Glycosyl fluorides in enzymatic reactions

Glycosyl fluorides have considerable importance as substrates and inhibitors in enzymatic reactions. Their good combination of stability and reactivity has enabled their use as glycosyl donors with a variety of carbohydrate processing enzymes. Moreover, the installation of fluorine elsewhere on the carbohydrate scaffold commonly modifies the properties of the glycosyl fluoride such that the resultant compounds act as slow substrates or even inhibitors of enzyme action. This review covers the use of glycosyl fluorides as substrates for wild-type and mutant glycosidases and other enzymes that catalyze glycosyl transfer. The use of substituted glycosyl fluorides as inhibitors of enzymes that catalyze glycosyl transfer and as tools for investigation of their mechanism is discussed, including the labeling of active site residues. Synthetic applications in which glycosyl fluorides are used as glycosyl donors in enzymatic transglycosylation reactions for the synthesis of oligo- and polysaccharides are then covered, including the use of mutant glycosidases, the so-called glycosynthases, which are able to catalyze the formation of glycosides without competing hydrolysis. Finally, a short overview of the use of glycosyl fluorides as substrates and inhibitors of phosphorylases and phosphoglucomutase is given.     

Synthesis of a glycolipid for studying mechanisms of mitochondrial uncoupling proteins

Glucose-O-omega-palmitic acid is an amphipathic molecule that is useful as a tool for studying the mechanism of mitochondrial uncoupling proteins. The synthesis of this glycolipid is described herein. The study of the reaction of a series of glycosyl donors with appropriate acceptors derived from 16-hydroxyhexadecanoic acid showed that a glycosyl trichloroacetimidate donor was more efficient than thioglycoside, glycosyl halide and glycosyl acetate donors for synthesis of this glycolipid.     

2'-Carboxybenzyl glycosides: glycosyl donors for C-glycosylation and conversion into other glycosyl donors

Glycosylation of various glycosyl acceptors with 2'-carboxybenzyl (CB) 2,3,4,6-tetra-O-benzyl-beta-D-glucopyranoside and CB 2,3,4,6-tetra-O-benzyl-alpha-D-mannopyranoside as glycosyl donors afforded alpha-C-glycosides exclusively or predominantly in good yields. CB glycosides were also converted to other well-known glycosyl donors, the corresponding phenyl thioglycoside and the glycosyl fluoride derivatives.     

Use of ionically tagged glycosyl donors in the synthesis of oligosaccharide libraries

We have developed a new procedure based on the random glycosyl reaction of a partially benzoylated glycosyl acceptor with a glycosyl donor containing a 4,6-O-(4-methoxycarbonylbenzylidene) protecting group as a masked/caged ion-tag. Glycosylated products are ionically tagged by saponification of the methyl ester and the use of this anion-tag greatly simplifies the separation of the desired oligosaccharides from unreacted or excess glycosyl acceptors as well as from over-glycosylated oligosaccharides. In addition, the use of partially benzoylated acceptors greatly improves their solubility in dichloromethane increasing the yield of product formation and, also, of altering the distribution of positional isomers in favor of products derived by reaction of the donors at hydroxyl groups which otherwise would be considerably less reactive. Using this new approach in random glycosyl reactions, several oligosaccharide libraries were readily prepared in overall yields of 60–70% and the individual positional isomers present in the libraries were identified using the ‘reductive-cleavage’ method.     

Insulin Promotes the Hydrolysis of a Glycosyl Phosphatidylinositol in Cultured Rat Astroglial Cells

Abstract: Glycosyl phosphatidylinositols have been implicated in insulin signaling through their action as precursors of second messenger molecules in peripheral tissues. In the present study, cultured rat astrocytes were used to investigate whether glycosyl phosphatidylinositol might be involved in the mechanism of insulin signal transduction in neural cells. A glycosyl phosphatidylinositol sensitive to hydrolysis by both phosphatidylinositol-specific phospholipase C and glycosyl phosphatidylinositol-specific phospholipase D and to nitrous acid deamination was purified. When astrocytes were exposed to 10 n M insulin, a rapid and significant reduction in the content of glycosyl phosphatidylinositol was observed within 1–2 min. In addition, an inverse concentration-dependent relationship between glycosyl phosphatidylinositol and diacylglycerol levels was found, suggesting a phospholipase C-mediated hydrolysis of glycosyl phosphatidylinositol in response to insulin. The effects of insulin were mediated through its own receptors and not through insulin-like growth factor (IGF)-I and/or IGF-II receptors, as demonstrated by affinity cross-linking studies. Also, the effects of 5 n M IGF-I or 5 n M IGF-II on glycosyl phosphatidylinositol and diacylglycerol levels were different from those caused by insulin and were not essentially modified by pretreatment of the cells with either platelet-derived growth factor (PDGF) or epidermal growth factor (EGF). When cells were sequentially incubated with PDGF and EGF, a reduction in both glycosyl phosphatidylinositol and diacylglycerol contents was observed; the diacyl-glycerol but not the glycosyl phosphatidyl content was reversed after incubation with IGF-I, and especially with IGF-II, for 10 min. Despite the remarkable homology among insulin, IGF-I, and IGF-II, our results indicate that in astrocytes these compounds probably use different signal transduction pathways.     

