The primary acid product of DPNH

Analysis of the proton magnetic resonance spectra obtained at 220 MHz confirms the axial conformation of the C-6 hydroxyl in the model primary acid product 1-n-(2,6-dichlorobenzyl)-6-hydroxy-1,4,5,6-tetrahydronicotinamide. In the primary acid product of DPNH however the reaction occurs stereospecifically with the substitution at the C-6 position equatorial and on the B-side of the pyridine ring and the C-4A proton axial. A cyclic structure α,O^2′-6B cyclotetrahydronicotinamide is proposed for the primary acid product of DPNH, formed by epimerization of βDPNH to the α configuration followed by protonation at C-5 and subsequent attack of the ribose C-2′-OH on the C-6 position forming a new five membered ring.     

Stereochemistry of the hydrolysis of α,α-trehalose by trehalase,determined by using a labelled substrate

(1,1′-¹³C)α,α-Trehalose was obtained in 37% yield from the Pavia condensation of 2,3,4,6-tetra-O-benzyl-d-(1-¹³C)glucopyranose, in dichloromethane in the presence of trifluoromethanesulfonic anhydride, followed by the usual deprotection techniques. The hydrolysis of this substrate by cockchafer trehalase was monitored at 37° by using ¹³C-n.m.r. spectroscopy with short recording times. Equimolecular amounts of α- and β-d-glucopyranose are released simultaneously by the action of the enzyme. This result is consistent with a bimolecular substitution mechanism, taking into account previous results involving C-2 asymmetric participation in the catalytic step of hydrolysis of α,α-trehalose. For comparative evaluation of its accuracy, the usual polarimetric technique was also used for the determination of the anomeric configuration of the d-glucose released by the action of the enzyme on α,α-trehalose.     

The Modes of Binding Methyl—α (and β)-D-glucopyranosides and Some of their Derivatives to Concanavalin A—A Theoretical Approach

Abstract

The probable modes of binding of Methyl—α (and β)-D-glucopyranosides and some of their derivatives to concanavalin A have been proposed from theoretical studies. Theory predicts that βMeGlcP can bind to ConA in three different modes whereas α-MeGlcP can bind only in one mode. βMeGlcP in its most favourable mode of binding differs from α-MeGlcP in its alignment in the active-site of the lectin where it binds in a flipped or inverted orientation. Methyl substitution at the C-2 atom of the α-MeGlcP does not significantly affect the possible orientations of the sugar in the active-site of the lectin. Methyl substitution at C-3 or C-4, however, affects the allowed orientations drastically leading to the poor inhibiting power of Methyl-3-O-methyl-α-D-glucopyranoside and the inactivity of Methyl-4-O-methyl-α-D-glucopyranoside. These studies suggest that the increased activity of the α-MeGlcP over β-MeGlcP may be due to the possibility of formation of better hydrogen bonds and to hydrophobic interactions rather than to steric factors as suggested by earlier workers. These models explain the available NMR and other binding studies.     

Stereoselective synthesis of some methyl-substituted steroid hormones and their in vitro cytotoxic activity against human gastric cancer cell line MGC-803

A series of 3-, 7-, 15-, and 16-methyl-substituted steroid analogs were synthesized via a highly stereoselective 1,6-conjugate addition. Under the catalysis of CuBr, AlMe₃ reacted with four steroid dienone precursors to afford either the corresponding α-epimer of C-3 and C-7 methyl-substituted steroids as the major products, and the ratio of α/β was up to 10/1. No β-epimer has been detected for methyl addition at C-16. However, under the same reaction conditions, enantioselective methyl addition at C-15 afforded the 15β-epimer as the major product. The preliminary SAR analysis showed that the methyl substituents at C-7α and C-15β positions lead to a dramatical increase in potency against human gastric cancer cell line MGC-803.     

