Studies of the selective silylation of methyl α- and β-d-aldohexopyranosides: stability of the partially protected derivatives in polar solvents

Treatment of methyl α- (1) and β-d-glucopyranoside, methyl α- (3) and β-d-galactopyranosides, and methyl α-d-mannopyranoside (5) with 2, 3, or 4 mol. equiv. of tert-butyldimethylsilyl (TBDMS) chloride under two conditions afforded mixtures of TBDMS ethers which were identified. The following compounds were isolated in synthetically useful yields, the 2,6-di-TBDMS either of 1 (70%), the 2,6-di- and 2,3,6-tri-TBDMS ethers of 3 (84% and 57%, respectively), and the 2,6-di-and 3,6-di-TBDMS ethers of 5 (50% and 80%, respectively). In dipolar solvents, no migration of the TBDMS groups was detected between partially silylated hydroxyl groups, but the addition of a base (triethylamine or imidazole) caused migration to vicinal cis positions.     

α-D-galactosidase-catalysed synthesis of partially protected α-linked digalactopyranosides

Summary The facile synthesis of partially protected -linked digalactopyranosides was achieved employing -D-galactosidase as stereospecific catalyst and partially protected -galactopyranosides as acceptors. The influence of changing the structure and the number of protecting groups on yield and regioselectivity is described. The preparative synthesis of the structure Galp 1-3 (2-O–Bn) Galp -OMe, which is useful e.g. for the preparation of blood group determinant B and analogs, was achieved.     

Bromine oxidation of methyl α- and β-pyranosides of D-galactose,D-glucose,and D-mannose

Methyl α- and β-pyranosides of D-galactose, D-glucose, and D-mannose have been oxidized with bromine in aqueous solution at various pH values. The resulting keto glycosides were converted into their more-stable O-methyloxime derivatives which were characterized by spectroscopy and chromatography. Oxidation at a ring carbon atom where the hydrogen is axial is hindered by bulky substituents in syn (i.e., a 1,3) diaxial relationship. Thus, the aglycon group in the α anomers protects position 3, the axial HO-4 in galactopyranosides protects position 2, and the axial HO-2 in mannopyranosides protects position 4 from oxidation.     

Combined inhibiting action of new salicylic acid derivatives and α-tocopherol on oxidation of methyl oleate

The inhibitory effects of compositions of α-tocopherol (α-TP) and salicylic acid derivatives on the process of initiated oxidation of methyl oleate have been investigated. α-TP and the salicylic acid derivatives exhibited the synergistic effect, which was demonstrated by the methods of UV-spectroscopy and high-performance liquid chromatography (HPLC). Kinetics of α-TP utilization during methyl oleate oxidation was investigated under conditions of its independent use as well as using its binary mixture with the synthetic antioxidants.     

Mechanism of the cyanide-catalyzed oxidation of α-ketoaldehydes and α-ketoalcohols

Cyanide catalyzes the reduction of dioxygen or of ferricytochrome c by dihydroxyacetone phosphate. The rapid initial phase of these reactions, but not the subsequent slow phase, was augmented by incubating the triose phosphate aerobically or anaerobically at pH 9.0 prior to adding the cyanide. The aerobic incubation, which was most effective, was associated with a decline in enediol, whereas the less effective anaerobic incubation was accompanied by an increase in enediol content. This suggested that the α-ketoaldehyde product of autoxidation of the enediol, rather than the enediol itself, was responsible for the rapid phase reaction which followed addition of cyanide. This was confirmed by exploring the cyanide-catalyzed oxidation of the α-ketoaldehyde, phenylglyoxal. The inhibitory effect of the manganese-containing superoxide dismutase indicated that O₂⁻ was a kinetically important intermediate of the rapid phase reaction. A reaction mechanism is proposed which is consistent with the results presented.     

Carbasugar analogues of galactofuranosides: β-O-linked derivatives and towards β-S-linked derivatives

A selectively protected carbasugar analogue of β-galactofuranose was synthesised from glucose using ring-closing metathesis as the key step. The carbasugar was converted into an α-galacto configured 1,2-epoxide, which was an effective electrophile in Lewis acid catalysed coupling reactions with alcohols. The epoxide was opened with regioselective attack at C-1 to give β-galacto configured C-1 ethers. Using carbohydrates as nucleophiles, we synthesised a number of pseudodisaccharides. The epoxide was also regioselectively opened at C-1 with a sulfur nucleophile under basic conditions to give a β-galacto configured C-1 thioether.     

