The final structure of robinin and biorobin and their total synthesis

Robinin has been proved by total synthesis and by methylation analysis using GC-MS to be kaempferol-3- O-(6-O-α-l-rhamnopyranosyl -β-d-galactopyranoside)-7-O-α-l-rhamnopyranoside and not, as claimed by Maksjutina et al., a mixture of 4 glycosides containing the 7-O-rhamnosyl moiety in the α- and β-furanoside as well as in the α- and β-pyranoside forms. The assumption that the 3-O-rhamnosido -galactose moiety contained furanoid rings was also disproved.     

Immunochemical studies on two polysaccharides extracted from Salmonella johannesburg 5.58 wild strain and Salmonella johannesburg 5.58 transformed by phage phi 1 (40)

Methyl β-D-galacto-hexodialdo-1,5-pyranoside (2), produced by the action of D-galactose oxidase on methyl β-D-galactopyranoside, has been characterized in a dimeric form. Structural examination of the peracetate of this dimer by p.m.r. spectroscopy and by analysis of its mass-spectral fragmentation-patterns showed that 2 behaves as a β-hydroxy aldehyde, engaging in unsymmetrical dimerization via the 4 and 6 positions; this involves creation of a 1,3-dioxane ring as a bridge between the two units of the dimer. Aldehyde 2 also undergoes ready α,β-elimination.     

Oxidation of methyl α-d-galactopyranoside by galactose oxidase: products formed and optimization of reaction conditions for production of aldehyde

The reaction conditions of galactose oxidase-catalyzed, targeted C-6 oxidation of galactose derivatives were optimized for aldehyde production and to minimize the formation of secondary products. Galactose oxidase, produced in transgenic Pichia pastoris carrying the galactose oxidase gene from Fusarium spp., was used as catalyst, methyl α-d-galactopyranoside as substrate, and reaction medium, temperature, concentration, and combinations of galactose oxidase, catalase, and horseradish peroxidase were used as variables. The reactions were followed by ¹H NMR spectroscopy and the main products isolated, characterized, and identified. An optimal combination of all the three enzymes gave aldehyde (methyl α-d-galacto-hexodialdo-1,5-pyranoside) in approximately 90% yield with a substrate concentration of 70 mM in water at 4 °C using air as oxygen source. Oxygen flushing of the reaction mixture was not necessary. The aldehyde existed as a hydrate in water. The main secondary products, a uronic acid (methyl α-d-galactopyranosiduronic acid) and an α,β-unsaturated aldehyde (methyl 4-deoxy-α-d-threo-hex-4-enodialdo-1,5-pyranoside), were observed for the first time to form in parallel. Formation of uronic acid seemed to be the result of impurities in the galactose oxidase preparation. ¹H and ¹³C NMR data of the products are reported for the α,β-unsaturated aldehyde for the first time, and chemical shifts in DMSO-d₆ for all the products for the first time. Oxidation of d-raffinose (α-d-galactopyranosyl-(1-6)-α-d-glucopyranosyl-(1-2)-β-d-fructofuranoside) in the same optimum conditions also proceeded well, resulting in approximately 90% yield of the corresponding aldehyde.     

Facile synthesis of 1,2-trans-O-acetyl glycosyl chloride derivatives of cellobiose,lactose, and D-glucose

Solutions of O-acetyl-α-glycosyl bromide derivatives of d-glucose, cellobiose, and lactose in hexamethylphosphoramide were converted into corresponding β-chlorides at room temperature by the action of lithium chloride. At 3:1 mM ratios of chloride ion to glycose, 5–10% w/v solutions of glycosyl bromide formed α- and β-chlorides in ratios of (or greater than) 1:19 within 2–13 min and produced crystalline β-chlorides in 70–80% yields. Anomeric compositions were determined by n.m.r. spectroscopy in hexamethylphosphoramide. Older methods of preparing 1,2-trans-O-acetylgIycosyl chlorides, with aluminum chloride or titanium tetrachloride, gave the α- and β-cellobiosyl and -Iactosyl chlorides in ratios that varied from 2:3 to 1:4 and reached 85–95% levels of β-chloride only with β-d-glucose pentaacetate. When hydrolyzed under conditions that controlled solution acidity, the β-cellobiosyl and -Iactosyl chlorides each gave 2-hydroxy derivatives in yields that could be varied from 16 to 60%. Hepta-O-acetyl-2-O-methyl-α-cellobiose was prepared to demonstrate how these hydrolysis mixtures can be used to synthesize a 2-O-substituted derivative.     

