Y. C. Kim, and K.R. Lee, J. Nat. Prod. 68, 1471 (2005). 17. J-H Zou, J.S. Yang, and L. Zhou, J. Nat. Prod. 67, 664 (2004). 18. F.Diaz, H-B Chai, Q.Mi, B-N.Su, J.S.Vigo, J.G. Graham, F.Cabieses, N.R. Farnsworth, G.A. Cordell, J.M. Pezzuto, S.M. Swanson, and A. D.Kinghorn, J. Nat. Prod. 67, 352 (2004). 19. P. Manitto, D. Monti, and G. Speranza, J. Chem. Soc. Perkin Trans. 1, 1297 (1990). 20. H. Neubauer, J. Meiler, W. Peti, and C. Griesinger, Helv. Chim. Acta, 84, 243 (2001). 21. F. Tian, H.M. Al-Hashimi, J.L. Craighead, and J.H. Prestegard, J. Am. Chem. Soc., 123, 485 (2001). 22. A. De Bruyn, J. Carbohydr. Chem., 10, 159 (1991). 23. R.U. Lemieux and S. Koto, Tetrahedron, 30, 1933 (1974). 24. B. Bose, S. Zhao, R. Stenutz, F. Cloran, P.B. Bondo, G. Bondo, B. Hertz, I. Carmichael, and A.S. Serianni, J. Am. Chem. Soc., 120, 11158 (1998). 25. K. Bock, A. Brignole., and B.W. Sigurskjold, J. Chem. Soc. Perkin Trans. II, 1711 (1996). 26. A. Imberty, Current Opinion in Structural Biology, 7, 617 (1997). 27. P.K. Agrawal and A.K. Pathak, Phytochemical Analysis, 7, 113 (1996). 28. I. Tvaroska, M. Hricovini, and E. Petrakova, Carbohydr. Res., 189, 359 (1989). 29. (a) Y.S. Bae, J.F.W. Burger, J.P. Steynberg, D. Ferreira, and R.W. Heminway, Phytochemistry, 30. (a) G. Batta and A. Liptak, J. Am. Chem. Soc., 106, 248 (1984). (b) G. Masiiot, C. Lavaud, C. Delaude, G.V Binst, S.P.F. Miller, and H.M. Fales, Phytochemistry, 29, 3291 (1990).
References
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31. J.H. Prestegard, T.A.W. Koerner, P.C. Demou, and R.K. Yu. J. Am. Chem. Soc., 104, 4993 (1982). 32. (a) N.M. Duc, R. Kasai, K. Ohtani, A. Ito, N.T. Nham, K. Yamasaki, and O. Tanaka, Chem. Pharm. Bull., 42, 634 (1994). (b) T. Nakamura, T. Takedo, and Y. Ogihara, Chem. Pharm. Bull., 42, 1111 (1994). (c) B. Razanamahefa, C. Demetzos, A.-L Skaltsounis, M. Andriantisiferana, and F. Tillequin, Heterocycles, 38, 357 (1994). (d) T. Nakanishi, K. Tanaka, H. Murata, M. Somekawa, and A. Inada, Chem. Pharm. Bull, 41, 183 (1994). (e) S.T. Thulborg, S.B Christensen, C. Cornett, C.E. Olsen, and E. Lemmich, Phytochemistry, 36, 753 (1994). 33. (a) M. Bah and R. Pereda-Miranda, Tetrahedron, 41, 13063 (1996). (b) R. PeredaMiranda and M. Bah, Current Topics in Medicinal Chemistry, 3, 1 (2003). 34. B. Coxon, N. Sari, G. Batta, and G. Pozsgay, Carbohydr. Res., 324, 53 (2000). 35. H. Sato, and Y. Kajihara, J. Carbohydr. Chem., 22, 339 (2003). 36. F.G.J. Vliegenthart, L. Dorland, and H. van Halbeek, Adv. Carbohydr. Chem. Biochem., 41, 209 (1983). 37. M. Martin-Lomas and D. Chapman, Chem. Phys, Lipids, 10, 152 (1973). 38. (a) J. Dabrowski, P. Handfland, and H. Egge, Biochemistry, 19, 5652 (1980). (b) K.E. Falk, K.-A. Karlsson, and B.E. Samuelson, Arch. Biochem. Biophys., 192, 164 (1979). 39. L.S. Wolfe, R.G. Senior, and N.M.K. Ng Yin Kin, J. Biol. Chem., 249, 1838 (1974). 40. (a) F. Ni, Prog. Nucl. Magn. Reson Spectros., 26, 517 (1994). (b) F. Casset, T. Peters, M. Etzler. E. Korchagina, S. Nifantev, Perez, and A. Imberty, Eur. J. Biochem., 239, 710 (1996). 41. (a) T. Peters, and B.M. Pinto, Current Opinion in Structural Biology, 6, 710 (1996). (b) T. Weimar, S.L. Harris, .J.B. Pitnar, K. Bock, and B.M. Pinto, Biochemistry, 34, 13672 (1995). 