β-elimination in aldonolactones. Synthesis of 2-deoxy-D-lyxo-hexose and 2-deoxy-D-arabino-hexose

Benzoylation of D-glycero-L-manno-heptono-1,4-lactone (1) with benzoyl chloride and pyridine for 2 h afforded crystalline penta-O-benzoyl-D-glycero-L-manno-heptono-1,4-lactone (2), but a large excess of reagent during 8 h also led to 2,5,6,7-tetra-O- benzoyl-3-deoxy-D-lyxo-hept-2-enono-1,4-lactone (3). Catalytic hydrogenation of 3 was stereoselective and gave 2,5,6,7-tetra-O-benzoyl-3-deoxy-D-galacto-heptono-1,4-lactone (4). Debenzoylation of 4 followed by oxidative decarboxylation with ceric sulfate in aqueous sulfuric acid gave 2-deoxy-D-lyxo-hexose (5). Application of the same reaction to 3-deoxy-D-gluco-heptono-1,4-lactone afforded 2-deoxy-D-arabino-hexose (6).     

Degradation of 2-deoxyaldoses by alkaline hydrogen peroxide

Reaction of 2-deoxy-D-arabino-hexose, 2-deoxy-D-lyxo-hexose, and 2-deoxy-D-erythro-pentose with alkaline hydrogen peroxide in the presence of magnesium hydroxide afforded the corresponding 2-deoxyaldonic acid, the 1,4-lactone, and the 1-O-formyl derivative of the next lower alditol. The 2-deoxyaldonic acids were separated in 60–80% yields, as new, crystalline lithium salts. The 1,4-lactones were obtained under conditions that precluded intermidiate formation of the free acids: presumably, the reaction proceeded by way of an intermediate, furanosyl hydroperoxide, which was converted into the lactone by elimination of water. With an excess of alkaline hydrogen peroxide, in the absence of magnesium hydroxide, the substrates were degraded to formic acid, with concurrent decomposition of hydrogen peroxide. It is shown that decomposition of hydrogen peroxide is catalyzed by hydroperoxide anion, and that it takes place by both a chain, and a non-chain, process. The decomposition reactions afford an abundant source of hydroxyl radical capable of oxidizing a wide variety of compounds.     

Synthesis of 5-deoxy-d-xylo-hexose and 5-deoxy-l-arabino-hexose,and their conversion into adenine nucleosides

Anti-Markovnikov hydration of the olefinic bond of 5,6-dideoxy-1,2-O-isopropylidene-3-O-p-tolylsulfonyl-α- d-xylo-hex-5-enofuranose (4) and methyl 5,6-dideoxy-2,3-di-O-p-tolylsulfonyl-α-l-arabino-hex-5-enofuranoside (11) by the addition of iodine trifluoroacetate, followed by hydrogenation in the presence of a Raney nickel catalyst in ethanol containing triethylamine, afforded 5-deoxy-1,2-O-ísopropylidene-3-O-p-tolylsulfonyl-α-d-xylo-hexofuranose (6) and methyl 5-deoxy-2,3-di-O-p-tolylsulfonyl-α-d-arabino-hexofuranoside (14), respectively. 5-deoxy-d-xylo-hexose and 5-deoxy-l-arabino-hexose were prepared from 6 and 14, respectively, by photolytic O-detosylation and acid hydrolysis. Syntheses of 9-(5-deoxy-β-d-xylo-hexofuranosyl)-adenine and 9-(5-deoxy-α-l-arabino-hexofuranosyl)adenine are also described. Application of the sodium naphthalene procedure, for O-detosylation, to 11 is reported in connection with an alternative synthetic route to methyl 5-deoxy-α-l-arabino- hexofuranoside.     

Synthesis of derivatives of 3-amino-2,3-dideoxy-l-hexoses related to daunosamine (3-amino-2,3,6-trideoxy-l-lyxo-hexose)

The synthesis is described of 3-amino-2,3-dideoxy-l-arabino-hexose (10), methyl 2,3-dideoxy-3-trifluoroacetamido-α-l-lyxo-hexopyranoside (17), methyl 3-amino-2,3-dideoxy-α-l-ribo-hexopyranoside (21), methyl 2,3-dideoxy-3-trifluoroacetamido-α-l-xylo-hexopyranoside (26), and certain derivatives from methyl 4,6-O-benzylidene-2-deoxy-α-l-arabino-hexopyranoside (3). Conversion of 2-deoxy-l-arabino-hexose into 3 by modified, standard procedures, and on a large scale, gave a 75% yield.     

