EC:1.1.1.1 - FACTA Search

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Query: EC:1.1.1.1 (alcohol dehydrogenase)
9,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The antifungal antibiotic flavensomycin inhibited the oxidation of amino acids and of glucose by Penicillium oxalicum. The compound inhibited l-amino acid oxidase (EC 1.4.3.2) activity for l-leucine and l-phenylalanine, and also d-amino acid oxidase (EC 1.4.3.3) in the oxidation for dl-alanine. The addition of flavin adenine dinucleotide, which is a cofactor for this enzyme, antagonized the action of the antibiotic. Glucose oxidase (EC 1.1.3.4) was also inhibited. The antibiotic inhibited the reduced nicotinamide adenine dinucleotide (NADH(2)) cytochrome c reductase (EC 1.6.2.1) as well as the much slower nonenzymatic reduction of this cytochrome by the nucleotide. Reduced cytochrome c was also oxidized nonenzymatically by flavensomycin. The antibiotic completely inhibited the action of rabbit muscle lactic dehydrogenase (EC 1.1.1.27) in promoting the reduction of pyruvate by NADH(2) but only slightly affected the reverse reaction. Alcohol dehydrogenase (EC 1.1.1.1) was also similarly inhibited. Flavensomycin prevented the reduction of nicotinamide adenine dinucleotide phosphate by isocitrate in the presence of isocitrate dehydrogenase (EC 1.1.1.42). The hexokinase (EC 2.7.1.1)-catalyzed phosphorylation of glucose, in which the adenosine triphosphate acts as a phosphate donor, was only slightly affected. Flavensomycin also inhibited the action of yeast lactate dehydrogenase (EC 1.1.2.3) on the reduction of cytochrome c. High concentrations of cytochrome c were antagonistic to this reaction. The results point to an interference with enzymatically controlled hydrogen or electron transfer as the mechanism of the antifungal activity of flavensomycin.
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PMID:Flavensomycin, an inhibitor of enzyme reactions involving hydrogen transfer. 438 33

The enzyme activities involved in fructose metabolism were measured in samples of human liver. On the basis of U/g of wet-weight the following results were found: ketohexokinase, 1.23; aldolase (substrate, fructose-1-phosphate), 2.08; aldolase (substrate, fructose-1,6-diphosphate), 3.46; triokinase, 2.07; aldehyde dehydrogenase (substrate, D-glyceraldehyde), 1.04; D-glycerate kinase, 0.13; alcohol dehydrogenase (nicotinamide adenine dinucleotide [NAD]) substrate, D-glyceraldehyde), 3.1; alcohol dehydrogenase (nicotinamide adenine dinucleotide phosphate [NADP]) (substrate, D-glyceraldehyde), 3.6; and glycerol kinase, 0.62. Sorbitol dehydrogenases (25.0 U/g), hexosediphosphatase (4.06 U/g), hexokinase (0.23 U/g), and glucokinase (0.08 U/g) were also measured. Comparing these results with those of the rat liver it becomes clear that the activities of alcohol dehydrogenases (NAD and NADP) in rat liver are higher than those in human liver, and that the values of ketohexokinase, sorbitol dehydrogenases, and hexosediphosphatase in human liver are lower than those values found in rat liver. Human liver contains only traces of glycerate kinase. The rate of fructose uptake from the blood, as described by other investigators, can be based on the activity of ketohexokinase reported in the present paper. In human liver, ketohexokinase is present in a four-fold activity of glucokinase and hexokinase. This result may explain the well-known fact that fructose is metabolized faster than glucose.
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PMID:Enzymes of fructose metabolism in human liver. 438 49