42. K. Scheffler, B. Ernst, A. Katopodis, J.L. Magnani, W.T. Wang, R. Weisemann, and T. Peters, Angew. Chem. Int. Ed., 34, 1841 (1995). 43. (a) D.F. Wyss, and J.S. Choi, and G. Wagner, Biochemistry, 34, 1622 (1995). (b) D.F. Wyss, J.S. Choi, J. Li, M.H. Knoppers, K.J. Willis, A.R.N. Arulandaman, A. Smolyar, E.L. Reinherz, and G. Wagner, Science, 269, 1273 (1995). (c) R. Liang, A.H. Androtti, and D. Kahne, J. Am. Chem. Soc., 117, 10395 (1995). 44. D. Davies, Progress in NMR Spectroscopy, 12, 140 (1978). 45. M.H. Sorenssen, C. Nielsen, and P. Nielsen, J. Org. Chem., 66, 4878 (2001).
9 X-Ray Diffraction of Glycosides
X-ray crystallography is a powerful tool for obtaining molecular information regarding bond lengths, bond angles, hydrogen bond interactions, and torsion angles, which are necessary elements for understanding the conformation of glycosides. Improved diffractometers, faster computational processors, and newer mathematical programs have made possible the structural resolution of simple and complex substances of glycosidic nature particularly those with noncentrosymmetric space groups. Early studies on simple glycosides allowed to confirm that the sugar residue is pyranoid (and not acyclic), assuming two possible chair conformations (4 C1 and 1 1 4 C ), usually orienting the substituent to the equatorial position. In hydrogen bond interactions on pyranoids some facts that almost occur invariably are (a) the ring-oxigen atom is always a hydrogen bond acceptor, (b) each hydroxyl group is associated with two hydrogen bonds, one as donor and one as acceptor, (c) in disaccharides there might be intramolecular hydrogen bonding between two residues, (d) the hydrogen bond O-O distance has values around 2.68 ˚ to 3.04 A. Crystallographic observations on the anomeric effect demonstrated that the bond shortening and preferred gauche conformation of the glycosidic bonds in pyranoses was a consequence of an electronic distribution in the hemiacetal and acetal moiety of these molecules.2 On the other hand, the primarily alcohols can be present in three staggered orientations, defined as gg, gt, and tg, refering to torsion angles O5-C5-C6-O6 and the second to C4-C5-C6-O6 [g ± 60◦ , t 180◦ ]. An alternative nomenclature refers O5-C5-C6-O6 as +g = gt, −g = gg, t = tg. The general standard molecular dimensions for pyranosides are described in Table 9.1, being the C-C bond length in the range of 1.523–1.526, C-C-C angles 110.4–110.5◦ , and usually shorter glycosidic bond 1.398 for axial and 1.385 for equatorial disposition (Table 9.1).3 The distortion degree from the ideal chair conformation has been studied by Cremer and Pople,4 who, by following a mathematical approximation, were able to propose three puckering parameters described as spherical polar set Q (total puckering amplitude), and the angles θ and φ, describing the distortion suffered 330
9.1. X-Ray Diffraction of O-Glycosides
331
TABLE 9.1. Standard molecular dimensions for 4 C1 chair conformations in pyranosides. Bond ˚ lengths (A)
Bond ˚ lengths (A)
C-C ring C-C exo C-O exo
1.526 1.516 1.420
1.523 1.514 1.426
C5-O5 axial C1-O5 axial C1-O1 axial C5-O5 eq. C1-O5 eq.