Studies on Epimeric D-xylo-and D-lyxo-Tetritol-yl-2-phenyl-2H-1,2,3-triazoles. Synthesis and Anomeric Configuration of 4-(α- and β-D-Threofuranosyl)-2-phenyl-2H-1,2,3-triazole C-Nucleoside Analogs

Abstract

Treatment of 4-(D-xylo-tetritol-1-y1)-2-phenyl-2H-1,2,3-triazole (1) with one mole equivalent of tosyl chloride in pyridine solution, afforded the C-nucleoside analog; 4-(β-D-threofuranosyl)-2-phenyl-2H-1,2,3-triazole (2) in 55% yield, as well as the byproduct 4-(4-chloro-4-deoxy-D-xylo-tetritol-1-y1)-2-pheny1-2 H-1,2,3-triazole (4). Treatment of the epimeric 4-(D-lyxo-tetritol-1-y1)-2-pheny1-2H-1,2,3-triazole (6) with tosyl chloride in pyridine solution afforded the anomeric C-nucleoside analog; 4-(δ-D-threofuranosy1)-2-pheny1-2H-1,2,3-triazole (7) in 29% yield, as well as the byproduct 4-(4-chloro-4-deoxy-D-lyxo-tetritol-1-y1)-2-pheny1-2 H-1,2,3-triazole (9). Similar treatment of 1 and 6 with trifluoromethanesulfonyl chloride in pyridine solution afforded 2 and 7, respectively. The structure and anomeric configuration of these compounds were determined by acetylation, NMR, NOE, and circular dichroism spectroscopy, as well as mass spectrometry.     

Synthesis of 4-deoxy-d-xylo-hexose and 4-azido-4-deoxy-d-glucose and their effects on lactose synthase

Syntheses are reported of 4-deoxy-d-xylo-hexose and 4-azido-4-deoxy-d-glucose as potential inhibitors for lactose synthase [uridine 5′-(α-d-galactopyranosyl pyrophosphate):d-glucose 4-β-d-galactopyranosyltransferase, EC 2.4.1.22]. These syntheses involved SN2 displacement of the 4-methylsulfonyloxy group of methyl 2,3,6-tri-O-benzoyl-4-O-methylsulfonyl-α-d-galactopyranoside by iodide and azide ions. In both cases, inversion in configuration was observed. The resulting intermediates, methyl 2,3,6-tri-O-benzoyl-deoxy-4-iodo-α-d-glucopyranoside and methyl 4-azido-2,3,6-tri-O-benzoyl-deoxy-α-d-glucopyranoside, were obtained in crystalline form. Both 4-deoxy-d-xylo-hexose and 4-azido-4-deoxy-d-glucose were found to be inhibitors for lactose synthase in the presence of α-lactalbumin, but had no effect in the absence of α-lactalbumin. Both d-glucose analogues bind to the enzyme system far more weakly than d-glucose, suggesting that the recognition of the 4-OH group of the acceptor substrate is an important factor in binding.     

The synthesis of 3-deoxy-4-O-methyl-D-arabino-2-heptulosonic acid and its behaviour in the Warren reaction

3-Deoxy-4-O-methyl-D-arabino-2-heptulosonic acid was synthesized in six steps starting from 2-deoxy-D-arabino-hexose. Treatment with periodate-thiobarbiturate (Warren reaction) gave a positive reaction with a molar absorption coefficient of 3700 to 5000 depending on the conditions of the periodate oxidation. It is suggested that the Warren reaction, which is eminently suitable for the detection of 3-deoxy-aldulosonic acids, should not be used for the quantitative estimation of 3-deoxy-2-aldulosonic acids of undetermined substitution pattern.     

Two enzymes in Streptomyces griseus forb the synthesis of dTDP-L-dihydrostreptose from dTDP-6-deoxy-D-xylo-4-hexosulose.

