Synthesis of 3-deoxy-4-O-β-D-galactopyranosyl-D-erythro-hexos-2-ulose and of some of its derivatives from lactose

3-Deoxy-4-O-β-D-galactopyranosyl-D-erythro-hexos-2-ulose (1) was obtained from lactose by reaction with benzoylhydrazine in the presence of a slightly acidic solution of p-toluidine, followed by hydrazinolysis of the product, 3-deoxy-4-O-β-D-galactopyranosyl-D-erythro-hexos-2-ulose bis(benzoylhydrazone) (3), with benzaldehyde. A variety of derivatives of 1 and 3 was prepared. Lactose aroylhydrazones were also prepared. Quantitative determination of the oxidant during the periodate oxidation of 3 was studied. Periodate oxidation of monosaccharide arylhydrazones gave glyoxal mono(arylhydrazones) which afforded the corresponding, mixed bis(hydrazones).     

C-(polyacetoxy)alkyloxadiazolines and related compounds

The (phenylacetyl)hydrazones of d-galactose, d-glucose, d-mannose, d-arabinose, l-arabinose, d-xylose, and l-sorbose were prepared. The d-galactose and d-arabinose derivatives were converted into their per-O-acetylated derivatives (8 and 9, respectively). The acyclic structure of 8 was proved from its direct preparation by the condensation of(phenylacetyl)hydrazine with penta-O-acetyl-aldehydo-d-galactose. Cyclization of 2,3,4,5,6-penta-O-acetyl-aldehydo-d-galactose (phenylacetyl)hydrazone with boiling acetic anhydride yielded a mixture of two products that could be separated by fractional recrystallization, to give 3-acetyl-5-benzyl-2-(polyacetoxy)alkyl-1,3,4-oxadiazolines; a mechanism for the reaction was proposed. The n.m.r. and mass spectra of some of these derivatives were discussed.     

Reactions of d-glucose,d-xylose,and d-erythrose with 2-methyl-2-propanethiol

The reaction of d-glucose and d-xylose with 2-methyl-2-propanethiol in conc. hydrochloric acid yielded tert-butyl 1-thioglycopyranosides (products of kinetic and thermodynamic control). Di-tert-butyl dithioacetals (12–14) were obtained from the acetylated aldehydo-derivatives of d-glucose, d-xylose, and d-erythrose. On brief treatment with conc. hydrochloric acid, 12 and 13 gave tert-butyl 1-thio-α- and -β-glycopyranosides and 14 gave the corresponding furanosides.     

Kinetics of the enzymatic hydrolysis of cellulose: 1. A mathematical model for a batch reactor process

A mathematical model for enzymatic cellulose hydrolysis, based on experimental kinetics of the process catalysed by a cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] preparation from Trichoderma longibrachiatum has been developed. The model takes into account the composition of the cellulase complex, the structural complexity of cellulose, the inhibition by reaction products, the inactivation of enzymes in the course of the enzymatic hydrolysis and describes the kinetics of d-glucose and cellobiose formation from cellulose. The rate of d-glucose formation decelerated through the hydrolysis due to a change in cellulose reactivity and inhibition by the reaction product, d-glucose. The rate of cellobiose formation decelerated due to inhibition by the product, cellobiose, and inactivation of enzymes adsorbed on the cellulose surface. Inactivation of the cellobiose-producing enzymes as a result of their adsorption was found to be reversible. The model satisfactorily predicts the kinetics of d-glucose and cellobiose accumulation in a batch reactor up to 70–80% substrate conversion on changing substrate concentration from 5 to 100 g l^?1and the concentration of the enzymic preparation from 5 to 60 g l^?1.     

Affinity purification and glucose specificity of aldose reductase from bovine lens

Aldose reductase, a possible key enzyme of sugar-cataract formation in diabetes, has been purified from bovine lens by a five-step procedure including affinity chromatography with Mātrex gel red A. The enzyme was purified 12,600-fold and was apparently homogeneous by polyacrylamide gel electrophoresis. The glucose specificity of the purified enzyme was studied with d-glucose anomers and d-glucitol as substrates. The ratios of the reduction rate of α-d-glucose to that of β-d-glucose at 10, 13, and 20 mm were 1.90, 1.76, and 1.72, respectively. These values were in good agreement with the ratios (1.92, 1.81, and 1.66) calculated on the basis of the rate constants reported for d-glucose mutarotation equilibrium (J. M. Los, L. B. Simpson, and K. Wiesner, 1956, J. Amer. Chem. Soc.78, 1564–1568) and the assumption that aldose reductase acts on the aldehyde form of d-glucose. In addition, the composition of d-glucose produced from d-glucitol in the reverse reaction was 63% α anomer and 37% β anomer, which also agreed well with the values, 65 and 35%, respectively, calculated from the rate constants in reactions from the aldehyde form to both the α anomer and the β anomer. It was suggested from these kinetic analyses that aldose reductase acts on the aldehyde form of d-glucose (K_m = 0.66 μm) but not on either the α or the β anomer of d-glucose.     

