EC:1.1.1.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

1. The fatty acid synthesis in isolated liver cells from fed rats was studied with tritiated water as the radioactive precursor. The cells incorporated 3H20 at a rate of 1.26 mumol per min per g packed cells. 2. Addition of ethanol caused a 20% decrease in the incorporation of tritium into fatty acids. The decrease was correlated to the increase in the NAD-redox level. Probably, the decreased tritium incorporation into fatty acids during ethanol metabolism is due to a decrease in the specific activity of the NADPH used for the synthesis of fatty acids, rather than to a real inhibition of the fatty acid synthesis. 3. Ethanol oxidation via NADPH-consuming pathways and ethanol per se at a concentration of 80 mM had no effect upon the incorporation of tritium into fatty acids. 4. Fructose in a concentration of 15 mM inhibited the fatty acid synthesis by 75%, and this inhibition was further augmented by ethanol. 5. The ioslated rat liver cells oxidized ethanol at a rate of 2.72, 2.93 and 3.48 mumol per min per g packed cells at 5, 20 and 80 mM ethanol, respectively. Fructose had no effect upon ethanol oxidation neither at low nor at high concentrations of ethanol. 6. Ethanol oxidation via the non alcohol dehydrogenase pathway(s) may involve a transfer of reducing equivalents from mitochondrial NADH to cyctosolic NADP+ as judged from measurements of metabolite levels. This conclusion is supported by determinations of 14C yield in glucose from [1-14C] ethanol, and the results are taken as evidence for the presence of hydrogen shuttle activity during metabolism of ethanol, catalyzed by the NAD-dependent alcohol dehydrogenase. A metabolic scheme is proposed to account for the observed changes at low and high concentrations of ethanol.
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PMID:Ethanol metabolism and lipid synthesis by isolated liver cells from fed rats. 126 14

The purpose of this work was to compare the roles of a newly described mitochondrial dehydrogenase and catalase in ethanol elimination in deer mice deficient in alcohol dehydrogenase (ADH-). Fructose was used because of its well-known ability to stimulate dehydrogenase-dependent ethanol metabolism. Rates of ethanol metabolism in vivo were decreased significantly by about 60% in a dose-dependent manner by fructose in deer mice fed an ethanol-containing or a corn oil control diet. In addition, rates of metabolism of methanol, a selective substrate for catalase in rodents, were similar to rates of ethanol elimination and were decreased from 6.9 +/- 1.0 to 1.7 +/- 0.5 mmol/kg/h by fructose, supporting the hypothesis that catalase and not a mitochondrial dehydrogenase predominates in ethanol oxidation in ADH-deer mice. Glycolate, a substrate for peroxisomal H2O2 generation, reversed the inhibition of alcohol metabolism by fructose completely, indicating that fructose did not inhibit catalase directly. As expected, the ATP/ADP ratio was decreased by fructose significantly from 4.2 +/- 0.4 to 2.4 +/- 0.4 in deer mouse livers. These data are consistent with the hypothesis that fructose decreases catalase-dependent ethanol metabolism in vivo by inhibiting hepatic H2O2 generation.
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PMID:Inhibition of ethanol metabolism by fructose in alcohol dehydrogenase-deficient deer mice in vivo. 189 39

This study examined metabolic interactions between two nutrients--ethanol and carbohydrate. Both nutrients are metabolized by a common pathway to fatty acids from acetyl-coenzyme A by lipogenic enzymes. The effects of ethanol and carbohydrate on the induction of lipogenic enzymes in livers of rats were examined using two types of base diets differing in carbohydrate and lipid content and using isocaloric substitutions of ethanol, carbohydrate, and fat. Three nonlipogenic enzymes were used for comparison. Isocaloric substitution of both fat and carbohydrate for ethanol was necessary to show the specific effects of alcohol on the activity of lipogenic or nonlipogenic enzymes. Carbohydrate, and not ethanol, induced lipogenic enzymes. Ethanol specifically reduced the activity of lactate dehydrogenase and malic enzyme, but did not affect those of alcohol dehydrogenase or glycerol 3-phosphate dehydrogenase. Ethanol interacted with carbohydrate to increase the activity of ATP citrate lyase. In addition, we studied the effects of ethanol and different kinds of carbohydrates on the growth of rats and on the morphology of their livers and intestines. Ethanol significantly decreased growth characteristics (weight gain, growth rate, and caloric efficiency). Fructose, either as a monosaccharide or in sucrose, decreased this alcohol effect. Sucrose was better than glucose in lowering lipid accumulation in livers of rats. Fragility of intestinal villi was found with an alcohol, low carbohydrate diet, but was not present in alcohol diets with a higher level of carbohydrate. In contrast to carbohydrate, ethanol lacked some characteristics of a nutrient, namely, it did not induce some enzymes involved in its metabolism and did not promote optimum growth.
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PMID:Alcohol as a nutrient: interactions between ethanol and carbohydrate. 217 66