The biosynthesis of dTDP-L-dihydrostreptose from dTDP-6-deoxy-D-$\text{xylo}$-4-hexosulose requires two enzymes: dTDP-4-keto-L-rhamnose-3,5-epimerase and a NADPH-dependent dTDP-“dihydrostreptose synthase”. These enzymes could be separated on a Sephadex G-100 column.     

Structural studies of the O-specific side-chain of the lipopolysaccharide from Escherichia coli O 55

The structure of the O-specific side-chains of the lipopolysaccharide from Escherichia coli O 55 has been investigated, methylation analysis, specific degradations, and n.m.r. spectroscopy being the principal methods used. It is concluded that the O-specific side-chains are composed of pentasaccharide repeating-units having the following structure [where Col stands for colitose (3,6-dideoxy-l-xylo-hexose)].

     

γ-Irradiation-induced ring-opening of polycrystalline cycloamylose hydrates

The chemical modifications induced in polycrystalline cycloamylose hydrates during γ-irradiation have been investigated by using g.l.c-m.s. to analyse the monosaccharide mixtures formed on hydrolysis. Unchanged substrate and material retaining the original cyclic structure were removed by precipitation prior to hydrolysis, and the products therefore reflect the effect of the radical-induced opening of the cycloamylose ring structure. The following products were identified: glucose and glucono-1, 5-lactone (1), 4-deoxy-xylo-hexose (2), arabinose (3), ribose (4), 2-deoxy-erythro-pentose (5), 3-deoxy-erythro-hexos-4-ulose (6), xylo-hexos-5-ulose (7), 6-deoxy-xylo-hexos-5-ulose (8), 5-deoxy-xylo-hexodialdose (9), 2,6-dideoxyhexos-5-ulose (10), xylose (11), 5-deoxypentose (12), 3-deoxypentulose (13), erythrose (14), and threose (15). Products 1-9 appear to be terminals of the “anhydroglucose” chain. Established free-radical reactions, typical for carbohydrates. are invoked to account for these products.     

Reactions of enol sugar derivatives. 8. Action of -D-glucosidase and -D-galactosidase on D-glucal and D-galactal

D-Glucal and D-galactal were converted into the corresponding 2-deoxy-D-hexoses by β-D-glucosidase and β-D-galactosidase, respectively. The enzymic hydration of D-glucal compared to that of D-galactal occured at a faster rate and also yielded a byproduct of yet unknown structure. In the presence of glycerol as acceptor, D-glucal as well as D-galactal formed glyceryl 2-deoxy-β-D-glycosides. In this case also D-glucal yielded two byproducts which, according to preliminary investigations, seem to be glyceryl pseudoglucal derivatives. The enzymic hydration is irreversible. Glyceryl 2-deoxy-β-D-lyxo-hexopyranoside was hydrolyzed by β-D-galactosidase to give glycerol and 2-deoxy-D-lyxo-hexose. The mechanism of the enzymic hydration and glycosylation of glycals is discussed.     

o-nitrophenyl 6-deoxy-3-O-(6-deoxy-β-d-xylo-hex-5-enopyranosyl)-β-d-xylo-hex-5-enopyranoside,the major product of β-d-glucosidase action on o-nitrophenyl 6-deoxy-β-d-xylo-hex-5-enopyranoside

Incubation of o-nitrophenyl 6-deoxy-β-d-xylo-hex-5-enopyranoside (1) with emulin β-d-glucosidase gave, instead of the expected 6-deoxy-d-xylo-hexos-5-ulose (3), o-nitrophenyl 6-deoxy-3-O-(6-deoxy-β-d-xylo-hex-5-enopyranosyl)-β-d-xylo-hex-5-enopyranoside (2) in high yield (≈90% under optimal conditions). The structure of 2 was established from spectroscopic data and by correlation with compounds synthesised definitively. The specificity of the transfer reaction is discussed as an argument for an acceptor or aglycon binding-site.     

Synthesis of 5-deoxy-5-fluorosporaricin A

The structures of the O-specific side-chains in the lipopolysaccharides of Salmonella greenside, group Z, and Salmonella adelaide, group O, have been investigated. The former proved to be identical with that of Escherichia coli O 55. The latter, which was more extensively studied, was composed of repeating units having the structure

in which Col is colitose (3,6-dideoxy-l-xylo-hexose). This was also shown to be the biological repeating-unit. The same structure has been proposed for the O-antigen of E. coli O 111. The biological repeating-unit for the S. greenside O-antigen was also defined. The structural studies also confirmed that both lipopolysaccharides contain the hexose region typical for the Salmonella core.     