1.434 1.419 1.398 1.426 1.428
1.436 1.419 1.415 1.436 1.429
Bond type
Angle type
Bond angle (◦ )
Bond angle (◦ )
C-C-C ring C-C-C exo C-C-O ring C-C-O exo C5-O5-C1 O5-C1-O1 C5-O5-C1 O5-C1-O1
110.4 112.5 110.0 109.7 114.0 112.1 112.0 108.0
110.5 112.7 110.0 109.6 114.0 111.6 112.0 107.3
4 atoms ring
Torsion angles (◦ )
C-C-C-C C-C-C-O C-C-O-C C-C-C-C C-C-C-O
53 56 60 53 57
C pole
θ HB
HC
Q φ
B
equator
TB
FIGURE 9.1. One octant of the sphere on which the conformations of six-membered rings can be mapped for a constant Q.
by six-member rings from the ideal chair conformation. The chair corresponds to θ = 0◦ , φ = 0◦ ; boat for θ = 90◦ , φ = 0◦ ; and twist boat for θ = 90◦ , φ = 90◦ (Figure 9.1). The pyranoside ring varies slightly and in terms of Cremer and Pople ˚ with θ within 5◦ of puckering parameters, the range of values is Q = 0.55–0.58 A ◦ 3 0 or 180 .
9.1 X-Ray Diffraction of O-Glycosides One of the pioneering studies about sugar X-ray analysis was presented by Levy and Brown5 reporting the structure of sucrose and sucrose NaBr.H2 O. Through these studies it was observed that although they were energetically equivalent, the chair conformation was different, due to slight hydrogen bridge interactions on the furanoside moiety (Figure 9.2).
332
9. X-Ray Diffraction of Glycosides
FIGURE 9.2. X-ray diffraction of sucrose and sucrose NaBr.H2 O.
Another disaccharide characterized by X-ray crystallography was octa-Oacetyl-β-D-cellobiose, which presents space group P21 ,21 ,21 , with both pyranoside residues in 4 C1 chair conformation slightly more distorted in comparison with cellobiose. Moreover, the torsion angles determined were for O5-C1-C4 −77◦ , and for C1-O1-C4-C5 104◦ (Figure 9.3). The sign value indicates according with the Klyne & Prelog notation to the right if positive and to the left if negative.6
FIGURE 9.3. Chair conformation for octa-O-acetyl-β-D-cellobiose.
9.1. X-Ray Diffraction of O-Glycosides
333
FIGURE 9.4. Thermal ellipsoid drawing and packing diagram showing the hydrogen bonding along [001] of phenyl methyl 2,3,4,-tri-O-acetyl-b-D-fucopyranoside.
The crystal structure of benzyl 2,3,4-tri-O-acetyl-β-D-fucopyranoside is described,7 presenting a monoclinic system, space group P21 , with bond distances ˚ C-C 1.513 A, ˚ and shorter C-O 1.380 A ˚ for equatorially anomeric C-O 1.423 A, bond. The angle disposition for the endocyclic bond C1-O5-C5 is of 112.4 (3)◦ , being this value typical for chair conformation 4 C1 in pyranoside with substituents positioned at equatorial positions. The perspective view of the molecule shows equatorial disposition for all substituents except position 4 that remains axial (Figure 9.4).
334
9. X-Ray Diffraction of Glycosides
FIGURE 9.5. Perspective Ortep view of phenylmethyl glucosyl fucopyranosyl derivative showing the distortion degree between 5- and 6-member fused rings on chair conformation.
Disaccharide phenylmethyl-O-(2,3-di-O-acetyl-4,6-O-benzylidene-β-D-glucopyranosyl)-(1→2)-3,4-O-isopropylidene-β-D-fucopyranoside shows for fucopyranoside moiety a distorted chair due the five-member ring acetonide at O3 and O4 positions, with Cremer and Pople puckering parameters of Q = 0.556 (3), θ = 159.9 (3)◦ , and φ = 220.8 (8)◦ . In contrast for the glucopyranosyl moiety with a six-member ring benzylidene ring attached at positions O4 and O6, the chair conformation is less distorted with Cremer and Pople puckering parameters of Q = 0.597 (3), θ = 170.5 (3)◦ , and φ = 156.0 (16)◦ (Figure 9.5).8 The solid-state crystal structure of glycoresin tricolorin A was solved by using an intense syncroton radiation to collect data. The cystals belongs as usual to the P21 having cell dimensions a = 14.025(1), b = 33.337(1), c = 25.512(1) ˚ β = 91.07(1)◦ . The energy maps were calculated as a function of two glycoA, sidic linkage torsion angles defined as φ = (O5-C1-O1-Cx) and ψ = (C1O1-Cx-C(x+1), indicating a higher level of conformational freedom along the ψ-axis. The size of the crystal unit cell demonstrate the presence of four independent tricolorin A molecules per asymmetric unit and the refined structure showed the presence of 18 water molecules forming a channel along the hydrophilic region (Figure 9.6).9 Other selected pyranosides analyzed by X-ray diffraction and their parameters determined are shown in Table 9.2.