Natural phosphoglycans containing glycosyl phosphate units: structural diversity and chemical synthesis

An anomeric phosphodiester linkage formed by a glycosyl phosphate unit and a hydroxyl group of another monosaccharide is found in many glycopolymers of the outer membrane in bacteria (e.g., capsular polysaccharides and lipopolysaccharides), yeasts and protozoa. The polymers (phosphoglycans) composed of glycosyl phosphate (or oligoglycosyl phosphate) repeating units could be chemically classified as poly(glycosyl phosphates). Their importance as immunologically active components of the cell wall and/or capsule of numerous microorganisms upholds the need to develop routes for the chemical preparation of these biopolymers. In this paper, we (1) present a review of the primary structures (known to date) of natural phosphoglycans from various sources, which contain glycosyl phosphate units, and (2) discuss different approaches and recent achievements in the synthesis of glycosyl phosphosaccharides and poly(glycosyl phosphates).     

氟代糖在糖苷酶研究中的应用

近年来,氟代糖应用于糖苷酶反应研究,显示出越来越重要的作用。氟代糖可以作为糖苷酶及其突变酶的水解底物研究酶学性质;氟代糖抑制剂可以标记糖苷酶催化中心,鉴定亲核体氨基酸。尤为重要的是,氟代糖可作为糖苷酶的糖基供体来合成糖类。糖苷酶突变后,可生成糖苷合成酶和硫代糖苷合成酶,可以用与正常底物构型相反的氟代糖作为糖基供体高效合成糖类,收率一般为60%~90%,有的可达100%。糖苷酶及其突变酶以氟代糖为底物高效合成糖类的研究,必将促进生物学、糖生物学和纳米生物材料的发展。     

On the stereoselectivity of glycosidation of thiocyanates, thioimidates, and thioglycosides

Comparative side-by-side glycosylation studies demonstrated that glycosyl thiocyanates, thioimidates, and thioglycosides provide comparative stereoselectivities in glycosylations. Very high α-stereoselectivity that was previously recorded for glycosyl thiocyanates can be achieved, but only if glycosyl acceptors are equipped with electron-withdrawing acyl substituents. Partially benzylated glycosyl acceptors provided relatively modest stereoselectivity, which was on a par with other common glycosyl donors. Accordingly, thioimidates and thioglycosides showed high stereoselectivity similarly to that of thiocyanates with different classes of acylated primary and secondary glycosyl acceptors.     

A method for the quantitative determination of neutral glycosphingolipids in urine sediment

A method is described for the isolation and quantitation of six neutral glycosyl ceramides from human urinary sediment. Total lipids were extracted from sediments of 24-hr urine collections, and the glycosyl ceramides were isolated by silicic acid column chromatography followed by thin-layer chromatography. Methanolysis of the individual glycosyl ceramides yielded methyl glycosides which were quantitated as the trimethylsilyl ethers by gas-liquid chromatography. By this technique, the submicromolar concentrations of six glycosyl ceramides in normal subjects and in individuals with Fabry's disease, an hereditary glycosphingolipid storage disease, were determined. Trihexosyl ceramide (galactosyl-galactosylglucosyl ceramide) and a digalactosyl ceramide accumulated in the urinary sediment of patients with Fabry's disease.     

Immunochemistry of Ii-active glycosphingolipids of erythrocytes.

Fractions of complex glycosphingolipids were prepared from adult, cord, and i phenotype erythrocytes by the method elaborated for the isolation of poly(glycosyl)ceramides. In contrast to poly(glycosyl)ceramides which comprise on the average 30 glycosyl units and about 5 branching points, i.e. 3,6-di-O-substituted galactopyranosyl residues, per mole of glucose, complex glycosphingolipids from cord and i erythrocytes comprise 6 and 15 glycosyl units respectively and only 0.7 branching points. The latter substances exhibited also a high i activity which was not detected in poly(glycosyl)ceramides. Erythrocyte membranes were labeled with radioactive N-acetylgalactosamine (GalNAc) from UDP-GalNAc using a purified A-blood-group gene-specified transfered of GalNAc. It was found that electrophoretic mobilities in dodecylsulfate-gel electrophoresis of all glycoconjugates which accepted GalNAc were increased in i as compared to I membranes. We conclude that the absence of highly branched glycosphingolipids in cord and i erythrocytes as well as the reduction of apparent molecular weights of the glycoconjugates, which are substrates for A-gene-specified transferase of GalNAc, result from a single cause, that is an inadequacy of the biosynthetic process which is responsible for the formation of GlcNAc1 leads to 6Gal structures.     