The kinetic deuterium isotope effect, D(V/K), on ethanol oxidation was measured on hepatocytes from rat and pig by the radiometric competitive method using 14C-labelled ethanol containing deuterium in the (1-R)-position. The corrected D(V/K) values of 2.68 and 2.80 for rat and pig hepatocytes respectively were significantly different, suggesting differences in the amount of non-ADH ethanol oxidizing activity. The apparent isotope effects declined rapidly with time when acetaldehyde was present in the medium as a result of the reduction to ethanol of the [14C]-acetaldehyde formed from the double labelled ethanol by alcohol dehydrogenase (ADH). Fructose and cyanamide caused the acetaldehyde concentration during ethanol oxidation to increase by entirely different mechanisms, and the isotope effect to decrease with time, as did also the addition of acetaldehyde. The apparent first order rate constant for the reverse ADH reaction, assuming the reactants to be acetaldehyde and the ADH-NADH complex, was determined by two methods giving comparable results. In the presence of semicarbazide, which removes acetaldehyde, the isotope effect was nearly constant. This was the case also when the acetaldehyde concentration was very low (less than 1 microM) for other reasons, as in hepatocytes from starved animals. A mathematical formula describing the expected decrease of the apparent isotope effect with time was derived. The different response of pig and rat hepatocytes to addition of fructose (the 'fructose effect') is suggested to be caused by differences in activity of aldehyde dehydrogenases in the two species.
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PMID:Deuterium D(V/K) isotope effects on ethanol oxidation in hepatocytes: importance of the reverse ADH-reaction. 237 Dec 31

Some enzymatic activities of the glycolytic and hexose monophosphate pathways of Candida parapsilosis, a yeast lacking alcohol dehydrogenase but able to grow on high glucose concentrations, were compared to those of Saccharomyces cerevisiae. Cells were grown either on 8% glucose or on 2% glycerol and activities measured under optimal conditions. Results were as follows: glycolytic enzymes of C. parapsilosis, except glyceraldehyde 3-phosphate dehydrogenase, exhibited an activity weaker than that of S. cerevisiae, especially when yeasts were grown on glycerol. Fructose-1,6 bisphosphatase, an enzyme implicated in gluconeogenesis and in the hexose monophosphate pathway, and known to be very sensitive to catabolite repression in S. cerevisiae, was always active in C. parapsilosis even when cells were grown on 8% glucose. However, the allosteric properties towards AMP and fructose-2,6-bisphosphate were the same in both strains. Glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase, two other enzymes of the hexose monophosphate pathway, exhibited a higher activity in C. parapsilosis than in S. cerevisiae. Regulation of two important control points of the glycolytic flux, phosphofructokinase and pyruvate kinase, was investigated. In C. parapsilosis phosphofructokinase was poorly sensitive to ATP but fructose-2,6-bisphosphate completely relieved the light ATP inhibition. Pyruvate kinase did not require fructose-1,6-bisphosphate for its activity, and by this way, did not regulate the glycolytic flux.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Comparative studies on the glycolytic and hexose monophosphate pathways in Candida parapsilosis and Saccharomyces cerevisiae. 283 96

D-Fructose and D-glucose activate alcohol dehydrogenase from horse liver to oxidize ethanol. One mol of D-[U-14C]fructose or D-[U-14C]glucose is covalently incorporated per mol of the maximally activated enzyme. Amino acid and N-terminal analyses of the 14C-labelled glycopeptide isolated from a proteolytic digest of the [14C]glycosylated enzyme implicate lysine-315 as the site of the glycosylation. 13C-n.m.r.-spectroscopic studies indicate that D-[13C]glucose is covalently linked in N-glucosidic and Amadori-rearranged structures in the [13C]glucosylated alcohol dehydrogenase. Experimental results are consistent with the formation of the N-glycosylic linkage between glycose and lysine-315 of liver alcohol dehydrogenase in the initial step that results in an enhanced catalytic efficiency to oxidize ethanol.
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PMID:Activation of liver alcohol dehydrogenase by glycosylation. 634 12