Acetolysis of disaccharides: Comparative kinetics and mechanism

The initial acetolysis rates of several disaccharides were compared using an assay procedure which involves adding portions of the reaction mixture to an alkaline sodium borohydride solution. After reduction, glycosidically-linked hexose was determined by the phenol-sulfuric acid method. For D-glucose disaccharides, β linkages were cleaved faster than α linkages, suggesting anchimeric assistance from the trans C-2 acetoxyl group. The acetolysis reaction rates for the various β-linked D-glucose disaccharides decreased in the order (1→6) ? (1→3) > (1→2) > (1»4). For the various α-linked disaccharides the order was (1→6) ? (1→4) > (1»3)> (1→2). The acetolysis rates for D-mannose disaccharides were in the order α-(1»6) ? α-(1→3) > β-(1»4) > α-(1»2). Turanose (3-O-α-D-glucopyranosyl-D-fructose) was cleaved at a much faster rate than either D-mannobiose or D-glucobiose with α-(1»2) or α-(1»3) linkages. A reaction mechanism is supported which features an acyclic intermediate, and, for certain -disaccharides, C-2 acetoxyl anchimeric assistance.     

Enzymatic regioselective deprotection of peracetylated mono- and disaccharides

Selective enzymatic hydrolysis of the peracetylated disaccharides, namely cellobiose, lactose, maltose and melibiose, with lipase from Asperilligus niger in aqueous buffer and organic solvent for 30 min afforded exclusively the corresponding heptaacetates with a free hydroxyl group at C-1 in high yield. Prolonged reaction of the β-1,4 linked cellobiose and lactose peracetates afforded selectively their hexaacetates with free hydroxyl groups at C-1,2, whereas the α-1,4 linked disaccharides maltose and melibiose peracetate gave a complex mixture of products. The reaction of 2-acetamido-2-deoxy-1,3,4,6-tetra-O-acetylglucopyranose (11) for 22 h afforded as the major product the diacetate 12 with free hydroxyl groups at C-1,4.     

The mechanism of,and the solvent effects in,the glycosidation of D-glucosyl chlorides having a non-participating group at C-2, using silver perchlorate as catalyst

The mechanism of, and the solvent effects in, the Koenigs—Knorr reaction of D-glucosyl chlorides having a non-participating group at C-2, using silver perchlorate as principal catalyst, were investigated. When a large excess of methanol was used, methyl D-glucopyranosides with inversion of the configuration at C-1 were predominantly obtained, except in one case. When 1 molar equivalent of nucleophile, such as methanol, methyl trityl ether, or 2-propanol, was used, the ratio of α- and β-D-glucopyranosides obtained varied with the solvent used. It is proposed that the reactions proceed via a common intermediate such as a D-glucosyl-perchlorate. The following conclusions are made for the preparation of α-D-glucopyranosides: anhydrous ether is a preferable solvent, silver perchlorate and sym-collidine are superior to a mixture of silver perchlorate and silver carbonate in the presence of Drierite, β-D-glucosyl chloride is preferred to the α-D anomer, and the solvent and reagents should be as dry as possible.     

Carboxyalkylation of chitosan in the gel state

This study presents a new approach for direct carboxyalkylation of chitosan in the gel state by using aza-Michael addition and substitution reactions. Various reagents were applied including acrylic and crotonic acids, and α-, β-, γ-, δ-, and ?-halocarboxylic acids. The reaction of chitosan with γ- and δ-halocarboxylic acids showed no target product formation either in solution or in the gel state. In the case of acrylic, crotonic, α- and β-halocarboxylic acids, the reaction performed in the gel state (concentration of chitosan 20-40%) shows higher degree of substitution at lower reaction time and temperature than in diluted solutions (concentration of chitosan 0.5-2%). The results were discussed in terms of kinetics of the target and side reactions. (1)H and (13)C NMR confirmed that in all cases the carboxyalkylation of chitosan proceeds exclusively at the amino groups.     

Stereochemistry of the β-cyanoalanine synthetase and S-alkylcysteine lyase reactions

The stereochemistry of the replacement of the SH-group of cysteine by CN catalyzed by β-cyanoalanine synthetase was studied using cysteine stereospecifically tritiated at C-3. Analysis of the resulting β-cyanoalanine by conversion into fumarate via aspartate and malate showed that the reaction had occurred with retention of configuration at C-3. Using cystine stereospecifically labeled at C-3 with tritium or with tritium and deuterium, it was found that the α,β-elimination reaction catalyzed by S-alkylcysteine lyase involves stereo-specific replacement of the β-substituent of the substrate by a hydrogen derived from the solvent, D₂O or H₂O, with retention of configuration to give pyruvate containing a chiral methyl group. The results are discussed, particularly in the light of mechanistic proposals by Braunstem and co-workers.     