Reduced nicotinamide adenine dinucleotide phosphate (NADPH)-aldehyde reductase was isolated in 24% yield and 66-fold purification from a dl-glyceraldehyde-grown Rhodotorula species. This enzyme was specific for NADPH, and d-, l-, or dl-glyceraldehyde were equally good substrates. Other substrates had activities as follows: methylglyoxal, 50%; fructose, 33%; d- and l-arabinose, 12%; d-xylose, 8%; d-glucose, 5%; d-erythrose and d-threose, 0 to 5%. The product from the reduction of dl-glyceraldehyde was glycerol, as shown by high voltage electrophoresis, paper chromatography, and direct enzymatic analysis. Kinetic studies gave K(m) values of 0.89 mm and 0.013 mm for dl-glyceraldehyde and NADPH, respectively. An optimal pH range of 6.3 to 6.7 was found for maximal activity. Reduction of NADP(+) by glycerol was not demonstrable. This Rhodotorula NADPH-aldehyde reductase activity was compared to similar enzymes from other sources.
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PMID:Identification of reduced nicotinamide adenine dinucleotide phosphate-dependent aldehyde reductase in a Rhodotorula strain. 439 May 2

S organism ferments ethanol to acetate and H(2) but grows poorly on ethanol unless the partial pressure of H(2) is kept low, as when it is grown in combination with an H(2)-utilizing methanogenic bacterium. The present study shows that S organism contains an alcohol dehydrogenase and a formate dehydrogenase, both of which require nicotinamide adenine dinucleotide (NAD) for activity. Hydrogen is evolved from NADH generated by these activities via a ferredoxin-dependent oxidation of NADH to NAD and H(2). NADH:NADP oxido-reductase activity was also demonstrated. The relationship of these activities to the growth of S organism is discussed.
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PMID:Ferredoxin- and nicotinamide adenine dinucleotide-dependent H 2 production from ethanol and formate in extracts of S organism isolated from "Methanobacillus omelianskii". 440 99

The pathways of carbohydrate metabolism in Spirochaeta stenostrepta, a free-living, strictly anaerobic spirochete, were studied. The organism fermented glucose to ethyl alcohol, acetate, lactate, CO(2), and H(2). Assays of enzymatic activities in cell extracts, and determinations of radioactivity distribution in products formed from (14)C-labeled glucose indicated that S. stenostrepta degraded glucose via the Embden-Meyerhof pathway. The spirochete utilized a clostridial-type clastic reaction to metabolize pyruvate to acetyl-coenzyme A, CO(2), and H(2), without production of formate. Acetyl-coenzyme A was converted to ethyl alcohol by nicotinamide adenine dinucleotide-dependent acetaldehyde and alcohol dehydrogenase activities. Phosphotransacetylase and acetate kinase catalyzed the formation of acetate from acetyl-coenzyme A. Hydrogenase and lactate dehydrogenase activities were detected in cell extracts. A rubredoxin was isolated from cell extracts of S. stenostrepta. Preparations of this rubredoxin stimulated acetyl phosphate formation from pyruvate by diethylaminoethyl cellulose-treated extracts of S. stenostrepta, an indication that rubredoxin may participate in pyruvate cleavage by this spirochete. Nutritional studies showed that S. stenostrepta fermented a variety of carbohydrates, but did not ferment amino acids or other organic acids. An unidentified growth factor present in yeast extract was required by the organism. Exogenous supplements of biotin, riboflavin, and vitamin B(12) were either stimulatory or required for growth.
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PMID:Carbohydrate metabolism in Spirochaeta stenostrepta. 542 71

Methylococcus capsulatus grows only on methane or methanol as its sole source of carbon and energy. Some amino acids serve as nitrogen sources and are converted to keto acids which accumulate in the culture medium. Cell suspensions oxidize methane, methanol, formaldehyde, and formate to carbon dioxide. Other primary alcohols are oxidized only to the corresponding aldehydes. Oxidation of formate by cell suspensions is more sensitive to inhibition by cyanide than is the oxidation of other one carbon compounds. This is due to the cyanide sensitivity of a soluble nicotinamide adenine dinucleotide-specific formate dehydrogenase. Oxidation of formaldehyde and methanol is catalyzed by a nonspecific primary alcohol dehydrogenase which is activated by ammonium ions and is independent of pyridine nucleotides. Some comparisons are made with a strain of Pseudomonas methanica.
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PMID:Physiological studies of methane and methanol-oxidizing bacteria: oxidation of C-1 compounds by Methylococcus capsulatus. 556 68

