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. Ethanol metabolism in slices or homogenates of transplantable hepatocellular carcinoma HC-252 (HC-252) was 50 to 60% of the rate found in host liver slices or homogenates when they were expressed per gram of tissue wet weight and 70 to 80% of the liver when the rates were expressed per milligram of tissue protein. At 10 mM ethanol, the activities of alcohol dehydrogenase in tumor and liver supernatants were comparable. 2. Tumor microsomes did not oxidize ethanol in the presence of a NADPH-generating system, indicating the absence of the microsomal ethanol-oxidizing system and catalase-mediated peroxidation of ethanol. The HC-252 microsomes were contaminated with catalase, and acetaldehyde production occurred in the presence of a H2O2-generating system (xanthine oxidase). The virtual absence of ethanol oxidation and drug metabolism (aminopyrine demethylase and aniline hydroxylase) in HC-252 microsomes may be due to the low activities of NADPH-cytochrome c reductase, NADPH oxidase, and NADPH-dependent oxygen uptake. 3. Microsomal oxidation of ethanol was present in Morris hepatoma 5123C, a well-differentiated tumor of intermediate growth rate, while activity was negligible in microsomes from Morris hepatoma 7288CTC, a less differentiated tumor. Microsomal NADPH oxidase was present in the well differentiated tumor 5123C but was lacking in the less differentiated tumor 7288CTC. Several microsomal, mitochondrial, and cytosolic properties of HC-252 are similar to those of Morris hepatoma 7288CTC but differ from those of the more differentiated 5123C tumor and normal liver. 4. The content of mitochondrial protein in HC-252 was only 25% that of liver, and oxygen consumption per gram of tumor was only 28% that of the liver. When corrected for the mitochondrial protein content, oxygen uptake in tumor HC-252 and liver homogenates was comparable. Isolated tumor and liver mitochondria displayed comparable State 4 and 3 rates of oxygen consumption with succinate and glutamate as substrates. The activities of the reconstituted malate-aspartate and alpha-glycerophosphate shuttles were only slightly lower in isolated HC-252 mitochondria compared to liver mitochondria, when shuttles were reconstituted with purified enzymes. 5. Antimycin inhibited alcohol metabolism,and pyruvate stimulated alcohol metabolism, much less in tumor slices than in liver slices, suggesting the presence of an augmented mitochondria-independent, cytosolic mechanism for oxidizing reducing equivalents in the tumor. These factors suggest that oxidation of NADH is the limiting factor in ethanol metabolism. Whereas, in the liver mitochondrial reoxidation is predominant, in HC-252, cytosolic reoxidation of NADH also plays a major role.
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PMID:Ethanol metabolism by a transplantable hepatocellular carcinoma. Role of microsomes and mitochondria. 13 37

The pathways responsible for ethanol oxidation and the toxic results of its metabolism are reviewed. The predominant pathway for ethanol oxidation at low ethanol concentrations involves alcohol dehydrogenase. However, at high alcohol concentrations, up to 50% of ethanol uptake is 4-methylpyrazole-intensitive. Oxidation of ethanol under these conditions is associated with a change in the steady-stage concentration of catalase-H2O2. Based on recent evidence, we conclude that it is unnecessary to postulate that ethanol is oxidized directly via cytochrome P-450. Acetaldehyde production from ethanol via the microsomal subfraction can be accounted for by the combined activities of catalase-H2O2 and alcohol dehydrogenase. The metabolism of ehtanol via alcohol dehydrogenase produces a marked reduction in the hepatocellular NAD-NADH sytems. This reduction is indirectly responsible for the inhibition of glycolysis, gluconeogenesis, citric acid cycle activity, and fatty acid oxidation and may be related to some of the pathological effects observed following chronic consumption of alcohol. Attempts in inhibit alcohol dehydrogenase with alkylpyrazoles and activate catalase with substrates for peroxisomal H2O2-generating flavoproteins, while successful, may have limited applicability because of the native toxicity of the substrates themselves...
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PMID:Hepatic alcohol oxidation and its metabolic liability. 19 Dec 95