An active site-directed, irreversible inactivation of yeast hexokinase by (R,S)2,3-epoxypropyl beta-D-glucopyranoside

(1) Only (R,S)2′,3′-epoxypropyl β-d-glucopyranoside of the complete series of mono (R,S)2′.3′-epoxypropyl ethers and glycosides of d-glucopyranose significantly inactivated yeast hexokinase.(2) (R,S)2′,3′-Epoxypropyl β-d-glucopyranoside inactivates yeast hexokinase in the absence of MgATP^2?, The rate of inactivation is unaffected by MgATP^2?.(3) The rate of inactivation of hexokinase with (R,S)2′,3′-epoxypropyl β-d-ilucopyranoside was much greater when hexokinase was present in a monomeric form than when it was present in a dimeric form.(4) (R,S)2′,3′-Epoxypropyl β-d-glucopyranoside has a high K_t (0.38 M) and at a saturating concentrarion, the first order rate constant for the inactivation of monomeric hexokinase is 8.3 · 10^?4 sec.(5) d-Glucose protects against this inactivation and this was used to derive a dissocistion constant of 0.21 mM for d-glucose in the absence of MgATP^2?.(6) The alkylation of yeast hexokinase by (R,S)2′,3′-epoxypropyl β-d-gluco-pyranoside was not specific to the active site. When the concentration of (R,S)2′,3′-epoxypropyl β-d-glucopyranoside was 50 mM two thiol groups outside the active site were also alkylated.(7) The reaction between 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB) and yeast hexokinase was examined in detail. Two thiol groups per monomer (mol. wt. 50000) reacted with a second order rate constant of 27 1 mole^?1 sec^?1. A third thiol group reacted more slowly with a second-order rate constant of 1.6 1 mole^?1 sec^?1 and a fourth thiol group reacted very slowly with inactivation of the enzyme. Tue second-order rate constant in this case was 0.1 1 mole^?1 sec^?1.     

Hexose kinases from the plant cytosolic fraction of soybean nodules

The enzymes responsible for the phosphorylation of hexoses in the plant cytosolic fraction of soybean (Glycine max L. Merr cv Williams) nodules have been studied and a hexokinase (ATP:d-hexose 6-phosphotransferase EC 2.7.1.1) and fructokinase (ATP:d-fructose 6-phosphotransferase EC 2.7.1.4) shown to be involved. The plant cytosolic hexokinase had optimum activity from pH 8.2 to 8.9 and the enzyme displayed typical Michaelis-Menten kinetics. Hexokinase had a higher affinity for glucose (K_m 0.075 millimolar) than fructose (K_m 2.5 millimolar) and is likely to phosphorylate mainly glucose in vivo. The plant cytosolic fructokinase had a pH optimum of 8.2 and required K⁺ ions for maximum activity. The enzyme was specific for fructose (apparent K_m 0.077 millimolar) but concentrations of fructose greater than 0.4 millimolar were inhibitory. The native molecular weight of fructokinase was 84,000 ± 5,000. The roles of these enzymes in the metabolism of glucose and fructose in the host cytoplasm of soybean nodules are discussed.     

Acid-catalysed monoacetalation of some 2-deoxyalditols

Acid-catalysed monobutylidenation of 2-deoxy-D-arabino-hexitol, 2-deoxy-D-lyxo-hexitol, and 2-deoxy-D-erythro-pentitol yielded a 1,3-monoacetal as a kinetic product in each reaction. The thermodynamic products were 4,6-monoacetals from 2-deoxy-D-arabino-hexitol and 2-deoxy-D-lyxo-hexitol, and a 3,5-monoacetal from 2-deoxy-D-erythro-pentitol 2-Deoxy-D-lyxo-hexitol also yielded diastereoisomeric 4,5-monoacetals.     