9.1. X-Ray Diffraction of O-Glycosides
335
FIGURE 9.6. ORTEP representation of tricolorin A and graphical representation of the unit cell.
336
9. X-Ray Diffraction of Glycosides
TABLE 9.2. X-ray diffraction parameters of some selected pyranosides. Structure
Symmetry cell
OPiv
orthorhombic
Symmetry space P 21 21 21
Conformation
monoclinic
P 21
monoclinic
P21
orthorhombic
P 21 21 21
monoclinic
C2
orthorhombic
P 21 21 21
monoclinic
C2
4C
monoclinic
P21
4C
Ref
4
C1
10
4
C1
11
chair for α-anomer and boat β-anomer
12
OH O HO PivO OMe OCOCH2Ph O N H PhH2COCO
O
PhH2COCO
OMe
O
Ph
O
O PhO2S
HN OMe Ph
Ph N N
OAc
4
C1
13
1 4C
14
4
C1
15
1 4
C1
16
1 4
C1
17
S
O
AcO AcO
S OAc
Me
O N MeOOC
O N OAc O
MeO
NH
OAc
OAc OH
OH O
O OH OH
OH OH Me
O OH
O
O OH HO
OH OMe
OH OH
OH HO O OH
OH
. 5 H2O
O HO
O OMe OH
MeOH
9.2. X-Ray Diffraction of Nucleosides
337
9.2 X-Ray Diffraction of Nucleosides A number of N -glycosides and C-glycosides has been solved by X-ray analysis, presenting as common features space group P21 21 21 orP21 , the furanoside ring in the twist conformation, and symmetric system monoclinic or orthorhombic. For instance, the hypermodified nucleoside queuosine presents a space group ˚ and symmetric P21 21 21 , cell dimensions a = 26.895, b = 7.0707, c = 23.883 A, system orthorhombic (Figure 9.7). The three-dimensional structure determined by X-ray has been also helpful to understand the recognition process at the tRNA level. Thus, based on this information it was possible to determine that the bulky group cyclopentenediol due to the trans disposition assumed is not involved in any interaction codon-anticodon, therefore suggesting that another type of interaction was taken place.18 The unusual conformation of α-D anomer of 5-aza-7-deaza-2 -deoxyguanosine has been reported by Seela et al.19 In this work it is described that the title compound adopts a high-anticonformation with the C1 -C2 and N9-C8 bonds nearly eclipsed with torsion angle C1 -C2 -N9-C8 = 30.3 (4)◦ . It can be also observed that for 2 deoxy-α-D-ribonucleosides the C2’ endo sugar puckering with either a half chair or envelope conformation is preferred (Figure 9.8). The solid-state conformation of constrained carbocyclic nucleosides (N)methano-carba-AZT and N-(S)-methano-carba-AZT was determined by X-ray
FIGURE 9.7. Perspective view of hypermodified nucleoside queuosine.
338
9. X-Ray Diffraction of Glycosides
FIGURE 9.8. Perspective view of α-D anomer of 5-aza-7-deaza-2 -deoxyguanosine.
diffraction. As expected with the prediction, their thermal ellipsoid presented a rigid pseudoboat conformation for the bicycle [3.1.0] hexane system, which makes them assume in nearly perfect 2 E and 3 E envelope conformations in the pseudorotational cycle (Figure 9.9).20 Other selected N-nucleosides that have been analyzed by X-ray diffraction and their parameters determined are shown in Table 9.3.
FIGURE 9.9. X-ray structure of (N)methano-carba-AZT.
TABLE 9.3. N-Glycosides and their X-ray diffraction parameters.
