1,5-Anhydro-4-deoxy-d-glycero-hex-1-en-3-ulose and other pyrolysis products of cellulose

Uncatalyzed pyrolysis of cellulose provides a tar containing mainly 1,6-anhydro-d-glucose derivatives and some unsaturated products. The latter include a new enone that has been isolated by preparative column chromatography in 1.4% yield and identified as 1,5-anhydro-4-deoxy-d-glycero-hex-l-en-3-ulose. This compound is also formed by pyrolysis of other carbohydrate polymers. A mechanism for its production from internal units has been deduced from the experimental data. The pyrolysis products of cellulose also contain 3,5-dihydroxy-2-methyl-4H-pyran-4-one, which appears to be an oxidation product.     

Preparation of 1,6-anhydro-3,4-dideoxy-β-D-glycero-hex-3-enopyranos-2-ulose (levoglucosenone) and some derivatives thereof

1,6-Anhydro-3,4-dideoxy-β-D-glycero-hex-3-enopyranos-2-ulose (levoglucosenone) was prepared on a laboratory scale by pyrolysis of H₃PO₄-treated, Kraft waste-paper. The aldehyde components of the pyrolyzate were removed by reaction with 5,5-dimethyl-1,3-cyclohexanedione (dimedone), and levoglucosenone was obtained in 3.3% yield by distillation of the remaining material. A variety of deoxy, keto, and branched-chain sugars was obtained by reduction of levoglucosenone, and by its reaction with Grignard reagents under different conditions.     

Selenium derivatives of L-arabinose, D-ribose,and D-xylose

Attempted cyclization of 2,3,4-tri-O-methyl-5-seleno-L-arabinose dimethyl acetal in acidic solution gave the corresponding diselenide. Intramolecular attack by the selenobenzyl group at C-5 of 5-O-p-tolylsulfonyl-L-arabinose dibenzyl diseleno-acetal resulted in the formation of benzyl 1,5-diseleno-L-arabinopyranoside. Similarly, 2,3,5-tri-O-methyl-4-O-p-tolylsulfonyl-D-xylose dibenzyl diselenoacetal gave benzyl 2,3,5-tri-O-methyl-1,4-diseleno-L-arabinofuranoside, and 2,3,4-tri-O-acetyl-5-O-p-tolylsulfonyl-D-xylose (or ribose) dibenzyl diselenoacetal gave benzyl 2,3,4-tri-O-acetyl-1,5-diseleno-D-xylo- (or ribo-)pyranoside. The glycosylic benzylseleno group was removed from the pyranoside with mercuric acetate, but attempted deacetylation of the product led to decomposition and not to the expected 5-seleno-D-xylopyranose.     

Proton magnetic resonance spectra of D-gluco-oligosaccharides and D-glucans

The p.m.r. spectra of some D-gluco-oligosaccharides and D-glucans in deuterium oxide were studied with respect to the anomeric proton. In (1→2)-linked glucobioses, the effect of change in configuration of the hydroxyl group at C-1 on the chemical shifts of the glycosidic proton is noted. Equilibrium mixtures of (1→2)-linked glucobioses contained more α-anomer than did the other examples, despite the cis configuration of substituents at C-1 and C-2. Some D-glucans were investigated with regard to the degree of branching, although solubility was a limitation.     

Alkali and oxygen-alkali treatment of D-arabino-hexosulose and O-β-D-glucopyranosyl-(1 → 4)-d-arabino-hexosulose.

Benzilic acid rearrangement of D-arabino-hexosulose (1) and O-β-D-glucopyranosyl-(1→4)-D-arabino-hexosulose (2) favours formation of mannonic acid and mannonic acid moieties, respectively. The results show that formation of aldonic acid end-groups via terminal aldosulose moieties is of little importance during oxygen-hydrogencarbonate treatment of (1→4)-linked polysaccharides. The major reaction of 1 in the absence of oxygen involves loss of C-1 as formic acid. The enediol intermediate gives rise to pentoses and pentuloses (degraded completely at high alkalinity), and 3-deoxypentonic acids. The yield of 3-deoxypentonic acids is decreased in the presence of oxygen, whereas that of arabinonic, erythronic, and glycolic acids is increased. The main reaction of 2 giving rise to aliphatic hydroxy acids is β-elimination of the glucose moiety, yielding a tricarbonyl intermediate (3) which, in sodium hydrogencarbonate, is decomposed mainly to 3,4-dihydroxybutanoic and glycolic acids. In sodium hydroxide, 3-deoxypentonic acids are among the major reaction products. In addition, a complex mixture of u.v.-absorbing solutes is formed, some of which are held irreversibly by anion exchangers.     