Synthesis of α- and β-glycosides containing spin labels,as probes for studies of carbohydrate-protein interaction

Nitroxide spin-labeled α-d-glycopyranosides were synthesized in good yield and in a highly stereoselective manner by reaction of per-O-benzyl-α-d-glycopyranosyl bromides with 2,2,6,6-tetramethyl-4-piperidinol under the bromide ion-catalyzed conditions devised by Lemieux etal. After hydrogenolysis, the deblocked intermidiates were oxidized to give the desired, spin-labeled α-d-glycopyranosides. Nitroxide spin-labeled α-d-glycopyranosides, as well as a β-maltoside, were synthesized by standard methods. The synthesis is also described of 2-amino-2-deoxy-d-glucose and -d-galactose derivatives having a spin label at C-2, and of the spin-labeled compound 1-[4-(β-d-galactopyranosyloxy)phenyl]-3-(2,2,6,6-tetramethylpiperidin-1-oxyl-4-yl)-2-thiourea.     

Selective deuterium labeling of the sphingoid backbone: facile syntheses of 3,4,5-trideuterio-d-erythro-sphingosine and 3-deuterio-d-erythro-sphingomyelin

Deuteration at C-4 and C-5 of sphingosine was achieved via a hydrogen–deuterium exchange reaction of a β-ketophosphonate intermediate catalyzed by ND₄Cl in D₂O/tetrahydrofuran. To install deuterium at C-3 of sphingosine and sphingomyelin, sodium borodeuteride reduction/cerium(III) chloride reduction of an α,β-enone in perdeuteromethanol was used.     

Chemical modification of alginates in organic solvent systems

Alginates are (1→4)-linked linear copolysaccharides composed of β-D-mannuronic acid (M) and its C-5 epimer, α-l-guluronic acid (G). Several strategies to synthesize organically modified alginate derivatives have been reported, but almost all chemistries are performed in either aqueous or aqueous-organic media. The ability to react alginates homogeneously in organic solvents would open up access to a wide range of new chemistries and derivatives. However, past attempts have been restricted by the absence of methods for alginate dissolution in organic media. We therefore report a strategy to dissolve tetrabutylammonium (TBA) salts of alginic acid in polar aprotic solvents containing tetrabutylammonium fluoride (TBAF). Acylation of TBA-alginate was performed under homogeneous conditions, such that both M and G residues were acetylated up to a total degree of substitution (DS) ≈1.0. Performing the same reaction under heterogeneous conditions resulted in selective acylation of M residues. Regioselectivity in the acylated alginate products was studied, and degradation under basic reaction conditions was probed.     

Macoma birmanica agglutinin recognizes glycoside clusters of β-GlcNAc/Glc and α-Man

Macoma birmanica agglutinin (MBA) that seems to play crucial roles in the innate immunity of marine bivalve, M. birmanica has been earlier defined as GlcNAc/Man specific. However, most complementary carbohydrate structures to its binding domain and ligand clustering in its recognition profile have not been established. In this study, the complete recognition profile of MBA was examined by enzyme-linked lectin-sorbent assay and inhibition assay. Among the monosaccharides tested, GlcNAc was more reactive followed by Man and Glc, others were non-reactive; revealing the importance of equatorial -NAc group at C-2, -OH group at C-4 and C-6, and pyranose conformation of hexose. Moreover, β-glycosides of GlcNAc and Glc were more potent whereas for Man it was α-glycoside. MBA recognized both exposed and internal α-Man and β-GlcNAc/Glc residues well with most linkages except (β1-4). This binding pattern was further extended and confirmed by polyvalent glycoside clusters of GlcNAc(β1-2)Man(α1-, which was a better inhibitor than Man(α1-2/3/6)Man(α1- or Man(α1-3/6)Man(β1- present in well-defined naturally occurring glycoproteins. This broad range specificity explains the importance of MBA as an important pattern recognition molecule that provides more realistic picture of carbohydrate-based immune response triggering.     