Catalytic versatility of trehalase: Synthesis of α-d-glucopyranosyl α-d-xylopyranoside from β-d-glucosyl fluoride and α-d-xylose

Trehalase was previously shown (see ref. 5) to hydrolyze α-d-glucosyl fluoride, forming β-d-glucose, and to synthesize α,α-trehalose from β-d-glucosyl fluoride plus α-d-glucose. Present observations further define the enzyme's separate cosubstrate requirements in utilizing these nonglycosidic substrates. α-d-Glucopyranose and α-d-xylopyranose were found to be uniquely effective in enabling Trichoderma reesei trehalase to catalyze reactions with β-d-glucosyl fluoride. As little as 0.2mm added α-d-glucose (0.4mm α-d-xylose) substantially increased the rate of enzymically catalyzed release of fluoride from 25mm β-d-glucosyl fluoride at 0°. Digest of β-d-glucosyl fluoride plus α-d-xylose yielded the α,α-trehalose analog, α-d-glucopyranosyl α-d-xylopyranoside, as a transient (i.e., subsequently hydrolyzed) transfer-product. The need for an aldopyranose acceptor having an axial 1-OH group when β-d-glucosyl fluoride is the donor, and for water when α-d-glucosyl fluoride is the substrate, indicates that the catalytic groups of trehalose have the flexibility to catalyze different stereochemical reactions.     

Synthesis of guanine nucleosides by fusion,and a mechanistic aspect of the reaction

N²-Acetylguanine (1) was condensed by fusion with the fully acetylated derivatives of the following sugars: β-D-ribofuranose (2), β-D-ribopyranose (3), α-D-xylopyranose (4), β-D-xylopyranose (5), α-D-glucopyranose (6), and β-D-gluco-pyranose (7). The reaction of 1 with either 2 or 3 gave a mixture of 7-β, 9-α, and 9-β isomers, whereas only the 7-β and 9-β isomers, and virtually no 9-α isomer, were obtained when 4, 5, 6, and 7 were used. When each isomeric acetylated ribofuranosylguanine was heated in the presence of an acidic catalyst, a mixture of 7-β, 9-α, and 9-β nucleosides was formed. Close examination of the product ratios showed that the ratio of 7:9 isomers remained unchanged throughout the reactions, but the anomeric nature of the 9-substituted nucleoside was dependent on the sugar used.     

Reaction of acetyl hypofluorite with pyranoid and furanoid glycals

The regiospecific syn-addition of acetyl hypofluorite to glycals derived from pentopyranoses led to mixtures of stereoisomers. Stereospecific reactions occurred with furanoid glycals, the direction of addition being governed by the nature of the substituent at C-3. Whereas a benzyloxy group caused attack from the opposite, less-hindered face of the double bond, a hydroxyl group induced addition from the same side. From these reactions, 2-deoxy-2-fluoro derivatives of β-d-arabino-, α-d-ribo-, β-d-lyxo-, and α-d-xylo-pyranose as well as β-d-manno-, α-d-gluco-, α-d-ribo-, and β-d-arabino-furanose were obtainedl their ¹H-, ¹³C-, and ¹⁹F-n.m.r. data are given.     

Regional heterogeneity in the ratio of α-MSH:β-endorphin in rat brain

The molar ratio of α-MSH:β-endorphin varies markedly among discrete microdissected regions of rat brain ranging from 0.57 in the median eminence to 2.74 in the lateral septum. This finding demonstrates that α-MSH and β-endorphin (β-END) are not uniformly distributed in a 1:1 molar ratio in rat brain as one might predict based on the consideration that the two peptides are synthesized in equimolar amounts as part of a common precursor molecule, pro-opiomelanocortin. The data indicate instead that the concentrations of α-MSH and β-END, the two predominant peptides expressed by opiomelantropinergic neurons, are independently regulated in rat brain. The heterogeneity of α-MSH:β-END ratios suggests that the regulation of α-MSH and β-END is regionally specific and may impart functional selectivity to the multisecretory opiomelanotropinergic neuronal system.     