340
9. X-Ray Diffraction of Glycosides
TABLE 9.3. (Continued)
References 1. (a) S. Furberg, and C.S. Petersen, Acta Chem. Scan. 1962, 16, 1539. (b) Reeves, R.E. J. Am. Chem. Soc. 1950, 72, 1499. 2. G.A. Jeffrey, J.A. Pople, J.S. Binkley, and S. Vishveshwara, J. Am. Chem. Soc. 1978, 100, 373. 3. G.A. Jeffrey, Acta Cryst. 1990, B46, 89. 4. D. Cremer and J.A. Pople, J. Am. Chem. Soc. 1975, 97, 1354. 5. G.M. Brown and H.A. Levy, Science, 1963, 141, 921. 6. F. Leung, H.D. Chanzy, S. P´erez,and H., Marchessault, Can J. Chem. 1976, 54, 1365. 7. M.A. Brito-Arias, E.V.Garc´ıa-Baez, E. Dur´an-P´aramo, and S. Rojas-Lima, J. Chem. Crystallogr., 2002, 32, 237. 8. M.A. Brito-Arias, E. Duran-Paramo, I. Mata, and E. Molins, Acta Cryst., 2002, C58, o537. 9. A. Rencurosi, E.P. Mitchell, G. Cioci, S. P´eres, R. Pereda-Miranda, and A. Imberty, Angew. Chem. Int. Ed. 2004, 4, 2. 10. I. Matijasic, G. Pavlovic, and R. Trojko Jr, Acta Cryst., C59, o184 (2003). 11. O. Renaudet, P. Dumy and C. Philouze, Acta Cryst., C57, 309 (2001). 12. C.G. Suresh, B. Ravindran, K.N. Rao, and T. Pathak, Acta Cryst., C56, 1030 (2000). 13. Z.-Z. Qiu, X.-P. Hui, P.-F. Xu, Acta Cryst, C61, O475 (2005). 14. N. Low, C. Garcia, M. Melguizo, J. Cobo, M. Nogueras, A. S´anchez, M.D. L´opez, and M.E. Light, Acta Cryst., C57, 222, (2001).
References
341
15. Z.-H. Cheng, T. Wu, S.W.A. Bligh, A. Bashall, and B.-Y. Yu, J. Nat. Prod. 2004, 67, 1761. 16. L. Eriksson, R. Stenutz, and G. Widmalm, Acta Cryst., C56, 702 (2000) 17. R. Stenutz, M. Shang, and A. S. Serianni, Acta Cryst., C55, 1719 (1999). 18. S. Yokohama, T. Miyazawa, Y., Litaka, Z. Yamaizumi, H. Kasai, and S. Nishimura, Nature, 1979, 107, 282. 19. F. Seela, H. Rosemeyer, A. Melenewski, E.-M. Heithoff, H. Eickmeier, and H. Reuter, Acta Cryst., C58, O142 (2002). 20. V.E. Marquez, A. Ezzitouni, P. Russ, M.A. Siddiqui, H. Ford, Jr., R.J. Feldman, H. Mitsuya, C. Goerge, J.J. Barchi, Jr., J. Am. Chem. Soc. 1998, 120, 2780. 21. F. Seela, P. Chittepu, J. He, and H. Eickmeier, Acta Cryst., C60, O884 (2004). 22. F. Seela, Y. Zhang, K. Xu, and H. Eickmeier, Acta Cryst., C61, O60 (2005). 23. F. Seela, K. Xu, and H. Eickmeier, Acta Cryst., C61, O408 (2005). 24. W. Lin, K. Xu, H. Eickmeier, and F. Seela, Acta Cryst., C61, O195 (2005). 25. F. Seela, K.I. Shaikh, and H. Eickmeier, Acta Cryst., C61, O151 (2005). 26. F. Seela, V.R. Sirivolu, J. He, and H. Eickmeier, Acta Cryst., C61, O67 (2005). 27. W. Lin, F. Seela, H. Eickmeier, and H. Reuter, Acta Cryst., C60, O566 (2004). 28. F. Seela, K.I. Shaikh, and H. Eickmeier, Acta Cryst., C60, O489 (2004). 29. J. W. Bats, J. Parsch, and J. W. Engels, Acta Cryst., C56, 201 (2000). 30. F. Seela, A.M. Jawalekar, and H. Eickmeier, Acta Cryst., C60, O387 (2004).