Trypsin cleavage of the α-subunit of beef heart F1-ATPase abolishes ATP synthesis and ATP-driven energy-transduction capabilities

Previous work has shown that mild trypsin treatment eliminates energy-transduction capability and tight (non-exchangeable) nucleotide binding in beef heart mitochondrial F₁-ATPase (Leimgruber, R.M. and Senior, A.E. (1976) J. Biol. Chem. 251, 7103–7109). The structural change brought about by trypsin was, however, too subtle to be identified by one-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis, and was not defined. In this work we have applied two-dimensional electrophoresis (isoelectric focussing then sodium dodecyl sulfate polyacrylamide gradient electrophoresis) to the problem, and have determined that the α-subunit of F₁ is altered by the mild trypsin treatment, whereas no change was detected in β-, γ-, δ- or ?-subunits. Binding of ADP to the trypsin-treated F₁ was compared to binding to control enzyme over a range of 0–40 μM ADP in a 30 min incubation period. There was no difference between the two enzymes, K^ADP_d in Mg²⁺-containing buffer was about 2 μM in each. Since the tight (nonexchangeable) sites are abolished in trypsin-treated F₁, this shows that tight exchangeable ADP-binding sites are different from the tight nonexchangeable ADP-binding sites. There was no effect of trypsin cleavage of the α-subunit on β-subunit conformation as judged by aurovertin fluorescence studies. The cleavage of the α-subunit which occurred was judged to occur very close to the C- or N-terminus of the subunit and constitutes therefore a small and specific chemical modification which abolishes overall function in F₁ but leaves partial functions intact.     

Isolation and identification of products in the reaction of 2-acetamido-3,4,6-tri-O-acetyl-1,5-anhydro-2-deoxy-d-arabino-hex-1-enitol with theophylline

Fusion of 2-acetamido-3,4,6-tri-O-acetyl-1,5-anhydro-2-deoxy-d-arabino-hex-1-enitol with theophylline, in the presence of boron trifluoride etherate as the catalyst, caused condensation to occur. This reaction afforded a variety of products of nucleosidic character, which were successively separated by repeated chromatography on silica gel. The structures of the products were determined, on the basis of X-ray crystallographic analysis (for three compounds) and by means of n.m.r.-spectral data and mass spectrometry, as the following: 7-(2-acetamido-4,6-di-O-acetyl-2,3-dideoxy-β-d-erythro-hex-2-enopyranosyl)theophylline, the corresponding α- and β-d-threo derivatives, and 7-(2-acetamido-6-O-acetyl-2,3-dideoxy-α-d-threo-hex-2-enopyranosyl)theophylline and its β anomer.In addition to these 2′,3′-unsaturated nucleosides having the base linked at C-1′, three products of a new type, having the base attached at C-4′, were also isolated: 7-(methyl 2-acetamido-6-O-acetyl-2,3,4-trideoxy-β-d-erythro-hex-2-enopyranosid-4-yl)theophylline, and the corresponding α-d-threo and α-d-erythro isomers.The correlation of the data obtained by X-ray structure analysis and proton nuclear magnetic spectroscopy, together with their application for the determination of configuration and conformation of these compounds, are discussed. It appears that the ¹H-n.m.r. data alone do not suffice for unambiguous and correct structure determination for these classes of compounds.     

Methanolysis of sphingomyelin. Toward an epimerization-free methodology for the preparation of D-erythro-sphingosylphosphocholine

It is well known that acid hydrolysis of natural sphingomyelin in aqueous methanol or 1-butanol at refluxing temperature is accompanied by epimerization at the C-3 position of the long-chain base. An improved procedure for the hydrolysis of commercially available, naturally occurring sphingomyelin is described. Prolonged exposure (3;-4 days) of sphingomyelin to freshly prepared 0.5 M anhydrous methanolic hydrogen chloride (generated by trapping the gas evolved from the reaction of concentrated sulfuric acid with solid sodium chloride in anhydrous methanol) at 50 degrees C resulted in cleavage of the amide side chain. The extent of epimerization of the allylic alcohol stereocenter was quantified by integration of the C-5 signal of the (13)C nuclear magnetic resonance spectrum of lysosphingomyelin.The method described here is superior to the traditional acid hydrolysis methods because it provides the product as a approximately 10:1 ratio of d-erythro/l-threo epimers; in contrast, a ratio of approximately 1. 3:1 was obtained by the previous methods. We also report that use of dichloromethane as a cosolvent with N,N-dimethylformamide in the reaction of lysosphingomyelin with an activated fatty acid reduced the time required for completion of the N-acylation reaction.     