Quantitation of l-glycero-d-manno-heptose and 3-deoxy-d-manno-octulosonic acid in rough core lipopolysaccharides by partition chromatography

A partition chromatographic procedure utilizing a cationic exchange resin column in the Li⁺ form and 90% ethanol as the mobile phase was employed to quantify 3-deoxy-d-manno-octulosonic acid (KDO) and l-glycero-d-manno-heptose in the lipopolysaccharides (LPS) of R_e and R_dP^? rough mutants of Salmonella minnesota. In a standard mixture of monosaccharides, KDO eluted shortly after the void volume and heptose eluted after the neutral hexoses. Mild acid treatment of either the R_e or R_dP^? LPS with 0.16 n methanesulfonic acid in the presence of Dowex 50-X8 resin (H⁺ form) released more than 80% of the KDO residues within 15 min. The heptose of the R_dP^? LPS, first detected after 90 min of hydrolysis, increased gradually to a maximum level at 12 h. A secondary gradual increase in KDO became apparent during the heptose release. The weight contents of these two monosaccharides based upon aheir maximum values detected during hydrolysis were 20.3 ± 0.6% KDO, for the R_e LPS, and 13.8 ± 0.4% KDO and 12.0 ± 0.4% heptose, for the R_dP^? LPS. The relationship between the kinetics of release of KDO and heptose and the nature of the linkages involving these two monosaccharides are discussed.     

Reaction of some D-glucobioses with 2,2-dimethoxypropane

Laminarabiose, cellobiose, and gentiobiose were acetonated with 2,2-dimethoxy-propane under various conditions. Two isopropylidene acetals in which the reducing D-glucose residue had the furanoid form were obtained from laminarabiose, and two, in which the reducing D-glucose residue formed the acyclic dimethyl acetal, from cellobiose. Gentiobiose gave both types of isopropylidene compound.     

Spontaneous reactions of the irreversible β-D-galactosidase inhibitor 2,6-anhydro-1-deoxy-1-diazo-D-glycero-L-manno-heptitol

2,6-Anhydro-1-deoxy-1-diazo-D-glycero-L-manno-heptitol (2) decomposes in 0.01M methanolic sodium methoxide with a half-life of approx. 18 min. Decomposition in aqueous solution is too rapid for spectrophotometric measurement. Seven products could be identified in methanolic and aqueous reaction mixtures. 2,6-Anhydro-1-deoxy-D-galacto-hept-1-enitol (6), 2,7-anhydro-1-deoxy-β-D-galacto-heptulopyranose (10), and 4-O-vinyl-D-lyxose (12) are products of rapid intramolecular reactions. The major portion consists of the direct solvolysis products 2,6-anhydro-1-O-methyl-D-glycero-L-manno-heptitol (3) and 2,6-anhydro-D-glycero-L-manno-heptitol (5).     

A non-hydrogen-bonding role for the 4-hydroxyl group of D-Galactose in its reaction with D-Galactose oxidase

Several 4-deoxy analogs of methyl β-D-galactopyranoside are oxidized by D-galactose oxidase. The rates associated with their various, axially attached 4-substituents follow the sequence OH>NH₂>F?>Cl> H; these differences are attributed mainly to variations in K_m. Other 4-deoxy analogs, namely, the 4-azido-4-deoxy, 4-bromo-4-deoxy-, 4-deoxy-4-iodo, and 4-thio derivatives were found to be inactive. These observations indicate that the axial 4-hydroxyl group of D-galactopyranose does not play a hydrogen-bonding role primarily, but constitutes a substituent of a size optimal for interaction with the enzyme.     

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.     

The synthesis of D-xylo-hexos-4-ulose and some derivatives

D-xylo-Hexos-4-ulose has been synthesised, characterised chromatographically, and methyl α-D-xylo-hexopyranosid-4-ulose has been shown to be stable in neutral aqueous solution, contrary to a previous report. Glycosyl phosphate derivatives are also reported.     

Synthesis of 3-O Substituted D-Mannoses

1,2,4,6-Tetra-O-acetyl-3-O-benzyl-α-D-mannopyranose (7) was obtained in good yield from 3,4,6-tri-O-benzyl-1,2-O-(1-methoxyethylidene)-β-D-mannopyranose (1) by acetolysis. Hydrogenolysis of 7 afforded 1,2,4,6-tetra-O-acetyl-α-D-mannopyranose which is a versatile intermediate for the preparation of other 3-O-substituted D-mannoses, such as 3-O-methyl-D-mannose and 3-O-α-D-mannopyranosyl-D-mannose. 3,4-Di-O-methyl-D-mannose was readily prepared from 1,2,6-tri-O-acetyl-3,4-di-O-benzyl-α-D-mannopyranose, which was also obtained from 1 by controlled acetolysis.     