10 Mass Spectrometry of Glycosides
High-resolution mass spectrometry has become another valuable tool for characterization of simple and complex glycosides. The method is based on the collision of a high-energy electron against a sample under study producing as result a cation radical fragment known as the molecular ion, which should match with the molecular weight of the molecule. The mass spectrum also registers a number of fragments being the most intense the base peak assigned a relative intensity of 100. Mass spectrometry can be applied as high and low ionization experiments, being for the former the most suitable for glycosides electron impact and for the latter fast atom bombardment (FAB) and electrospray ionization the routine experiments for characterization of glycosides. In terms of sensitivity of the measurement this instrumental method requires small amount of sample, even in the order of nanogram quantities. The fragmentation patterns of acetyl-protected pentoses and hexoses was studied and their main m/z fragment established. For instance, for methyl-β-Dxylopyranoside triacetate the main fragment follows the two alternative routes shown in Figure 10.1.1 High ionization experiments such as electron impact has been found to be a suitable approach for the determination of the molecular weight through their corresponding molecular ion of protected glycosides such as peracetylated Oglycosides of low molecular weight. For instance, by using electron impact it was possible to determine the molecular weight, and the common fragmentation patterns, of m/e 331 and 169 (100) of the phenylazonaphtol-β-D-glucopyranoside pentaacetate (Figure 10.2).2 However, for most of nonprotected glycosides, high ionization does not provide reliable information and commonly decomposition is observed due to thermal unstability. The introduction of shoft ionization techniques such as fast atom bombardment (FAB) and electrospray ionization has produced great progress for the structural characterization of simple and complex glycosides. This important analytical procedure is especially useful for determining the molecular weight through detection of the molecular ion, as well as sugar sequence. The choice of the matrix and the solubility of the sample are essential aspects to consider for obtaining
342
10. Mass Spectrometry of Glycosides O OCH3 OAc
O
-CH3O
-CH3COOH
OAc
OAc
m/e: 199 A1 - 60
OAc OAc
343
OAc
A1= M-31 (m/e: 259)
MW 290 -CH3COOH
-CH2CO
m/e: 139
m/e: 97
A2
A3
O OCH3 OAc
-CH2CO
AcO
OAc
m/e 128
-CH2CO
B2 OAc
MW 290
m/e 86 B2-42
OAc
m/e 170 B1
FIGURE 10.1. Fragmentation pattern of methyl-β-D-xylopyranoside.
the best resolution. Glycerol is the matrix most commonly used and it is the best choice for underivatized carbohydrates and glycopeptides. Some other matrices used alternatively for hydrophobic samples are thioglycerol, tetraethyleneglycol, and triethanolamine.3 The use of derivatives also plays an important rule and may improve the spectral interpretation and the sensitivity. The most commonly used derivatives are the per-O-acetyl and the per-O-methyl. Usually for the former the fragmentation pathways are less specific and furnish more information, although the spectrum is more difficult to interpret. For the assignment of the molecular ion it is important to recognize the pseudomolecular ions produced during a FAB experiment, which can be positive-ion and negative-ion mode. In the positive-ion mode the usually present signals are [M+H]+ , [M+NH4 ]+ , [M+Na]+ , and [M+K]+ , and for the negative [M−H]− , and for those molecules that cannot lose a proton [M+Cl]− , or [M+SCN]− . Some of the most common fragmentation pathway produced by polysaccharides and glycoconjugates are represented in Figure 10.3:4 Likewise, application of different ionization techniques in the study of natural glycosides has been performed and derived. From this it has been possible to assign the main potential fragmentation sites in O- and C-glycosides (Figure 10.4).5 Negative ion FAB-MS in triethanolamine of synthetically prepared glycoresin composed by fucose, glucose, and quinovose attached to jalapinolic acid (Figure 10.5) shows [M−H]− peak (m/z 1216) in agreement with the expected molecular weight.6
344
10. Mass Spectrometry of Glycosides
FIGURE 10.2. Mass spectrum of Phenylazonaphtol glucoside.
Mass spectrometry has been also applied successfully for glycoprotein structural determination of primary structure. The first glycoprotein primary structure was determined through electron impact and chemical ionization;7 however, soft ionization methods of fast atom bombardment (FAB), electrospray (ES), or matrixassisted laser desorption ionization (MALDI) are conducting most of the glycoprotein structural determinations. FAB is particularly useful for analyzing the permethyl derivatives of oligosaccharides released from glycoproteins by chemical or enzymatic methods. When the atom or ion beam collides with the matrix, a substantial number of sample molecules are ionized producing positively charged species called quasimolecular ions [M+H]+ and [M+Na]+ .8 In order to optimize fragment ion information of glycoproteins, three approaches are currently being used: inducing fragmentation by collisional activation,
10. Mass Spectrometry of Glycosides
345
Pathway A
CH2OH
CH2OH
O
+
O
O
O
O HO
CH2OH
OH
O HO
+
H
+
O
OH
HO
OH
Pathway B
CH2OH
CH2OH
O
+ or –
O
+ or –
CH2OH
O
O
O
O
+ or –
H
HO
O
+ or –
H
H HO
HO
OH
OH
HO
OH
Pathway C
CH2OH
CH2OH
O O
O O
H OH
OH
+ or –
CH2OH
O O
HO
+ or –
+ or –
H
O
OH
OH HO
+ or –
H
OH
Pathway D CH2OH
CH2OH
O
+ or –
+ or –
CH2OH
O O
O
O
O H
HO
OH
+ or –
+ or –
H OH
O
H O
O
OH HO
OH
FIGURE 10.3. The most common fragmentation pathways.