Methods of synthesis of glycosyl fluorides

In recent years glycosyl fluorides have been utilized as versatile sugar donors in the synthesis of natural products and carbohydrates. This paper provides an update on the advances made in the preparation of glycosyl fluorides during the last decade (1988-1998).     

New technique for enzymic hydrolysis of glycosphingolipids

A method is described for the study of glycosyl ceramide glycosyl hydrolases. Problems arising from the limited solubility of glycosyl ceramides in aqueous media were overcome by coating the substrate on a filter paper disc that had been treated with phosphatidyl choline. A comparison between the disc method and conventional dispersion of the substrate by detergents was made with two enzymes, galactosylgalactosyl-glucosyl ceramide galactosyl hydrolase (trihexosyl ceramide galactosyl hydrolase) from lysosomes of human and rat small intestine and human spleen, and d-galactose oxidase. In both cases enzymatic activity was greater with the paper disc method than it was with substrates dispersed by detergents. The galactose liberated by the glycosyl hydrolase was determined as the trimethylsilyl derivative of the free sugar by gas-liquid chromatography.     

Synthesis and surface-active properties of glycosyl carbamates and thioureas

Several amphiphilic glycosyl carbamates, glycosyl thiocarbamates and glycosylthioureas were prepared by addition of the anomeric hydroxyl group of acetylated glycosyl derivatives to alkyl isocyanates, or by reaction of glycosyl isothiocyanates with alcohols or amines. The solubility, critical micelle concentrations and detergent efficiency for the extraction of proteins of these compounds were evaluated and compared.     

Screening for hetero-transglycosylating activities in extracts from nasturtium (Tropaeolum majus)

Using combinations of different polysaccharides as glycosyl donors and of oligosaccharides fluorescently labeled by sulforhodamine (SR) as glycosyl acceptors, we screened for the presence of transglycosylating activities in extracts from nasturtium (Tropaeolum majus). Besides xyloglucan endotransglycosylase/hydrolase (XTH/XET, EC 2.4.1.207) activity, which transfers xyloglucanosyl residues from xyloglucan (XG) to XG-derived oligosaccharides (XGOs), a glycosyl transfer from XG to SR-labeled cellooligosaccharides and laminarioligosaccharides has been detected. The XGOs also served as acceptors for the glycosyl transfer from soluble cellulose derivatives carboxymethyl cellulose and hydroxyethylcellulose. The effectivity of these polysaccharides as glycosyl donors for transfer to XG-derived octasaccharide [1-3H]XXLGol decreased in the order XG > HEC > CMC. Isoelectric focusing in polyacrylamide gels showed that bands corresponding to hetero-transglycosylase activities coincided with zones corresponding to XTH/XET. These results can be explained as due either to substrate non-specificity of certain isoenzymes of XTH/XET or to existence of enzymes catalyzing a hetero-transfer, that is the formation of covalent linkages between different types of carbohydrate polymers.     

Synthesis of ceramidated GLA-60 derivatives

Ceramidated GLA-60 derivatives 11 and 11' were synthesized from 1 via glycosidation of ceramide derivative 12 as a glycosyl acceptor with GLA-60 derivative 5 as a glycosyl donor, and successive conversion. Compound 11' showed only weak LPS-antagonistic activity without showing any LPS-agonistic activity.     

基于右旋糖酐蔗糖酶转糖基作用的槲皮素葡萄糖苷的合成研究

右旋糖酐蔗糖酶是一种以蔗糖为唯一底物,将蔗糖分子中D-葡萄糖基催化转移到受体分子上的葡萄糖基转移酶。利用右旋糖酐蔗糖酶的转糖基作用,以蔗糖为葡萄糖糖基供体,槲皮素为糖基受体,对槲皮素糖苷的酶法合成进行了探索。通过对该酶催化反应体系、催化反应条件及产物分析的研究,结果表明：在25℃下,右旋糖酐蔗糖酶能够在30％DMSO-70％乙酸-乙酸钙（0.02 mol/L,pH值5.4）的反应体系中催化合成一种槲皮素葡萄糖苷,在这个反应体系下,以10％的蔗糖作为糖基供体,槲皮素为糖基受体,右旋糖酐蔗糖酶活力为40 U/mL,转速为150 r/min,槲皮素糖苷的转化率最高,可达39.5％。通过质谱分析确定是一种槲皮素单糖苷,分子量为464。该研究结果为黄酮类物质的糖基化修饰奠定了基础。     

The synthesis of cyclic imidates from amides of glucuronic acid and investigation of glycosidation reactions

The synthesis of novel cyclic glycosyl imidates and an investigation of their potential as donors in glycosidation reactions is described. The results show that 1,2-cis glycosides obtained from the reactions of glycosyl acetates or cyclic imidates, each derived from amides of glucuronic acid, result from the anomerisation of initially formed 1,2-trans glycosides.     