Preparation of some (1→6)-linked disaccharides,and their derivatives suitable for protein modification

Synthetic methods for the preparation of per-O-acetylated, (1→6)-linked disaccharides containing either a d-galactose or a d-glucose residue at the reducing end are described. In these methods, 1,2,3,4-tetra-O-acetyl-6-O-trityl-β-d-glucopyranose was first converted into 1,2,3,4-tetra-O-acetyl-β-d-glucopyranose (1) by rapid treatment with 90% trifluoroacetic acid, followed by rapid isolation designed to minimize O-acyl migration. Disaccharides were formed by glycosylation of 1 or 1,2:3,4-di-O-isopropylidene-d-galactopyranose with per-O-acetylglycosyl halides. Isopropylidene groups in the resulting disaccharide, if present, were removed, and the disaccharide was per-O-acetylated. Per-O-acetylated β-Gal-(1→6)-Glc and β-GlcNAc-(1→6)-Gal, and a mixture of per-O-acetylated α-Gal-(1→6)-Gal and β-Gal-(1→6)-Gal (in the ratio of 3:7) were thus obtained. The per-O-acetylated Gal-(1→6)-Gal disaccharides were converted, by a reaction sequence previously reported, into (2,2-dimethoxyethyl)aminocarbonylmethyl 1-thio-β-d-glycosides, which could then be coupled to proteins via reductive alkylation. For the anomeric mixture of per-O-acetylated Gal-(1→6)-Gal, conversion into the corresponding 1-thioglycoside permitted resolution of the isomers by chromatography on silica gel. When disaccharides, as borate complexes, were chromatographed on a column of a strong, anion-exchange resin, all of the (1→6)-linked disaccharides of neutral sugars tested (including melibiose) were eluted later than analogous disaccharides having other linkages, and also later than any neutral monosaccharides.     

Pyrimidine homonucleoside analogues from 2,5-anhydroaldose derivatives

3,4-Di-O-acetyl-2,5-anhydro-D-xylose diisobutyl dithioacetal (1) reacts with bromine to give a monobromo derivative which, on condensation with 2,4-diethoxy-pyrimidine or its 5-methyl analogue, affords the protected nucleoside derivatives 4 and 11, respectively; ammonolysis of 4 gave the cytosine “homonucleoside” 7, and hydrolysis of 11 gave the thymine “homonucleoside” 12. The same type of “homonucleoside” may be produced by cyclization of the sugar chain in a suitable acyclic-sugar nucleoside, as in the conversion of 1-S-ethyl-1-thio-1-(uracil-1-yl)-D-xylitol (16, obtained from tetra-O-acetyl-D-xylose diethyl dithioacetal, 9), by the action of one molar equivalent of p-toluenesulfonyl chloride, into a homonucleoside isolated as its diacetate 17; acyclic-sugar derivatives not susceptible to such cyclization afford instead the 5-p-toluenesulfonates, as exemplified by the conversion of the D-arabino analogue (13) of 16 into the 5′-ester 14. When cyclohexene is used to remove the excess of bromine in the preparation of nucleoside analogues from dithioacetals, the alkylsulfenyl bromide produced may react, by way of its cyclohexene adduct, with the hoterocyclic base to give cyclohexane-base adducts, for example, compounds 6 and 10.     

Glycosides for testing glycosidases: Vinyl,l-ethoxyethyl,and l-ethoxybut-3-enyl d-glucopyranosides

The reaction of ethyl vinyl ether and 2,3,4,6-tetra-O-acetyl-β-d-glucopyranose (1) in the presence of Hg-(OAc)₂ and toluene-p-sulphonic acid as catalysts yielded the acetylated vinyl, l-ethoxyethyl, and l-ethoxybut-3-enyl glycosides in varying proportions. Crystalline l-ethoxybut-3-enyl 2,3,4,6-tetra-O-acetyl-β-d-glucopyranoside (2), vinyl 2,3,4,6-tetra-O-acetyl-α-d-glucopyranoside (3), and l-ethoxyethyl 2,3,4,6-tetra-O-acetyl-β-d-glucopyranoside (4) were isolated by chromatography. Compound 4 was also prepared by the reaction of 1 with cold acetaldehyde diethyl acetal containing a trace of acetic acid, and its α anomer (5) by the reaction of 1 with boiling acetaldehyde diethyl acetal containing a trace of acetic acid. Each deacetylated d-glucoside was cleaved by the corresponding d-glucosidase, to yield d-glucose and either acetaldehyde (from deacetylated 3-5) or but-3-enal (from deacetylated 2).     