1. The purified alcohol dehydrogenase of Pseudomonas sp. M27, whose action is independent of nicotinamide nucleotides, has absorption peaks at 280mmu and at 350mmu with little or no absorption at or above 450mmu. 2. It does not fluoresce, but green-fluorescent material, diffusible on dialysis, is produced when the enzyme is treated with acid or alkali or when it is boiled. 3. Evidence is presented that the enzyme is not a flavoprotein. 4. Kinetic studies show a correlation between enzyme inactivation by acid, alkali or heat and liberation of the fluorescent material. 5. Some purification of the fluorescent material was achieved, but definite identification was not possible; the major component has a fluorescence maximum at about 460mmu with excitation maxima at about 260mmu and 365mmu. 6. Data are given (including absorption and fluorescence spectra) that support the suggestion that the prosthetic group of the enzyme is a pteridine derivative. 7. Possible mechanisms of action of the enzyme are discussed.
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PMID:The microbial oxidation of methanol. The prosthetic group of the alcohol dehydrogenase of Pseudomonas sp. M27: a new oxidoreductase prosthetic group. 604 34

1. A method for the purification of the nicotinamide nucleotide-independent alcohol dehydrogenase of Pseudomonas sp. M27 is described. 2. In the analytical ultracentrifuge, the purified enzyme shows a single major component of molecular weight 146000. 3. On electrophoresis in polyacrylamide gels between pH5.0 and 9.55, it shows only one protein band and the isoelectric point appears to be between pH7.0 and 8.0. 4. Spectrographic analysis indicates no significant metal content. 5. Amino acid analysis shows an unusually small number of cysteine/cystine residues per molecule as well as about 4.1% of glucosamine. 6. The role of ammonia as enzyme activator has been investigated.
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PMID:The microbial oxidation of methanol. Purification and properties of the alcohol dehydrogenase of Pseudomonas sp. M27. 605 12

Experiments on 220 albino rats showed that lithium carbonate, chloride and nicotinate had different capacities to suppress ethanol dependence induced by a three-month administration of alcohol, with lithium nicotinate showing the greatest activity. The efficacy of the drugs correlated with the normalization of the activity of alcohol dehydrogenase, catalase and the levels of nicotinamide coenzymes and lipid peroxides in the brain, liver and kidneys. The drug administration was attended by an increased EEG synchronization, expanded range of perceived frequencies and enhanced synchronization energy. The above changes occurred with all lithium salts, being, however, most prominent with lithium nicotinate.
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PMID:[Comparative evaluation of the suppressive effects of lithium preparations in the treatment of experimental chronic habituation to alcohol]. 608 85

The binding of NAD to liver alcohol dehydrogenase has been studied in four different ternary complexes by using crystallographic methods. These complexes crystallize isomorphously in a triclinic crystal form which contains the whole dimer of the enzyme in the asymmetric unit. This form of the enzyme has been refined at 2.9-A resolution to a crystallographic R factor of 0.22. NAD binds in essentially the same way in these complexes. The binding site is located at the central part of the coenzyme binding domain. The adenine ring binds with hydrophobic interactions between two isoleucine side chains. Both ribose rings have 2E(C2'-endo) puckering, and each ribose makes three hydrogen bonds to the enzyme. The pyrophosphate bridge has hydrogen bonds to the side chains of arginine-47 and -369 and to main chain nitrogen atoms from the amino ends of two alpha-helices. The nicotinamide ring is in van der Waals contact with the active-site zinc atom and with the sulfur atoms of its cysteine ligands. The carboxamide group is about 30 degrees out of the plane of the nicotinamide ring and hydrogen bonds to main chain atoms of residues 292,317, and 319. The overall conformation of the NAD molecule is similar to that observed for other dehydrogenases, but differs in details. In the presence of the coenzyme, the enzyme undergoes a large conformational change from an open to a closed form. This conformational change has three major effects: to create favorable binding interactions with groups of the enzyme, to enclose the coenzyme and gain binding energy for the coenzyme by reducing the accessible surface area, and to close off one entrance to the active site. As a comparison, ADP-ribose binding has been studied in the open form of the enzyme. The adenosine moiety binds in a similar way as NAD, while the rest of the molecule has different interactions.
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PMID:Crystallographic investigations of nicotinamide adenine dinucleotide binding to horse liver alcohol dehydrogenase. 609 6

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