Synthesis and anti-inflammatory evaluations of β-lapachone derivatives

β-Lapachone (β-LAPA), a natural product from the lapacho tree in South America, is a potential chemotherapeutic agent that exhibit a wide variety of pharmacological effects such as anti-virus, anti-parasitic, anti-cancer, and anti-inflammatory activities. In order to discover novel anti-inflammatory agents, we have synthesized a series of β-LAPA derivatives for evaluation. Among them, 4-(4-methoxyphenoxy)naphthalene-1,2-dione (6b) was found to be able to inhibit NO and TNF-α released in LPS-induced Raw 264.7 cells. Inhibition of iNOS and COX-2 was also observed in compound 6b treated cells. Mechanism studies indicated that 6b exhibited anti-inflammatory properties by suppressing the release of pro-inflammatory factors through down-regulating NF-κB activation. In addition, it suppressed NF-κB translocation by inhibiting the phosphorylation of p38 kinase. Our results also indicate that the inhibitory effect of 6b on LPS-stimulated inflammatory mediator production in Raw 264.7 cell is associated with the suppression of the NF-κB and MAPK signaling pathways. A low cytotoxicity (IC₅₀ = 31.70 μM) and the potent anti-inflammatory activity exhibited by compound 6b make this compound a potential lead for developing new anti-inflammatory agents. Further structural optimization of compound 6b is on-going.     

Crystal structure of trisodium β-d-fructofuranose 1,6-diphosphate octahydrate

Trisodium β-d-fructose 1,6-diphosphate octahydrate crystallises in the monoclinic space group P2₁ with unit-cell dimensions a = 13.289(2), b = 11.643(3), c = 7.092(1) Å, and β = 102.32(2)°. The unit cell contains two symmetry-related molecules. The structure has been determined by direct methods, and refined to an R value of 0.035 and an R_w value of 0.049. The puckering of the furanose ring is C-3-exo, corresponding to an E₃ conformation slightly distorted towards ⁴T₃. The sodium atoms are hexaco-ordinated. The crystal packing involves alternating charged layers and a network of hydrogen bonds which links the molecules belonging to the same layer and to adjacent layers.     

Action of xylan deacetylating enzymes on monoacetyl derivatives of 4-nitrophenyl glycosides of β-D-xylopyranose and α-L-arabinofuranose

Measurements of esterase activity by enzyme-coupled assays on monoacetates of 4-nitrophenyl β-d-xylopyranoside and 4-nitrophenyl α-l-arabinofuranoside showed that acetylxylan esterases of families 1, 4 and 5 produced by Trichoderma reesei and Penicillium purpurogenum have a strong preference for deacetylation of position 2 in xylopyranosides. The acetylxylan esterases exhibit only weak activity on acetylated arabinofuranosides, with 2-acetate as the best substrate. Acetyl esterases of family 16 produced by the same two fungi deacetylate in xylopyranosides preferentially positions 3 and 4. Their specific activity on arabinofuranosides is also much lower than on xylopyranosides, however, substantially greater than that in the case of typical acetylxylan esterases.     

Synthesis and electrochemical behaviour of β-halodehydroamino acid derivatives

Several new β,β-dihalo and β-halo-β-substituted dehydroalanines and dehydrodipeptides were synthesized by reacting the corresponding dehydroamino acid derivative with a N-halosuccinimide or in the case of β,β-di-iododehydroalanines with iodine. The results obtained confirmed that the stereochemical outcome of the halogenation reaction with β-substituted dehydroamino acids depends on the substrate. Thus, an increase Z-stereoselectivity was found when the β-phenyldehydroalanines were used as substrates and when these compounds were N-protected with 4-tolylsulfonyl or with carbamates. From this study, it is also possible to conclude that when N-iodosuccinimide was used as reagent a much higher Z-stereoselectivity is found. The electrochemical behaviour of the halogenated dehydroamino acids was studied by cyclic voltammetry. The results show a shift in the reduction peak to higher potentials of the β-halogenated dehydroamino acids when compared with the corresponding non-halogenated derivatives. As expected, the β,β-dihalodehydroalanines exhibit higher peak potentials than β-halo-β-substituted dehydroalanines and the bromo derivatives have lower peak potentials when compared with the corresponding iododehydroamino acids. Controlled potential electrolysis of several β-halo-β-substituted dehydroamino acids afforded the corresponding dehalogenated dehydroamino acids as mixtures of their E and Z-isomers. In all cases, the major isomer isolated results from dehalogenation without isomerization. These new results show that electrochemical reduction constitutes a valuable method for the synthesis of the E-isomer of β-substituted dehydroalanines.     