H
346
10. Mass Spectrometry of Glycosides
Pathway E
CH2OH
CH2OH
O
+ or –
+ or –
CH2OH
O
O O
O H HO
+ or –
O
OH
H
+ or –
O OH
H
O
OH
OH HO
OH
FIGURE 10.3. (continued)
monitoring natural ionization-induced fragmentation, and selecting derivatives that enhance and direct fragmentation. During collisional activation of collected fractions from an enzymatic digest, the first step is to identify in the MS mode the fractions containing sugar fragmentions. Then switching to the MS/MS mode of a doubly or triply charged ion a composite spectrum containing fragmentation of saccharide and peptide is obtained. Since glycosidic bonds are weaker than peptide bonds, the basic oligosaccharide sequence is determined.9 The natural fragmentation approach relies on the fragmentation created by internal energy transfer to the ion during the ionization process, and now is becoming most limited in use than the previous one.10
Gly
O
Aglycone Gly
C
Aglycone
S
A + frag S A
A A + Gly'
S A + Gly S'
Gly'
O
Gly
O
S + S'
Gly'
Aglycone A
O
Gly
O
Aglycone
S' A + Gly
S, S' = free sugar unit
A
A = aglycone Gly, Gly' = inked glycosidic unit
FIGURE 10.4. The main potential fragmentation sites in O- and C-glycosides.
10. Mass Spectrometry of Glycosides
347
FIGURE 10.5. FAB-MS negative mode of synthetically prepared protected glycoresin.
Derivatization methods are likewise divided into tagging of reducing ends and protection of most of all of the functional groups. The first type facilitates chromatographic purifications and enhances the formation of reducing end fragment ions. The second type involves primarily the permethylation, which form abundant fragment ions arising from cleavage on the reducing side of each HexNAc residue. The permethylation of Tamm-Horsfall glycoprotein was effected and the FAB mass spectrum obtained, showing molecular ions for core 2-type structures carrying up to three sialyl Lex moieties (Figure 10.6).11
348
10. Mass Spectrometry of Glycosides
FIGURE 10.6. Partial FAB mass spectrum of permethylated O-oligosaccharides from glycoprotein uromodulin.
References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
K. Bieman, J. Am. Chem. Soc. 85, 2289 (1963). M. Brito-Arias, unpublished results. K. Harada, M. Suzuki, and H. Kambara, Org. Mass. Spectrom, 1982, 17, 386. M. Dell, Advances in Carbohydrate Chemistry and Biochemistry, 1987, 45, 19. J.-L. Wolfender, M. Maillard, A. Marston, and K., Hostettman, Pytochemical Analysis, 1992, 3, 193. M.A. Brito-Arias, R. Pereda-Miranda, and C.H. Heathcock, J. Org. Chem., 2004. Morris, et al., J. Biol. Chem. 1978, 253, 5155. A. Dell and H.R. Morris, Science, 2001, 291, 2351. Teng-umnuay et al., J. Biol. Chem. 1998, 273, 18242. A. Dell, Adv. Carbohydr. Chem. Biochem. 1987, 45, 19. R.L. Easton, M.S. Patankar, G.F. Clark, H.R. Morris, and A. Dell, J. Biol. Chem. 2000, 275, 21928.