The nitrous acid deamination of glycosides and acetates of 2-amino-2-deoxy-D-glucose

A procedure is described for the nitrous acid deamination of 2-amino-2-deoxy-D-glucose hydrochloride (1), and reduction of the product with buffered borohydride, to afford crystalline 2,5-anhydro-D-mannitol (3) in 71% yield. Similar treatment of the methyl α-pyranoside (4) of 1 gives 59% of crystalline 3, and the same product is obtained in 44% yield from 1,3,4,6-tetra-O-acetyl-2-amino-2-deoxy-α(or β)-D-glucopyranose hydrochloride (5 or 6) by the deamination-reduction sequence with subsequent deacetylation. These results provide a model, for a nonhydrolytic, depolymerization technique for structural characterization of glycosaminoglycans.     

Differential effects induced by α- and β-endosulfan in lipid bilayer organization are reflected in proton permeability

The effects of two insecticides isomers, α- and β-endosulfan, on the passive proton permeability of large unilamellar vesicles (LUV) reconstituted with dipalmitoylphosphatidylcholine (DPPC) or mitochondrial lipids were reported. In DPPC (LUV) gel phase, at 30 °C, the global kinetic constant (K) of proton permeability (proportional to the proton permeability) initially increased slightly with the increase of α-endosulfan/lipid molar ratio up to 0.143. In the range from 0.143 to 0.286, a discontinuity in the increment occurred and, above this range, the proton permeability increased substantially. In DPPC fluid phase, at 48 °C, the proton permeability showed a behavior identical to that observed in gel DPPC, with a sharp increase for α-endosulfan/lipid molar ratios ranging from 0.143 to 0.286. At these and higher concentrations, α-endosulfan induced phase separation in the plane of DPPC membranes, as revealed by differential scanning calorimetry (DSC). Conversely to α-endosulfan, β-endosulfan induced only a slight increase in the proton permeability, either in the fluid or the gel phase of DPPC, for all β-endosulfan/lipid molar ratios tested. Additionally, the effects of the endosulfan isomers on the proton permeability of mitochondrial fluid lipid dispersions, at 37 °C, are similar to those described for DPPC. The β-isomer induced a very small effect, and α-endosulfan, at low concentrations, increased slightly the proton permeability, but for insecticide/lipid molar ratios above 0.143 the permeability increased substantially. Consequently, the membrane physical state of synthetic and native lipid dispersions, as affected by the structural features of α- and β-endosulfan, influenced the proton permeability. The effects here observed in vitro suggest that the formation of lateral membrane domains may underlay the biological activity of α-endosulfan in vivo, contributing to its higher degree of toxicity as compared with β-endosulfan.     

A complex polysaccharide from the seeds of anthocephalus indicus a. rich

The seeds of Anthocephalus indicus contain a water-soluble polysaccharide composed of D-xylose, D-mannose, and D-glucose in the molar ratios 1:3:5. Methylation analysis afforded 2,3,4-tri-O-methyl-D-xylose, 2,3,6,-tri-O-methyl-D-mannose, 2,3,6-tri-O-methyl-D-glucose, 2,3-di-O-methyl-D-glucose, and 2,3,4,6-tetra-O-methyl-D-glucose in the molar ratios 7:21:12:15:8. Periodate oxidation and methylation data indicated 22.5% and 21.9% of end groups, respectively. The above findings, together with the results of partial hydrolysis with acid, indicate the polysaccharide to consist of a linear chain of (1→4)-linked β-D-mannosyl and β-D-glucosyl residues to which α-D-xylosyl and β-D-glucosyl groups are attached by (1→6)-linkages.     

N,N-Diacetylsialyl chloride—a novel readily accessible sialyl donor in reactions with neutral and charged nucleophiles in the absence of a promoter

N,N-Diacetylneuraminic acid glycosyl chloride was prepared for the first time and made to react with various nucleophiles to give the corresponding α-glycosyl phosphate, β-glycosyl dibenzyl phosphate, α-glycosyl azide, α-phenyl thioglycoside and α-glycosyl xanthate in 65-82% yields and high stereoselectivity while its reactions with simple alcohols were not stereoselective. The new sialyl donor made possible the first stereoselective synthesis of sialic acid glycosyl phosphate with α-configuration and highly efficient synthesis of β-configured sialic acid glycosyl dibenzyl phosphate.     