Reactions of 3-(1-arylhydrazono-L-threo-2,3,4-trihydroxybutyl)-1-methyl-2-Quinoxalinones

The 1-methyl derivatives (3 and 4) of 3-(1-phenyl- (1) and 3-(1-p-bromophenylhydrazono-L-threo-2,3,4-trihydroxybutyl)-2-quinoxalinone (2) were prepared by methylation. Periodate oxidation of 3 gave 1-methyl-3-[1-(phenylhydrazono)glyoxal-1-yl]-2-quinoxalinone (5), which, on reduction with sodium borohydride, gave the corresponding 3-[2-hydroxy-1-(phenylhydrazono)ethyl] derivative (8). Reaction of 5 with hydroxylamine or benzoylhydrazine gave the corresponding 2-oxime (6) and 2-(benzoylhydrazone) (7), respectively. Acetic anhydride causes one molecule of 3 or 4 to undergo elimination of two molecules of water, with simultaneous acetylation and ring closure to afford pyrazoles 9 and 10, respectively. Pyrolysis of the triacetate of 3 led to the elimination of acetic acid from the sugar and the hydrazone residue, to give the 3-[5-(acetoxymethyl)-1-phenylpyrazol-3-yl] derivatives (9). Acetic acid was found to effect the same rearrangement, but without acetylation, of 1, 2, and 3 to give the 3-[5-(hydroxymethyl)] derivatives 11, 12, and 13, respectively. The structure of these pyrazoles was confirmed by a series of reactions, including methylation and acetylation. The n.m.r. and i.r. spectra of the compounds were investigated.     

The crystal structure of potassium (1S)-D-galactit-1-ylsulfonate

The structure of the crystalline addition product (1) formed between d-galactose and potassium bisulfite (potassium hydrogen sulfite) has been determined by X-ray diffraction analysis and compared with those structures reported for the related addition products from d-glucose and d-mannose. As with the latter two sulfonates, the d-galactose derived compound has an open-chain structure, with the carbon chain adopting a near planar zigzag conformation extending to the sulfur atom, similar to the d-mannose derivative but in contrast to the sickle conformation adopted by the d-glucose derivative. This last compound also differs in crystallising as a monohydrate. Inter-chain linking through cation coordination leads to a three dimensional network in the crystal.     

Reactions of the bis(p-tolylsulfonylhydrazone) of periodate-oxidized methyl 4,6-O-benzylidene-α-D-glucopyranoside with borohydride and cyanoborohydride: novel syntheses of unsaturated and deoxy sugars

Periodate-oxidized methyl 4,6-O-benzylidene-α-D-glucopyranoside (1) reacted with p-toluenesulfonylhydrazine to give the substituted bis(hydrazone) 2, which was converted into an N-substituted epimino derivative (3) by treatment with sodium borohydride in ethanol. Compound 3 was further converted into the glyc-2-enoside 4 by heating it with sodium borohydride in 1,4-dioxane. Sodium cyanoborohydride in ethanol reduced 2 to an epimeric mixture of 2-deoxy-D-arabino (5) and D-ribo (6)-hexoside derivatives. In the presence of an acidic resin in the same solvent, however, compound 2 underwent hydrogenation to the bis(hydrazino) derivative (7). The mechanisms of these reactions are discussed.     

Synthesis,X-ray structures and characterization of beryllium phthalocyanine and (2-ethoxyethanol)-aqua-beryllium phthalocyanine

Crystals of beryllium phthalocyanine (I) were obtained from the reaction of beryllium pieces with 1,2-dicyanobenzene at 270 °C. In subsequent preparatory work the beryllium phthalocyanine was transformed into the monoaxially ligated compound (2-ethoxyethanol)-aqua-beryllium phthalocyanine (II). The crystal structures of (I) and (II) were determined by single crystal X-ray diffraction. Based on thermogravimetric measurements, a conversion of the beryllium phthalocyanine into beryllium phthalocyanine monohydrate in wet air has been followed in detail. The beryllium phthalocyanine monohydrate and compound II loose the ligated water and 2-ethoxyethanol in the 150 °C region. The EPR spectra of the beryllium phthalocyanine complexes as exposed to air have been recorded and discussed.     