Synthesis of methyl α- and β-maltotriosides and aryl β-maltotriosides

Reaction of β-maltotriose hendecaacetate with phosphorus pentachloride gave 2′,2″,3,3′,3″,4″,6,6′,6″,-nona-O-acetyl-(2)-O-trichloroacetyl-β-maltotriosyl chloride (2) which was isomerized into the corresponding α anomer (8). Selective ammonolysis of 2 and 8 afforded the 2-hydroxy derivatives 3 and 9, respectively; 3 was isomerized into the α anomer 9. Methanolysis of 2 and 3 in the presence of pyridine and silver nitrate and subsequent deacetylation gave methyl α-maltotrioside. Likewise, methanolysis and O-deacetylation of 9 gave methyl β-maltotrioside which was identical with the compound prepared by the Koenigs—Knorr reaction of 2,2′,2″,3,3′,3″,4″,6,6′,6″-deca-O-acetyl-α-maltotriosyl bromide (12) with methanol followed by O-deacetylation. Several substituted phenyl β-glycosides of maltotriose were also obtained by condensation of phenols with 12 in an alkaline medium. Alkaline degradation of the o-chlorophenyl β-glycoside decaacetate readily gave a high yield of 1,6-anhydro-β-maltotriose.     

Synthesis of disaccharide derivatives employing β-N-acetyl- d-hexosaminidase, β-d-galactosidase and β-d-glucuronidase

-N-Acetyl-d-hexosaminidase from Aspergillus oryzae catalysed the stereo- and regiospecific formation of the 6-O-benzylated disaccharide derivatives GalNAc1-3(6- OBn)Gal-SEt and GlcNAc1-3(6-OBn)Gal-SEt, which were obtained in transglycosylation reactions employing ethyl 6- O-benzyl-1-thio--d-galactopyranoside as acceptor. Preparative amounts of the chitobiose derivative GlcNAc1- 3GlcNAc-OPhNO2-p was prepared as well. - N-Acetyl-d-hexosaminidase from bovine testes catalysed the specific synthesis of GlcNAc1-3(6-OBn)GlcNH2-SEt and GalNAc1-3(6-OBn)GlcNH2-SEt, employing ethyl 2-amino-6-O-benzyl-2-deoxy-1-thio--d-glucopyranoside as acceptor. -d-Glucuronidase from E. coli was found to catalyse the formation of GlcA1-3(6-OBn)GlcNH2- SEt employing the same acceptor.     

A practical synthesis of N α -Fmoc protected l-threo-β-hydroxyaspartic acid derivatives for coupling via α- or β-carboxylic group

Abstract  

A simple and practical general synthetic protocol towards orthogonally protected tHyAsp derivatives fully compatible with Fmoc solid-phase peptide synthetic methodology is reported. Our approach includes enantioresolution of commercially available d,l-tHyAsp racemic mixture by co-crystallization with l-Lys, followed by ion exchange chromatography yielding enantiomerically pure l-tHyAsp and d-tHyAsp, and their selective orthogonal protection. In this way N ^α -Fmoc protected tHyAsp derivatives were prepared ready for couplings via either α- or β-carboxylic group onto the resins or the growing peptide chain. In addition, coupling of tHyAsp via β-carboxylic group onto amino resins allows preparation of peptides containing tHyAsn sequences, further increasing the synthetic utility of prepared tHyAsp derivatives.     

Microbial Oxidation of α-Methylstyrene and β-Methylstyrene

An unidentified bacterial strain S107B1, isolated from soil by use of isopropylbenzene as a carbon source, was shown to bring about oxidation of α-methylstyrene and β-methylstyrene,

One of the oxidation products produced from α-methylstyrene was identified as the new compound, (—)-cis-23-dihydroxy-1-isopropenyl-6-cyclohexene.

The same strain S107B1 also oxidized β-methylstyrene and produced 3-phenylpropionaldehyde and benzoic acid.

From these results, the existence of reductive step for the aerobic degradation of these aromatic hydrocarbons by this strain was made clear. The initial attack on these aromatic hydrocarbons and a cyclohexenediol compound formed from α-methylstyrene were discussed.     

Synthesis of derivatives of methyl β-sophoroside

Selective tritylation of methyl β-sophoroside (1) and subsequent acetylation gave the 3,4,2′,3′,4′-penta-O-acetyl-6,6′-di-O-trityl derivative, which was O-detritylated, and the product p-toluenesulfonylated, to give methyl 3,4,2′,3′,4′-penta-O-acetyl-6,6′-di-O-p-tolylsulfonyl-β-sophoroside (4) in 63% net yield. Compound 4 was also obtained in 69% yield by p-toluenesulfonylation of 1, followed by acetylation. Several, 6,6′-disubstituted derivatives of 1 were synthesized by displacement reactions of 4 with various nucleophiles. Treatment of 4 with sodium methoxide afforded methyl 3,6:3′,6′-dianhydro-β-sophoroside. Several 6- and 6′-monosubstituted derivatives of 1 were prepared, starting from the 4,6-O-benzylidene derivative of 1.     