Selectivity in vitamin B-6 model reactions: Selective α or β deuteration of amino acids under transamination or racemization conditions

Al(III)-catalyzed reactions of vitamin B-6 (pyridoxal)-amino acid schiff bases have been studied in ²H₂O. By using excess of the amino acid and varying conditions, amino acids selectively deuterated in the α-position, the β-position, or in both α- and β-positions are isolated. Reaction conditions are those of model systems in which amino acids are known to be reversibly transaminated and racemized by pyridoxal and Al(III). The racemization reaction leads to α-deuteration of the amino acid while transamination followed by its reverse leads to both α- and β-deuteration. The two reactions are viewed as passing through a common dihydropyridine intermediate. The Al(III) serves as an interesting model for the enzyme in that it not only catalyzes transamination and racemization but also can be made to select which of these reactions predominates. This selective catalysis of these reactions is attributed to strong and different pH dependence of the reactivity of various sites of the dihydropyridine intermediate for vitamin B-6 catalysis when incorporated in an Al(III) complex. The biochemical importance of this selectivity and the practical extension of the method of deuteration to other amino acids is discussed.     

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.     

急性粒细胞白血病珠蛋白基因表达失衡的研究

应用竞争性逆转录聚合酶链式反应（ＲＴ－ＰＣＲ）测定了１０例急性粒细胞白血病Ｍ＿２型（ＡＭＬ）患者外周血网织红细胞中α／β珠蛋白ｍＲＮＡ的相对含量,其中８例表现不同程度增高,２例正常,均值为１．５１３±０．１８２（±ｓ）,与正常对照组（１．２４±０．０８３）进行ｔ检验比较,有非常显著差异（Ｐ＜０．０１）．此外,ＰＣＲ－ＳＳＣＰ分析显示ＡＭＬ患者β珠蛋白基因启动子区序列（５＇端－１３５至＋１２２位核苷酸）无明显异常。说明ＡＭＬ患者珠蛋白基因表达失衡系由于转录异常,很可能系ＡＭＬ的发生对α／β珠蛋白基因的平衡表达产生了某种影响,从而表现为获得性β地中海贫血特征。实验结果为进一步探讨白血病的发病机理及其α／β珠蛋白基因表达失衡的机制奠定了基础。     

Synthesis of C-(d-glycopyranosyl)ethylamines and C-(d-glycofuranosyl)methylamines as potential glycosidase inhibitors

The C-glucosyl aldehyde, 2-C-(2,3,4,6-tetra-O-acetyl-α-d-glucopyranosyl)ethanal was prepared from the C-glucopyranosyl propene precursor by ozonolysis. Reductive amination of the C-glucosyl aldehyde and subsequent deprotection gave 1-anilino-2-C-(α-d-glucopyranosyl)ethane. The E and Z isomers of the oxime derivative, 1-C-(α-d-arabinofuranosyl)methanal oxime were prepared by treating their aldehyde precursor with hydroxylamine. Acetylation of the oxime, followed by catalytic hydrogenation and deprotection, gave the corresponding 1-C-(α-d-arabinofuranosyl)methylamine. Reductive amination of ethyl 2,3-O-isopropylidene-α-d-lyxo-pentodialdo-1,4-furanoside using aniline gave ethyl 5-anilino-5-deoxy-d-lyxo-furanoside. Inhibition studies with these compounds on β-d-glucosidase from sweet almond, using o-nitrophenyl d-glucopyranoside as substrate, were carried out.     