Acyclic nucleoside phosphonates with 5-azacytosine base moiety substituted in C-6 position

Two methods for preparation of 6-substituted derivatives of anti DNA-viral agent 1-(S)-[3-hydroxy-2-(phosphonomethoxy)propyl]-5-azacytosine (HPMP-5-azaC) were developed: (1) ammonia mediated ring-opening reaction of diisopropyl esters of HPMP-5-azaC (4) to carbamoylguanidine derivatives followed by ring-closure reaction with orthoesters and (2) condensation reaction of 6-substituted 5-azacytosines with diisopropyl (1S)-[2-hydroxy-1-tosyloxymethyl)ethoxy]methylphosphonate (15). Deprotection of diisopropyl esters to free phosphonic acids was performed with bromotrimethylsilane in acetonitrile followed by hydrolysis. In contrast to parent compound HPMP-5-azaC, a substantial decrease of antiviral activity in case of 6-substituted analogues occurred. Surprisingly, N-3 isomer of 6-methyl-HPMP-5-azaC in the form of isopropyl ester revealed activity against RNA viruses (Sindbis virus).     

Branched-chain sucroses: Synthesis and Wittig reaction of the 1′-aldehydo derivative of sucrose

The reaction of 2,3,4,3′,4′-penta-O-acetylsucrose (1) with 3.3 mol. equiv. of tert-butyldiphenylsilyl chloride in pyridine in the presence of 4-dimethylamino-pyridine gave the 6,1′,6′-tris(tert-butyldiphenylsilyl) derivative 2 (27%) and the 6,6′-bis(tert-butyldiphenylsilyl) derivative (67%). Oxidation of the HO-1′ in 3 with methyl sulphoxide and trifluoroacetic anhydride gave the 1′-aldehydo derivative 5, which reacted with the stabilised Wittig reagent (Ph₃PCHCO₂Et) to give the 1′-ethoxycarbonylmethylene derivative 6. Deacetylation of the hepta-acetate 7 of 6 with methanolic sodium methoxide was accompanied by a Michael addition reaction to give 2,1′-anhydro-1′-methoxycarbonylmethylsucrose.     

Synthesis and photochemical redox reactivity of an unsymmetrically substituted MnMn Bond: mer,fac-Mn2(CO)6(PMe2CH2PMe2)2

The reaction of Mn₂(CO)₁₀ with the diphosphine bis(dimethylphosphino)methane, dmpm, gives a mixture of two isomers: mer, fac-Mn₂(CO)₆(dmpm)₂, 1, and mer,mer-Mn₂(CO)₆(dmpm)₂, 2. Complex 1 is the first example of a bis(dmpm) complex with a cis,trans arrangement of the dmpm ligands. Both 1 and 2 can be thermally oxidized by one-electron to give the relatively stable binuclear radial cations [mer,fac-Mn₂(CO)₆(dmpm)₂]⁺, 3, and [mer,mer- Mn₂(CO)₆(dmpm)₂]⁺ , 4, respectively. The EPR spectra of 3 and 4 in THF indicate localization of unpaired spin density on one of the two Mn metal centers. The EPR of 4 in CH₂Cl₂ indicates delocalization of unpaired spin density over both Mn metal centers. The unsymmetrical isomer, 1, is a strong one-electron photoreductant. The excited state redox potential of 1, E° (3/1*), has been approximated to be −1.35 ⩽E° (3/1*)⩽−1.87 V vs. SCE. Under the same experimental conditions the symmetrical isomer 2 exhibits no photochemical redox behavior.     

Immobilization of glucoamylase on DEAE-cellulose activated with chloride compounds

Partially purified glucoamylase (1,4-α-d-glucan glucohydrolase, EC 3.2.1.3) from Aspergillus niger NRRL 330 has been immobilized on DEAE-cellulose activated with cyanuric chloride in 0.2 m acetate buffer, pH 4.2. In the matrix-bound glucoamylase, enzyme yield was 20 mg g^?1 of support, corresponding to 40 200 units g^?1 of DEAE support. Binding of the enzyme narrows the pH optimum from 3.8–5.2 to 3.6. Thermal stability of the bound glucoamylase enzyme was decreased although it showed a higher temperature optimum (70°C) than the free form (55°C). The rate of reaction of glucoamylase was also changed after immobilization. V_max values for free and bound enzyme were 36.6 and 22.6 μmol d-glucose ml^?1 min^?1 and corresponding K_m values were 3.73 and 4.8 g l^?1 respectively. Free and immobilized enzyme when used in the saccharification process gave 84 and 56% conversion of starch to d-glucose, respectively. The bound enzyme was quite stable and in the batch process it was able to operate for about five cycles without any loss of activity.     