Differential mutagenicity of streptozotocin analogs of the carbohydrate moiety

The mutagenicity of streptozotocin (SZN), 8 of its analogs and N-msthyl-N-nitrosourea (MNU) were compared in Salmonella typhimurium. SZN and its analogs carry MNU attached to the carbohydrate moiety at the C-2 position. The C-1 analogs tested were α- and β-methyl-SZN, α-ethyl-SZN, β-propyl-SZN, α- and β-butyl-SZN; in 2 analogs glucose was replaced by α- or β-inositol. When the ability of these compounds to revert the hisG46 auxotroph was compared, they fell into 4 groups which differed by about 10-fold in mutagenicity from one another. The most mutagenic was (i) SZN, followed by (ii) β-methyl-SZN; (iii) α-methyl-SZN, α-ethyl-SZN, β-propyl-SZN, α- and β-butyl-SZN; (iv) α and β-inositol-MNU. These results suggest that the presence of the glucose moiety is conducive to a high level of mutagenicity of SZN. Alterations of the glucose moiety by addition of larger alkyl groups, especially in the α position lead to decreased mutagenicity. The least mutagenic analogs are those in which the glucose moiety is replaced by inositols.The mutagenicity of SZN, β-methyl-SZN and of β-butyl-SZN was also compared in a mouse tissue-mediated assay. SZN was about 500-fold more mutagenic than its β-methyl analog, while the β-butyl analog was not mutagenic.Depletion of SZN and 4 of its analogs from the medium in presence of bacteria was determined spectrophotometrically. The more mutagenic compounds were depleted more rapidly but the quantitative differences in mutagenicity between these compounds could not be accounted for by depletion alone.     

Further studies on the composition and structure of a fucoidan preparation from the brown alga Saccharina latissima

The polysaccharide composition of a fucoidan preparation isolated from the brown alga Saccharina latissima (formerly Laminaria saccharina) was reinvestigated. The preparation was fractionated by anion-exchange chromatography, and the fractions obtained were analyzed by chemical methods combined with NMR spectroscopy. Several 2D procedures, including HSQC, HMQC-TOCSY, and HMQC-NOESY, were used to obtain reliable structural information from the complex spectra, and the signal assignments were additionally confirmed by comparison with the literature spectra of the related polysaccharides and synthetic oligosaccharides. In accordance with the previous data, the main polysaccharide component was shown to be a fucan sulfate containing a backbone of 3-linked α-l-fucopyranose residues sulfated at C-4 and/or at C-2 and branched at C-2 by single sulfated α-l-fucopyranose residues. In addition, three other types of sulfated polysaccharide molecules were detected in the total fucoidan preparation: (i) a fucogalactan having a backbone of 6-linked β-d-galactopyranose residues branched mainly at C-4 and containing both terminal galactose and fucose residues; (ii) a fucoglucuronomannan having a backbone of alternating 4-linked β-d-glucopyranosyluronic acid and 2-linked α-d-mannopyranose residues with α-l-fucopyranose residues as single branches at C-3 of α-d-Manp; and (iii) a fucoglucuronan having a backbone of 3-linked β-d-glucopyranosyluronic acid residues with α-l-fucopyranose residues as single branches at C-4. Hence, even a single algal species may contain, at least in minor amounts, several sulfated polysaccharides differing in molecular structure. Partial resolution of these polysaccharides has been accomplished, but unambiguous evidence on their presence as separate entities was not obtained.     

Carbasugar-thioether pseudodisaccharides related to N-glycan biosynthesis

Analogues of the α-Glcp-(1→3)-α-Glcp and α-Glcp-(1→3)-α-Manp disaccharides (representing the two α-gluco linkages cleaved by α-Glucosidase II in N-glycan biosynthesis) in which the non-reducing-end sugar is replaced by a carbasugar and the inter-glycosidic oxygen by a sulfur were synthesised. The key coupling step was an S_N2 displacement of an equatorial triflate at C-1 of the carbasugar by C-3 gluco or manno thiolates with inversion of configuration to give thioether pseudodisaccharides with axial substitution at C-1 of the carbasugar. The deprotected pseudodisaccharides failed to inhibit the action of α-Glucosidase II as measured both by an in vitro assay and by free oligosaccharide (FOS) analysis from cell studies.