New Approaches to Enzymatic Oligosaccharide Synthesis: Glycosynthases and Thioglycoligases

Abstract

An overview of the applications of engineered glycosynthases and thioglycoligases for the enzymatic synthesis of O- and S-glycosidic linkages in oligosaccharides is presented. Glycosynthases lack the catalytic nucleophile of retaining glycosidases and use glycosyl fluorides with inverted anomeric stereochemistry as glycosyl donors. To date, nine enzymes from seven different glycosyl hydrolase families have been engineered to perform the glycosynthase reaction. Thioglycoligases lack the catalytic acid/base residue of retaining glycosidases and use dinitrophenyl glycosides as donors and deoxy-thiosugars as acceptors. The regioselectivity of the transglycosylation reaction is entirely controlled by the position of the thiol in the acceptor. To date, two retaining exo glycosidases and one endo glycanase, all from different glycosyl hydrolase families, have been engineered in this fashion.     

Regulation of acetyl-CoA carboxylase in rat mammary gland. Effects of incubation with Ca2+, Mg2+ and ATP on enzyme activity in tissue extracts.

The catalytical role of the hydroxy amino acid in the "marker sequence" Asn-Xaa-Thr(Ser) for the N-glycosylation step of glycoprotein formation was investigated by using a series of hexapeptides derived from Tyr-Asn-Gly-Xaa-Ser-Val by substituting threonine, serine, cysteine, valine and O-methylthreonine respectively for Xaa. The results, which were obtained with calf liver microsomal fractions as enzyme source and dolichyl diphosphate di-N-acetyl [14C] chitobiose as glycosyl donor showed that the threonine-, serine- and cysteine-containing derivatives could be glycosylated, although at very different rates, whereas the valine and O-methylthreonine analogues did not work as glycosyl acceptors. Replacement of threonine by serine resulted in a 4-fold decrease in Vmax, and about a 10-fold increase in Km for glycosyl transfer. Replacement of serine by cysteine again decreased acceptor activity 2-3-fold. The various results, taken together, indicate an absolute requirement for a hydrogen-bond-donor function in the side chain of the hydroxy amino acid of the "marker sequence" and furthermore, point to a considerable influence of the structure of this amino acid on binding as well as on the glycosyl transfer itself. In order to explain the observed differences in the glycosyl-transfer rates, a model is proposed with a hydrogen-bond interaction between the amide of asparagine as the hydrogen-bond donor and the oxygen of the hydroxy group of the hydroxy amino acid as the hydrogen-bond acceptor. The participation of the hydroxy group in the catalytic mechanism of glycosyl transfer in the kind of proton-relay system is discussed.     

Glycosyl phosphatidylinositol in thyroid: cell signalling or protein anchor?

During the last 10 years, attention has been focused on the stimulation by various agonists of the hydrolysis of phosphatidylinositol bis-phosphate into the second messengers inositol tris-phosphate and diacylglycerol. Two other aspects of the metabolism of phosphoinositides were therefore not paid sufficient attention. The first one was the release by insulin of a glycosyl inositol-phosphate from a glycosyl phosphatidylinositol, the hydrosoluble product being able to reproduce some of the hormone effects; the second was the discovery that several membrane proteins were anchored via a glycosyl phosphatidylinositol. For over 20 years, we have been interested in the effect of thyreostimulin (TSH) on the turnover of phosphatidylinositol in pig thyrocyte. As this effect did not seem to result from the hydrolysis of phosphatidylinositol bis-phosphate we explored another possibility, the synthesis of glycosyl inositol-phosphate. We have shown that, in cultured pig thyrocytes, TSH stimulates the release of the polar head of a glycosyl phosphatidylinositol. This soluble glycosyl inositol-phosphate which acts as insulin on adipocyte, modulates the cAMP accumulation and iodine metabolism in thyrocytes and could be held responsible for the cAMP independent effects of TSH. However, we do not yet know if there is a link between the glycosyl phosphatidylinositol sensitive to TSH and the anchor membrane protein. To date, the amount of 2 of these proteins: NAD glyco-hydrolase in thyroid cell membranes and heparan sulfate proteoglycan have been shown to be increased by TSH treatment of thyroid cells.