Stereoselectivity of the Enzymatic Reduction of Aldehydic and Ketonic Carbonyl Groups in Planar Chiral Organomanganese Complexes

(±)-Tricarbonyl(η⁵-1-formyl-2-methylcyclopentadienyl)manganese (1) was optically resolved with horse liver alcohol dehydrogenase (HLADH) and two species of yeasts, Saccharomyces sp. H-1 and Rhodotorula rubra IFO 889. Usually, (1R)-1 was preferentially reduced to give (?)-alcohol 2 of ≥ 97% e.e. ? 84% e.e. Ketone analogue (±)-tricarbonyl(η⁵-1-acetyl-2-methylcyclopentadienyl)-manganese (4) was reduced by the yeasts. The major product by S. sp. H-1 was the (1S,2R,1′S)-(+)-alcohol (5) (≥ 98% e.e.) and the minor product, the (1R,2S,1′S)-(?)-alcohol (6) (86% e.e.). R. rubra gave only the latter alcohol (≥ 99 % e.e.). The Stereodifferentiation mechanism for these bioreductions is discussed in terms of the Prelog rule. The mechanism for HLADH reduction was examined with computer graphics.     

Microbiological Synthesis of Adenine Arabinoside

The microbiological synthesis of 9-βd-arabinofuranosyl adenine (ara-A, an antiviral drug) from adenine and arabinofuranosyluracil (ara-U) is described. Various bacteria, especially Enterobacter aerogenes, Escherichia coli, Erwinia herbicola and Aeromonas salmonicida, were found to be able to transfer the arabinofuranosyl moiety of ara-U to adenine (transarabinosylation) in the presence of inorganic phosphate. The optimum conditions for the transarabinosylation were pH 7.0 and 60°C. No reaction was observed in the absence of inorganic phosphate and its optimum concentration was around 30 mM. Six grams of ara-A was produced in liter of reaction mixture in the presence of wet cell paste of Enterobacter aerogenes AJ 11125. Ara-A formed was precipitated in the reaction mixture and isolated with an 87% yield. Physicochemical data for the compound agreed with those of authentic ara-A.     

On the Fermenting Ability of Sand Cultures of Acetone-Butanol Organisms Stored for Long Years

β-N-Acetyl-D-hexosaminidase was isolated from the mid-gut gland of Patinopecten yessoensis. The enzyme was purifted by making an acetone-dried preparation of the mid-gut gland, extracting with 50 mM citrate-phosphate buffer (pH 4.0) (about 13% of the extracted proteins was β-N-acetyl-D-hexosaminidase), ammonium sulfate fractionation, and column chromatographies on CM-Sepharose and DEAE-Sepharose. The purifted β-N-acetyl-D-hexosaminidase was homogeneous on SDS–PAGE, and sufficiently free from other exo-type glycosidases. The molecular weight was 56,000 by SDS–PAGE. The enzyme hydrolyzed both p-nitrophenyl β-N-acetyl-D-glucosaminide and p-nitrophenyl β-N-acetyl-D-galactosaminide. For p-nitrophenyl β-N-acetyl-D-glucosaminide, the pH optimum was 3.7, the optimum temperature was 45°C, and the K_m was 0.24 mM. For p-nitrophenyl β-N-acetyl-D-galactosaminide, these were pH 3.4, 45°C, and 0.15 mM, respectively. The enzyme liberated non-reducing terminal β-Iinked N-acetyl-D-glucosamine or N-acetyl-D-galactosamine from various 2-aminopyridyl derivatives of oligosaccharides of N-glycan or glycolipid type except of G_M2-tetrasaccharide. As the enzyme was stable around pH 3.5–5.5, it may be useful for long time reactions around the optimum pH.     

Hyperoxia reverses glucotoxicity-induced inhibition of insulin secretion in rat INS-1 β cells

Chronic hyperglycemia has deleterious effects on pancreatic β-cell function, a process known as glucotoxicity. This study examined whether chronic high glucose (CHG) induces cellular hypoxia in rat INS-1 β cells, and whether hyperoxia (35% O₂) can reverse glucotoxicity-induced inhibition of insulin secretion. CHG (33.3?mm, 96?h) reduced insulin secretion, and down-regulated insulin and pancreatic duodenal homeobox factor 1 gene expression. CHG also increased intracellular pimonidazole-protein adducts, a marker for hypoxia. CHG also enhanced hypoxia-inducible factor 1α (HIF-1α) protein expression and its DNA-binding activity, which was accompanied by a decrease in mRNA expression of glucose transporter 2 (GLUT2), glucokinase and uncoupling protein-2 and an increase in mRNA expression of GLUT1 and pyruvate dehydrogenase kinase 1. Hyperoxia restored the decrease in insulin secretion and the gene expression except for GLUT2, and suppressed intracellular hypoxia and HIF-1α activation. These results suggest that glucotoxicity may cause β-cell hypoxia. Hyperoxia might prevent glucotoxicity-induced β-cell dysfunction and improve insulin secretion.     