Enzymes of sucrose breakdown in soybean nodules: alkaline invertase

The specific activities of acid and alkaline invertases (β-d-fructofuranoside fructohydrolase, EC 3.2.1.26), sucrose synthase (UDPglucose: d-fructose 2-α-d-glucosyltransferase, EC 2.4.1.13), hexokinase (ATP: d-hexose 6-phosphotransferase, EC 2.7.1.1), and fructokinase (ATP: d-fructose 6-phosphotransferase, EC 2.7.1.4) were determined in soybean (Glycine max L. Merr cv Williams) nodules at different stages of development and, for comparison, in roots of nonnodulated soybeans. Alkaline invertase and sucrose synthase were both involved in sucrose metabolism in the nodules, but there was only a small amount of acid invertase present. The nodules contained more phosphorylating activity with fructose than glucose. Essentially all of the alkaline invertase, sucrose synthase, and fructokinase were in the soluble fraction of nodule extracts whereas hexokinase was in the bacteroid, plant particulate, and soluble fractions.     

Structure of the O-antigen of Yersinia pseudotuberculosis O:4a revised

The O-specific polysaccharide was isolated by mild acid degradation of the lipopolysaccharide of Yersinia pseudotuberculosis O:4a and studied by NMR spectroscopy, including 2D ROESY and ¹H, ¹³C HMBC experiments. The following structure of the pentasaccharide repeating unit of the polysaccharide was established, which differs from the structure reported earlier [Gorshkova, R. P. et al., Bioorg. Khim. 1983, 9, 1401-1407] in the linkage modes between the monosaccharides: where Tyv stands for 3,6-dideoxy-d-arabino-hexose (tyvelose). The structure of the Y. pseudotuberculosis O:4a antigen resembles that of Y. pseudotuberculosis O:2c, which differs in the presence of abequose (3,6-dideoxy-d-xylo-hexose) in place of tyvelose only.     

The characterisation of the reaction between (r,s)2′,3′-epoxypropyl β-d-glucopyranoside and yeast hexokinase: Evidence for the presence of a cysteine residue in the binding site of d-glucose

After the inactivation of yeast hexokinase with (R,S)2′,3′-epoxypropyl β-d-[U-¹⁴C]glucopyranoside (50 mM), four moles of this inhibitor were found to be bound per mole of hexokinase monomer (mol.wt., 50 000). The hexokinase inactivated in this way did not show any reaction with 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB) in 8 M urea; this is consistent with the alkylation of four cysteine residues per monomer by (R,S)2′,3′-epoxypropyl β-d-glucopyranoside.Amino acid analyses of hexokinase which had been alkylated with (R,S)2′,3′-epoxypropyl β-d-glucopyranoside and then oxidised with performic acid gave evidence for the alkylation of two types of cysteine residue, one type reactive towards DTNB and not essential for enzyme activity, the other type less reactive towards DTNB and essential for enzyme activity.The presence of a cysteine residue in the binding site of d-glucose is proposed and a mechanism for the binding of d-glucose involving an intermediate covalent, d-glucose enzyme complex is suggested.     

The structure and properties of the products of reaction between 3,4,6-tri-O-acetyl-2-deoxy-2-nitroso-α-d-galactopyranosyl chloride and pyrazole

Dimeric 3,4,6-tri-O-acetyl-2-deoxy-2-nitro-α-d-galactopyranosyl chloride reacts with pyrazole in acetonitrile to give 1-(3,4,6-tri-O-acetyl-2-deoxy-2-hydroxyimino-α-d-lyxo-, -β-d-lyxo-, and -β-d-xylo-hexopyranosyl)pyrazole. The stereospecificity of the reaction depends on the temperature and its duration. Transformations of the type α-d-lyxo-←β-d-lyxoα β-d-xylo have been observed. The condensation products were modified at C-2 or C-3. The following derivatives have thus been obtained: 1-(α-d-galacto-, 2-acetamido-2-deoxy-α-d-galacto-, -α-d-talo-, and -α-d-xylo-hexo-pyranosyl)pyrazole, (Z)- and (E)-1-(3-azido-2,3-dideoxy-2-hydroxyimino-α- and -β-d-lyxo- and -α-d-xylo-hexopyranosyl)pyrazole, 1-(3-acetamido-2-acetoxyimino-4,6-di-O-acetyl-2,3-dideoxy-α- and -β-d-lyxo-hexopyranosyl)pyrazole, as well as (Z)- and (E)-1-(2,3-dideoxy-2-hydroxyimino-α-d-threo-hexopyranosyl)pyrazoles.