Index
A Abacavir, 179, 220 Acarbose, 35 Aceptor, 95 Acetate, 46, 145 Acetobromoglucose, 39, 40 Acetonide, 49 Acyclovir, 223, 224 Adenosine, 157 Adenosine triphosphate, 138 Aldohexoses, 318 Aldopentoses, 318 Aldolases, 22 Aldol condensation, 22 Aloin, 247 Altromycin B, 247 Aminosugars, 29 Anomeric effect, 38 Antigens Globo H, 112 KH-1, 292 Lewis, 292 MBr1, 292 Antisense, 172 Antivirals, 179 Aristeromycin, 210, 219 Armed-Disarmed approach, 95, 96 Arthrobacilin A, 109 Aurodox, 247 AZT, 191
B Benzoyl, 47, 145 Benzyl, 47, 146 Benzylidene, 50 Biosynthesis, 11 Bleomycin, 74
Boronate, 50 Brigl epoxide nmr spectrum, 101 preparation, 100
C Cadeguomycin, 155 Calcitonine, 283 Calicheamicin, 82 Capuramycin, 138, 195 Carbapyranosides, 34 Carbonate, 50 Carbovir, 220 Carminic acid, 247 Castanospermine, 28 Cellobiose, 332 Cellulase, 308 Chair conformation 1, 3, 4 Chromophores, 310 Concanavalin, 279 Cross-metathesis, 260 Cucumerin, 247 Cyclodextrin, 124 Cytidine, 161
D Deazapurines, 155 Deoxynojirimycin, 27 Disaccharides, 319 Disarmed sugars, 95, 96 Donor, 39, 95
E Electrospray, 344 Eleutherobin, 88
349
350
Index
Epirubicine, 77 Exoglycals, 265
F Fast atom bombardment, 344 Fischer projections 3–7 Fluoresceine, 310 Formycin, 2002, 207 Fucose, 72, 272, 333 Furfural, 10
G Galactose, 16, 272 Ganglioside, 81, 115 Gentobiose, 75 Glycal nmr spectrum, 99 preparation, 98 Glucanase, 308 Glucosamine N-acetyl, 272 Glucuronidase, 308 Glycans, 274 Glyceraldehyde, 6 Glycosidase, 308 Glycosides alpha, 104, 110 cis, 73 reactivity, 35 trans, 73 Glycosyltransferases, 113–115 Guanosine, 157
H Heck type reactions, 166, 167 Herbicidin, 247 Hikizimycin, 138
I Iminosugars, 25 Imidate formation, 82 Imidate reaction, 81 nmr spectrum, 82 Indole O-glycoside, 311
J Jalapinolic acid, 83
K Kanamacin A, 77 Karplus, 315, 316 Kifunensine, 28 Kiliani-Fischer synthesis, 9
L Lactosamine, 117 Laminaribiose, 74 Lasalocid A, 247, 255 Leaving group, 35 Lectins, 277 Lipase, 142 Lodenosine, 193 Lubocavir, 219 Luganol, 108
M Malayamycin A, 207, 209 Mannose, 272 Mannostatin, 28 Methoxybenzyl, 48 Monosaccharides definition, 1 distribution, 2 reactions, 3–11
N Nectricine, 28 Neplanocin, 210, 221 Nicotinic acid adenine dinucleotide, 138 Nikkomycin B, 138 p-Nitrophenol, 311 Nojirimycin, 29 Nuclear Overhauser effect, 317, 323 Nucleosides, 138, 155, 179, 327
O Octosyl acid A, 138 Oxidations, 3–5
P Palladium type reactions, 166, 167, 187 Palytoxin, 247 Phenylazonaphtol glycoside, 312, 344 Phosphonate, 172 Phosphoramidite, 170
Index Pseudouridine, 202, 205, 327 Pyramicine, 202 Pyrazomycin, 202 Pivaloyl, 47, 145 Protecting groups, 43 Puckering parameters, 330
Q Queuine, 195 Queuosine, 138, 337 Quitinase, 308
R Rafinose, 77 Rearrangements enediol, 9 Pummerer, 241 Ramberg-B¨acklund, 21, 262 sigmatropic, 110 Residual dipolar coupling, 318 Resorufin, 310 Rhodiooctanoside, 117 Ruff degradation, 10
S Samarium, 260 Sangivamicine, 154 Saponarin, 247 Scoparin, 247 Selectins, 84, 281 Showdomycine, 202, 206 Sialic acids, 12, 272 Sialyl Lewis, 104 Silyl protecting groups, 146, 147, 160 Sinefungin, 138 Spongistatin, 247 Sucrose, 331
Sugar amino acids, 18 Sulfotransferases, 117 Swainsonine, 28
T Tebbe reagent, 265 Thiazofurine, 202, 205 Thioglycosides, 89 Thiomonosaccharides, 34 Thionucleosides, 228 Thuringiensin, 138 Transglycosylation, 117 Tricolorin, 83, 324, 334 Toluyl, 145 Toyocamicine, 154 Trans rule, 157 Triciribine, 200 Trityl, 47, 146 Tubercidine, 154 Tunicamycin V, 138, 198
U Umbelliferone, 70, 310 Umpolung, 257
V Vineomicinone B2, 256
W Wang resin, 121 Wittig-type reaction, 265 Wye base, 138
X Xylose, 272, 343
351