Oligosaccharides from “standardized intermediates”. The 2-amino-2-deoxy- d-galactose analog of the blood-group O(H) determinant,type 2, and its precursors

The selectively benzylated glycoside allyl 2-acetamido-4,6-di-O-benzyl-2-deoxy-β- d-galactopyranoside ( 4) was prepared from the corresponding derivative of 2-acetamido-2-deoxy- d-glucose via the p-bromobenzenesulfonate and the benzoate. 2-O-Benzoyl-3,4,6-tri-O-benzyl-α- d-galactopyranosyl chloride ( 10) was obtained from allyl 6-O-benzyl-2-O-(2-butenyl)-α- d-galactopyranoside via known intermediates. To complete the sequence, the 1-propenyl 3,4,6-tri-O-benzyl galactoside was successively converted into the 2-benzoate, the free sugar, and the chloride 10. A fully protected form ( 11) of the trisaccharide α- l-Fucp-(1→2)-β- d-Galp-(1→4)- d-GalNAc was then synthesized by coupling 10 to 4, partially deblocking the disaccharide product, and l-fucosylating the resulting intermediate. Cleavage of the O-benzyl groups from 11, with concomitant saturation of the allyl group, gave the propyl β-glycoside of the unsubstituted trisaccharide.     

Addition of hydrazoic acid to methyl 6-O-benzoyl-2,3-dideoxy-α-D-glycero-hex-2-enopyranosid-4-ulose

The title compound 4 reacted with hydrazoic acid to give exclusively an adduct having the threo configuration, whose structure was established by reduction to the lyxo derivatives 8 and 10. The reaction of 4 with hydrogen peroxide afforded the epoxide 12, the lyxo structure of which was deduced by conversion into the alcohol 13. Tributylborane also reacted with the enone 4, giving the adduct 15, whose configuration was tentatively assigned to be threo.     

Action of 5-thio-D-glucose and its 1-phosphate with hexokinase and phosphoglucomutase.

Previous work from this laboratory has shown that 5-thio-d-glucose is a competitive inhibitor for active transport of d-glucose. The present work indicates that the thiosugar analog and its 1-phosphate can also interfere with d-glucose 6-P formation.5-Thio-d-glucose serves as a substrate for yeast hexokinase with a K_m of 4 mm, and V of 8.8 nmol/min/μg of protein. The analog competitively inhibits d-glucose phosphorylation with a K_i of 20 mm.5-Thio-d-glucose 1-P can act as a substrate for rabbit skeletal muscle phosphoglucomutase with a K_m of 60 μm and V of 0.17 μmol/min/μg of protein. Thus, 5-thio-d-glucose 1-P behaves as a near metabolic analog of d-glucose 1-P. 5-Thio-d-glucose 1-P is a competitive inhibitor of d-glucose 1-P conversion to the 6-P with a K_i of 16.2 μm.5-Thio-d-glucose 6-P produced by phosphorylation of 5-thio-d-glucose and by conversion from 5-thio-d-glucose 1-P was identified by chromatographic mobility and by color reactions.     

Derivatives of phosphonate and vinyl phosphate analogs of D-ribose 5-phosphate

Propanal thiosemicarbazone (1a) showed activity in preventing anaphylactic shock in a mouse test-system; it also had some activity in stunting the growth of Botrytis allii. Hexanal thiosemicarbazone (1b) was active in the Botrytis allii test-system, and citral thiosemicarbazone (2) and citral guanylhydrazone nitrate (3) showed some activity in the same test-system. Heptanal guanylhydrazone nitrate (4) had some antibacterial activity against Staphylococcus aureus, and D-threo-pentosulose bis(thiosemicarbazone) (5) prevented anaphylactic shock in the mouse test-system. D-glycero-Tetrosulose bis(thiosemicarbazone) (6), D-lyxo-hexosulose bis-(guanylhydrazone) nitrate (7), D-galacto-heptosulose bis(thiosemicarbazone) (8), and D-galacto-heptosulose bis(guanylhydrazone) sulfate (9) showed some activity in stunting the growth of Botrytis allii. The copper chelate (10a) of D-arabino-hexosulose bis(thiosemicarbazone), and the copper (11a) and palladium (11b) chelates of 6-deoxy-L-arabino-hexosulose bis(thiosemicarbazone) showed antitumor activity in the KB cell-culture test-system. The palladium chelate 11b also showed some activity in the leukemia p-388 mouse test-system.