Synthesis and structural study of a fully protected α-C-galactosyl model dipeptide

The synthesis of three N-alkyl-6,7-dideoxy-1,2:3,4-di-O-isopropylidene-7-[(alkyl-carbonyl)amino]-L-glycero--D-galacto-octopyranuronamides6a–c, analogous model dipeptides containing two amide groups connected to the -carbon bearing the fully protected galactose as a side chain, has been realized with the aim of determining the conformational influence of the galactosyl moiety on the peptide backbone. Molecular modeling of 6a, X-ray crystallography of 6c, and IR and NMR experiments on 6a–c in organic solvents show that the carbohydrate ring assumes a twist boat conformation. In non-polar organic solvents, the NH of the left amide group interacts with one ketal oxygen of the galactosyl group.     

Synthesis and structural study of a fully protected α-C-galactosyl model dipeptide

Summary The synthesis of three N-alkyl-6,7-dideoxy-1,2:3,4-di-O-isopropylidene-7-[(alkyl-carbonyl)amino]-L-glycero-α-D-galacto-octopyranuronamides6a-c, analogous model dipeptides containing two amide groups connected to the α-carbon bearing the fully protected galactose as a side chain, has been realized with the aim of determining the conformational influence of the galactosyl moiety on the peptide backbone. Molecular modeing of6a, X-ray crystallography of6c and IR and NMR experiments on6a-c in organic solvents show that the carbohydrate ring assumes a twist boat conformation. In non-polar organic solvents, the NH of the left amide group interacts with one ketal oxygen of the galactosyl group.     

Synthesis and hydrogenolysis of the methylene,ethylidene, isopropylidene,and diastereoisomeric 1-phenylethylidene acetals of β-l-arabino- and α-l-rhamnopyranoside derivatives

Both diastereoisomers of 1-phenylethylidene acetals (acetophenone acetals) of methyl and benzyl β-l-arabinopyranoside and α-l-rhamnopyranoside were prepared. Acetal-exchange reactions gave only the endo-phenyl isomers; their 2-O- and 4-O-acetyl derivatives were isomerised into the exo-phenyl compounds. ¹H-N.m.r. data were used to determine the absolute configuration at the acetal carbon atom in these compounds. The protons of the methyl group of the exo-phenyl isomers resonate at lower field than those of the endo-phenyl isomers. Hydrogenolysis of various methylene, ethylidene, and isopropylidene derivatives gave axial ethers. The endo-phenyl isomers of the acetophenone derivatives also gave axial 1-phenylethyl ethers in two diastereoisomeric forms. The exo-phenyl isomers of the arabinosides were stable towards the reagent (LiAlH₄AlCl₃), whereas the corresponding rhamnopyranosides gave the 2-(1-phenylethyl) ethers, but cleavage required prolonged reaction time and higher temperature.     

Oxidation and formation of oxidation products of β-carotene at boiling temperature

β-Carotene is one of the most important lipid component extensively used in food industries as source of pro-vitamin A and colorant. During processing and storage β-carotene is oxidized and degraded to various oxidation compounds. Some of these compounds are also the key aroma compounds in certain flowers, vegetables and fruits. The methods for analysis and determination of these oxidized products formed during food boiling or preparation are key to the understanding the chemistry of these compounds. This paper presents a novel analytical method incorporating high performance liquid chromatography with diode array and mass spectrometric detection for the characterization of oxidation, isomerization and oxidation products of β-carotene in toluene at boiling temperature. HPLC and APCI-MS was optimized using oxidized sample and flow injection analysis of the standard β-carotene respectively. β-Carotene was oxidized in the Rancimat at 110°C for 30, 60 and 90 min. The oxidized samples were than analyzed by HPLC system at 450 nm and 350 nm as well as scanning and single ion monitoring mass spectrometry. A total of ten oxidation products and three Z-isomers were reported. Extensive isomerization was observed during treatment at the control accelerated conditions. The oxidation products include five apo-carotenals, three diepoxides, one mono-epoxide and one short chain species. Results show that the method was reproducible, accurate and reliable for the separation and identification of oxidation products of β-carotene.