Untersuchungen zur modifikation der cellobiose und synthese von methyl-2,6-didesoxy-4-O-(6-desoxy-β-D-glucopyranosyl)-α-D-arabino-hexopyranosid (methyl-4-O-β-D-chinovosyl-α-D-olivosid)

Starting with cellobiosides, several different procedures were employed to prepare 6,6′-dichloro-6,6′-dideoxy, 6,6′-dibromo-6,6′-dideoxy, and 6,6′-dideoxy-6,6′-diiodo derivatives. Reduction with lithium aluminum hydride or nickel boride afforded peracetyl derivatives of methyl, phenyl, and benzyl 6-deoxy-4-O-(6-deoxy-β-D-glucopyranosyl)-β-D-glucopyranoside. Following acetolysis or hydrogenolysis, the glycosyl halide and the corresponding-glycal 40 were prepared. Iodomethoxylation of 40 and subsequent reduction gave the title compound. Alternatively, the halomethoxylation products of cellobial hexaacetate gave, by various procedures, the 2,6,6′-trideoxy-2,6,6′-trihalo derivatives, which, in turn, could be reduced to the title compound. The structures of the derivatives prepared were unequivocally assigned by n.m.r. spectroscopy. The various reaction sequences were compared with respect to the number of steps and the yields obtained.     

Metabolism of 14C-labelled D-glucose, D-fructose and allitol by Itea plants

The metabolism of D-[1-¹⁴C]glucose, D-[6-¹⁴C]glucose, D-[1-¹⁴C]fructose and D-[6-¹⁴C]fructose by leafy spurs of Itea plants results in rapid incorporation of label into allitol and D-allulose. The patterns of labelling found in the allitol and D-allulose are discussed, a direct interconversion from D-glucose and D-fructose being indicated. Allitol has been found to be an active metabolite in Itea plants.     

Synthesis of D-ristosamine and its derivatives

A convenient preparative route involving eleven steps starting from D-glucose is described for the synthesis of D-ristosamine (15) hydrochloride. Methyl 2-deoxy-β-D-arabino-hexopyranoside, prepared from 3,4,6-tri-O-acetyl-1,5-anhydro-2-deoxy-D-arabino-hex- 1-enitol, was benzylidenated, and the product mesylated to give methyl 4,6-O-benzylidene-2-deoxy-3-O-methylsulfonyl-β-D-arabino-hexopyranoside. Azidolysis of this compound and subsequent opening of the 1,3-dioxane ring with N-bromosuccinimide gave methyl 3-azido-4-O-benzoyl-6-bromo-2,3,6-trideoxy-βD-ribo-hexopyranoside. Simultaneous reduction of the azido and bromo groups gave a mixture that was benzoylated to give methyl N,O-dibenzoyl-β-D-ristosaminide and then hydrolyzed to 15 hydrochloride (3-amino-2,3,6-trideoxy-D-ribo-hexopyranose hydrochloride).     

D-Galactose 6-phosphate: anomeric distribution and analysis of its synthesis from D-galactose and polyphosphoric acid

D-Galactose 6-phosphate as synthesized by direct phosphorylation of D-galactose with polyphosphoric acid is contaminated with two of its positional isomers. These were separated from D-galactose 6-phosphate and from each other, and identified as D-galactose 3- and 5-phosphate by enzymic, chromatographic, and mass-spectral analysis. The previous misidentification of these isomers as furanose forms of D-galactose 6-phosphate has led to erroneous reports concerning the anomeric distribution of D-galactose 6-phosphate. The anomeric distribution of D-galactose 6-phosphate in a purified preparation was determined by gas-liquid chromatography and ¹³C-n.m.r. spectroscopy to be 32% α-pyranose, 64% β-pyranose, and no more than 4% furanose anomers.     

Reaction of methyl β-d-glycero-l-manno-heptopyranoside with cyclohexanone: Synthesis of the 4- and 6-methyl ethers of d-glycero-l-manno-heptitol

Acid-catalysed condensation of methyl β-d-glycero-l-manno-heptopyranoside with cyclohexanone yielded an approximately 3:1 mixture of the 2,3:6,7- and 2,3:4,7-di-O-cyclohexylideneheptosides (1 and 2), which could be separated either as their benzoates (3 and 4) or as their methyl ethers (5 and 6). The latter compounds afforded the 4- and 6-methyl ethers (7 and 8) of d-glycero-l-manno-heptitol.