2-Chloroacetaldehyde (CAA)-induced cytotoxicity in isolated hepatocytes was enhanced markedly if hepatocyte alcohol or aldehyde dehydrogenase was inhibited prior to CAA addition. Hepatocyte GSH depletion, ATP depletion and lipid peroxidation by CAA were also enhanced markedly. Furthermore, CAA was about 10- and 70-fold more cytotoxic than its oxidative or reductive metabolite chloroacetate or chloroethanol, respectively. Nutrients such as lactate, xylitol, sorbitol or glycerol, which increase cytosolic NADH levels, prevented CAA cytotoxicity in normal hepatocytes but further enhanced cytotoxicity toward alcohol dehydrogenase inactivated hepatocytes, suggesting that increased cytosolic NADH reduces CAA via alcohol dehydrogenase in normal hepatocytes but prevents CAA oxidation in alcohol dehydrogenase inactivated hepatocytes. However, increasing cytosolic NADH levels with ethanol or NADH-generating nutrients after CAA had been metabolized also prevented cytotoxicity and caused a partial ATP recovery, whereas oxidation of cytosolic NADH with pyruvate markedly increased cytotoxicity. This indicates that cytotoxic CAA concentrations cause oxidative stress and that ATP levels can be restored if cellular redox homeostasis is normalized with reductants. Furthermore, except for fructose, nutrients that did not increase NADH did not affect CAA-induced cytotoxicity. Fructose also caused a partial ATP recovery, and its protection was prevented by the glycolytic inhibitor fluoride. Hepatocytes isolated from fasted animals were 4- to 6-fold more susceptible to CAA-induced ATP depletion and cytotoxicity. No lipid peroxidation occurred at these lower CAA concentrations. Furthermore, all nutrients, including alanine, glutamine and glucose, prevented cytotoxicity toward hepatocytes isolated from fasted animals. The susceptibility of hepatocytes to CAA cytotoxicity, therefore, depends on both cellular redox homeostasis and cellular energy supply.
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PMID:Chloroacetaldehyde-induced hepatocyte cytotoxicity. Mechanisms for cytoprotection. 809 90

Several quinoproteins have been newly indicated in acetic acid bacteria, all of which can be applied to fermentative or enzymatic production of useful materials by means of oxidative fermentation. (1) D-Arabitol dehydrogenase from Gluconobacter suboxydans IFO 3257 was purified from the bacterial membrane and found to be a versatile enzyme for oxidation of various substrates to the corresponding oxidation products. It is worthy of notice that the enzyme catalyzes D-gluconate oxidation to 5-keto-D-gluconate, whereas 2-keto-D-gluconate is produced by a flavoprotein D-gluconate dehydrogenase. (2) Membrane-bound cyclic alcohol dehydrogenase was solubilized and purified for the first time from Gluconobacter frateurii CHM 9. When compared with the cytosolic NAD-dependent cyclic alcohol dehydrogenase crystallized from the same strain, the reaction rate in cyclic alcohol oxidation by the membrane enzyme was 100 times stronger than the cytosolic NAD-dependent enzyme. The NAD-dependent enzyme makes no contribution to cyclic alcohol oxidation but contributes to the reduction of cyclic ketones to cyclic alcohols. (3) Meso-erythritol dehydrogenase has been purified from the membrane fraction of G. frateurii CHM 43. The typical properties of quinoproteins were indicated in many respects with the enzyme. It was found that the enzyme, growing cells and also the resting cells of the organism are very effective in producing L-erythrulose. Dihydroxyacetone can be replaced by L-erythrulose for cosmetics for those who are sensitive to dihydroxyacetone. (4) Two different membrane-bound D-sorbitol dehydrogenases were indicated in acetic acid bacteria. One enzyme contributing to L-sorbose production has been identified to be a quinoprotein, while another FAD-containing D-sorbitol dehydrogenase catalyzes D-sorbitol oxidation to D-fructose. D-Fructose production by the oxidative fermentation would be possible by the latter enzyme and it is superior to the well-established D-glucose isomerase, because the oxidative fermentation catalyzes irreversible one-way oxidation of D-sorbitol to D-fructose without any reaction equilibrium, unlike D-glucose isomerase. (5) Quinate dehydrogenase was found in several Gluconobacter strains and other aerobic bacteria like Pseudomonas and Acinetobacter strains. It has become possible to produce dehydroquinate, dehydroshikimate, and shikimate by oxidative fermentation. Quinate dehydrogenase was readily solubilized from the membrane fraction by alkylglucoside in the presence of 0.1 M KCl. A simple purification by hydrophobic chromatography gave a highly purified quinate dehydrogenase that was monodispersed and showed sufficient purity. When quinate dehydrogenase purification was done with Acinetobacter calcoaceticus AC3, which is unable to synthesize PQQ, purified inactive apo-quinate dehydrogenase appeared to be a dimer and it was converted to the monomeric active holo-quinate dehydrogenase by the addition of PQQ.
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PMID:New quinoproteins in oxidative fermentation. 1268 1