Crystallization and Reconstitution of Yeast Aconitase

The combination of flow injection analysis and the electrochemical method was investigated for measuring the organic acid content of citrus fruits. The controlled-potential four-electrode method was used for conductance measurements. The instrumentation of the measuring apparatus used in this study is defined. The optimum conditions of the flow system were as follows: injection volume 35 μ1, mixing coil length 100 cm, flow rate 20ml/min and dilution ratio of samples 1:130. A linear correlation between the peak conductivity and the organic acid content was obtained with high correlation coefficient (r=0.992). It is possible to analyze about 50 samples within an hour using the method, and the coefficient of variation with any given juice for 20 assays was less than 0.5%.     

The Co-immobilization of NAD and Dehydrogenases and Its Application to Bioreactors for Synthesis and Analysis

A polymerizable NAD derivative, N⁶-[N-[N-(2-hydroxy-3-methacrylamidopropyl)carbamoylmethyl]carbamoylmethyl]-NAD, formate dehydrogenase, and malate dehydrogenase were entrapped all together in polyacrylamide gels. The entrapment was carried out by radical copolymerization, and consequently NAD was bound on the matrix which enclosed the enzymes. These gels had the function of producing l-malate from oxalacetate and formate. The l-malate production was also continuously done in a column reactor for 3 days. Another gel was similarly prepared with N⁶-[N-(6-methacrylamidohexyl)carbamoylmethyl]-NAD, horse liver alcohol dehydrogenase, and diaphorase. This gel was shown to catalyze the formation of resorufin from resazurin and ethanol. This gel was applicable to ethanol analysis using a fluorescence spectrophotometer to determine resorufin. The analyzer was usable for one week.     

A Convenient Synthesis of 4-Hydroxy-3-methyl-2-(2-propynyl)-cyclopent-2-enone,an Alcohol Moiety of a Synthetic Pyrethroid Having Strong Killing and Knockdown Activity

We examined the primary structure of the α-amylase produced by Bacillus subtilis var. amylosacchariticus by attempting to isolate tryptic peptides of the enzyme. By solubilization and precipitation in buffers, the peptides were first fractionated into three. The main fraction was fractionated by ion-exchange chromatography. Twenty-seven peptides were generated from this fraction. The fraction insoluble at neutral pH was fractionated by SP-Sephadex C-25. From this fraction three peptides were obtained. The other fraction insoluble at acidic pH was fractionated by Bio-Gel P-60. Four peptides were isolated from this fraction. In total, thirty-four peptides were generated from the tryptic digest of the α-amylase. The amino acid sequences of twenty-one out of thirty-four peptides were completely determined, while those of the other thirteen peptides were partially determined. The peptides derived from the N- and C-terminal ends of the α-amylase were identified.     

The human bitter taste receptor hTAS2R39 is the primary receptor for the bitterness of theaflavins

We purified several hundred mgs of four major theaflavins (theaflavin, theaflavin-3-O-gallate, theaflavin-3′-O-gallate, and theaflavin-3,3′-O-digallate). Among the 25 hTAS2Rs expressed in HEK293T cells, hTAS2R39 and hTAS2R14 were activated by theaflavins. Both hTAS2R39 and hTAS2R14 responded to theaflavin-3′-O-gallate. In addition, hTAS2R39 was activated by theaflavin and theaflavin-3,3′-O-gallate, but not by theaflavin-3-O-gallate. In contrast, hTAS2R14 responded to theaflavin-3-O-gallate.     

Limb-specific differences in the skin vascular responsiveness to adrenergic agonists

In this study, to test the hypothesis that adrenergic vasoconstrictor responses of the legs are greater compared with the arms in human skin, cutaneous vascular conductance (CVC) in the forearm and calf were compared during the infusion of adrenergic agonists in healthy young volunteers. Under normothermic conditions, norepinephrine (NE, α- and β-agonist, 1 × 10(-8) to 1 × 10(-2) M), phenylephrine (PHE, α(1)-agonist, 1 × 10(-8) to 1 × 10(-2) M), dexmedetomidine (DEX, α(2)-agonist, 1 × 10(-9) to 1 × 10(-4) M), and isoproterenol (ISO, β-agonist, 1 × 10(-8) to 1 × 10(-3) M) were administered by intradermal microdialysis. Skin blood flow (SkBF) was measured by laser-Doppler flowmetry, and the local temperature at SkBF-measuring sites was maintained at 34°C throughout the experiments. CVC was calculated as the ratio of SkBF to blood pressure and expressed relative to the baseline value before drug infusion. The dose of NE at the onset of vasoconstriction and the effective dose (ED(50)) resulting in 50% of the maximal vasoconstrictor response for NE were lower (P < 0.001) in the calf than forearm. The ED(50) for PHE and DEX was also lower (P < 0.05) in the calf than forearm. Increases in CVC in response to ISO were potentially smaller in the calf, but the statistical differences in the responses were dependent on the expressions of CVC. These findings suggest that the cutaneous vasoconstrictor responsiveness to exogenous NE is greater in the legs than in the arms due to a higher α(1)- and α(2)-adrenoceptor reactivity, while the β-adrenoceptor function plays a minor role in regional differences in adrenergic vasoconstriction in normothermic humans.