Accumulation of α- and β-globin messenger RNAs in mouse erythroleukemia cells

The accumulation of α- and β-globin mRNA sequences in murine erythroleukemia cells (MELC) treated with various inducers has been studied using specific α- and β-globin complementary DNAs (cDNAs). In cells cultured with dimethylsulfoxide (Me₂SO), hexamethylene bisacetamide (HMBA) or butyric acid, accumulation of α-globin mRNA is detectable after 16, 12 and 8 hr of culture, respectively. An increase in β-globin mRNA sequences is not detected until 20–24 hr after culture. In cells exposed to hemin, both α- and β-globin mRNAs are detectable by 6 hr of culture, and a constant ratio of $\text{α}\text{β}\text{-}\text{mRNA}$ is maintained during induction. In maximally induced cells, the $\text{α}\text{β}\text{-}\text{globin}$ mRNA ratios are approximately 1 in cells induced by Me₂SO and HMBA, and 0.66 and 0.3–0.50 in cells induced by butyric acid and hemin, respectively. Thus different inducers of erythroid differentiation in MELC lead to different times of onset of the expression of α- and β-like genes. In addition, the relative accumulation of α- and β-globin mRNAs in induced cells differs with various types of inducers.     

Synthesis of α- and β-d-glucopyranosyl triazoles by CuAAC ‘click chemistry’: reactant tolerance, reaction rate, product structure and glucosidase inhibitory properties

Cu^I-catalysed azide alkyne 1,3-dipolar cycloaddition (CuAAC) ‘click chemistry’ was used to assemble a library of 21 α-d- and β-d-glucopyranosyl triazoles, which were assessed as potential glycosidase inhibitors. In the course of this work, different reactivities of isomeric α- and β-glucopyranosyl azides under CuAAC conditions were noted. This difference was further investigated using competition reactions and rationalised on the basis of X-ray crystallographic data, which revealed significant differences in bond lengths within the azido groups of the α- and β-anomers. Structural studies also revealed a preference for perpendicular orientation of the sugar and triazole rings in both the α- and β-glucosyl triazoles in the solid state. The triazole library was assayed for inhibition of sweet almond β-glucosidase (GH1) and yeast α-glucosidase (GH13), which led to the identification of a set of glucosidase inhibitors effective in the 100 μM range. The preference for inhibition of one enzyme over the other proved to be dependent on the anomeric configuration of the inhibitor, as expected.     

The methanolysis of some derivatives of 2,3,4-tri-O-benzyl-α-D-glucopyranosyl bromide in the presence and absence of silver salts

In contrast to reactions with high concentration, reactions of several derivatives of 2,3,4-tri-0-benzyl-α-D-glucopyranosyl bromide with low concentrations of methanol gave mainly the α-D-glucosides regardless of the structure of the C-6 substituent. Methanolysis of the same α-D-glucosyl bromides or the corresponding chlorides in the presence of silver tetrafluoroborate or hexafluorophosphate at —78° gave mainly the β-D-glucosides. The use of these silver salts led to side reactions, particularly when the glucosyl halide had an acyl blocking group at C-6. The side reactions were minimized when silver trifluoromethanesulfonate (triflate) was used. The relative amounts of α- and β-D-glucosides produced in the presence of silver triflate depended on the structure of the C-6 substituent and the solvent polarity. A rapid methanolysis of 2,3,4-tri-0-benzyl-6-0-(N-phenylcarbamoyl)-α-D-glucopyranosyl bromide with silver triflate in ether at —78° gave a high proportion of the methyl α-D-glucoside.The results of direct methanolysis seem to be due to competitive methanolysis of the anomeric bromides and a p?ush-pull$\text{\$}\text{?}$mechanism is postulated in the presence of silver tetrafluoroborate or hexafluorophosphate. Glucosyl triflate intermediates are proposed for the silver triflate-assisted methanolyses.     

Identification and application of threonine aldolase for synthesis of valuable α-amino, β-hydroxy-building blocks

Chiral β-hydroxy α-amino acid structural motifs are interesting and common synthons present in multiple APIs and drug candidates. To access these chiral building blocks either multistep chemical syntheses are required or the application of threonine aldolases, which catalyze aldol reactions between an aldehyde and glycine. Bioinformatics tools have been utilized to identify the gene encoding threonine aldolase from Vanrija humicola and subsequent preparation of its recombinant version from E. coli fermentation. We planned to implement this enzyme as a key step to access the synthesis of our target API. Beyond this specific application, the aldolase was purified, characterized and the substrate scope of this enzyme further investigated. A number of enzymatic reactions were scaled-up and the products recovered to assess the diastereoselectivity and scalability of this asymmetric synthetic approach towards β-hydroxy α-amino acid chiral building blocks.