Based on recently reported data that fructose ingestion is linked to arterial hypertension, a model of regulatory loops involving the colon role in maintenance of fluid and sodium homeostasis is proposed.In normal digestion of hyperosmolar fluids, also in cases of postprandial hypotension and in patients having the "dumping" syndrome after gastric surgery, any hyperosmolar intestinal content is diluted by water taken from circulation and being trapped in the bowel until reabsorption. High fructose corn sirup (HFCS) soft drinks are among common hyperosmolar drinks. Fructose is slowly absorbed through passive carrier-mediated facilitated diffusion, along the entire small bowel, thus preventing absorption of the trapped water for several hours.Here presented interpretation is that ingestion of hyperosmolar HFCS drinks due to a transient fluid shift into the small bowel increases renin secretion and sympathetic activity, leading to rise in ADH and aldosterone secretions. Their actions spare water and sodium in the large bowel and kidneys. Alteration of colon absorption due to hormone exposure depends on cell renewal and takes days to develop, so the momentary capacity of sodium absorption in the colon depends on the average aldosterone and ADH exposure during few previous days. This inertia in modulation of the colon function can make an individual that often takes HFCS drinks prone to sodium retention, until a new balance is reached with an expanded ECF pool and arterial hypertension. In individuals with impaired fructose absorption, even a higher risk of arterial hypertension can be expected.
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PMID:Arterial hypertension due to fructose ingestion: model based on intermittent osmotic fluid trapping in the small bowel. 2057 72

Lactobacillus kunkeei is classified as a sole obligate fructophilic lactic acid bacterium that is found in fructose-rich niches, including the guts of honeybees. The species is differentiated from other lactobacilli based on its poor growth with glucose, enhanced growth in the presence of oxygen and other electron acceptors, and production of high concentrations of acetate from the metabolism of glucose. These characteristics are similar to phylogenetically distant Fructobacillus spp. In the present study, the genomic structure of L. kunkeei was characterized by using 16 different strains, and it had significantly less genes and smaller genomes when compared with other lactobacilli. Functional gene classification revealed that L. kunkeei had lost genes specifically involved in carbohydrate transport and metabolism. The species also lacked most of the genes for respiration, although growth was enhanced in the presence of oxygen. The adhE gene of L. kunkeei, encoding a bifunctional alcohol dehydrogenase (ADH)/aldehyde dehydrogenase (ALDH) protein, lacked the part encoding the ADH domain, which is reported here for the first time in lactic acid bacteria. The deletion resulted in the lack of ADH activity, implying a requirement for electron acceptors in glucose assimilation. These results clearly indicated that L. kunkeei had undergone a specific reductive evolution in order to adapt to fructose-rich environments. The reduction characteristics were similar to those of Fructobacillus spp., but distinct from other lactobacilli with small genomes, such as Lactobacillus gasseri and Lactobacillus vaginalis. Fructose-richness thus induced an environment-specific gene reduction in phylogenetically distant microorganisms.
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PMID:Genomic characterization of a fructophilic bee symbiont Lactobacillus kunkeei reveals its niche-specific adaptation. 2777 11

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