Rat liver microsomes oxidized ethanol two to three times faster than propanol when incubated with either an NADPH- or an H2O2-generating system. In addition, solubilized, purified microsomal subfractions were found to contain protein with an electrophoretic mobility identical to rat liver catalase on SDS polyacrylamide gels, suggesting that the separation of catalase from cytochrome P-450 and other microsomal components may not be feasible. These data support the postulate that catalase is responsible for NADPH-dependent microsomal ethanol oxidation. Direct read-out techniques for pyridine nucleotides, the catalase-H2O2 complex, and cytochrome P-450 were utilized to evaluate the specificity of inhibitors of alcohol dehydrogenase (4-methylpyrazole; 4 mM) and catalase (aminotriazole; 1.0 g/kg) qualitatively in perfused rat livers. 4-Methylpyrazole and aminotriazole are specific inhibitors for alcohol dehydrogenase and catalase, respectively, under these conditions. Neither inhibitor nor a combination of them altered the mixed function oxygen of p-nitroanisole to p-nitrophenol as observed by oxygen uptake and product formation. When ethanol utilization was measured over the concentration range 20-80 mM in perfused liver, a concentration dependence was observed. At low concentrations of ethanol, ethanol oxidation was almost totally abolished by 4-methylpyrazole; however, the contribution of 4-methylpyrazole-insensitive ethanol uptake increased as a function of ethanol concentration. At 80 mM ethanol, ethanol utilization was nearly 50% methylpyrazole-insensitive. This portion of ethanol oxidation, however, was abolished by aminotriazole. The data indicate that alcohol dehydrogenase and catalase-H2O2 are responsible for hepatic ethanol oxidation. At low ethanol concentrations (less than 20 mM), alcohol dehydrogenase is predominant; however, at higher ethanol concentrations (up to 80 mM), the contribution of catalase-H2O2 to overall ethanol utilization is significant. No evidence that the endoplasmic reticulum is involved in ethanol metabolism in the perfused liver emerged from these studies.
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PMID:Significant pathways of hepatic ethanol metabolism. 24 Jul 43

Oxidation of methanol, ethanol, propanol, and butanol by the microsomal fraction of rat liver homogenate is described. This microsomal alcohol-oxidizing system is dependent on NADPH and molecular oxygen and is partially inhibited by CO, features which are common for microsomal drug-metabolizing enzymes. The activity of the microsomal alcohol-oxidizing system could be dissociated from the alcohol peroxidation via catalase-H2O2 by differences in substrate specificity, since higher aliphatic alcohols react only with the microsomal system, but not with catalase-H2O2. Following solubilization of microsomes by ultrasonication and treatment with deoxycholate, the activity of the microsomal alcohol-oxidizing system was separated from contaminating catalase by DEAE-cellulose column chromatography, ruling out an obligatory involvement of catalase-H2O2 in the activity of the NADPH-dependent microsomal alcohol-oxidizing system. In intact hepatic microsomes, the catalase inhibitor sodium azide slightly decreased the oxidation of methanol and ethanol, but not that of propanol and butanol, indicating a facultative role of contaminating catalase in the microsomal oxidation of lower aliphatic alcohols only. It is suggested that the microsomal alcohol-oxidizing system accounts, at least in part, for that fraction of hepatic alcohol metabolism which is independent of the pathway involving alcohol dehydrogenase activity.
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PMID:Hepatic microsomal alcohol-oxidizing system. Affinity for methanol, ethanol, propanol, and butanol. 24 Aug 27

"Uncoupling" of microsomal hepatic oxygenases is characterized by a situation in which microsomal monooxygenases exhibit more oxidase than oxygenase activity with an increased formation of hydrogen peroxide at the expense of O2, NADPH and substrate hydroxylation. The importance of such in vitro observations with respect to physiological conditions "in vivo" has been tested by investigating elimination kinetics of ethanol. If hexobarbital, a substrate of mixed function oxygenase as well as an "uncoupler", is given to guinea pigs together with ethanol, changes in the elimination of ethanol occur. It is suggested that this is the consequence of an increased formation of H2O2 which contributes via peroxidatic reaction of catalase to the elimination of ethanol. The results also show additional interactions of hexobarbital as well as of ethylmorphine with ethanol elimination. Both compounds increased the initial blood levels of ethanol which precede accelerated elimination, probably by a first pass effect. At low concentrations of ethanol, ethylmorphine inhibits ethanol elimination by inhibition of ADH.
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PMID:Demonstration of drug-ethanol interactions by changes in activity of hepatic microsomal oxidase/oxygenase cytochrome P-450 function. 28 65

Simple models were developed to study changes in oxygen uptake in perfused rat liver and increases in ethanol metabolism in vivo. Results obtained 2.5 hours following a large dose of ethanol were quantitatively similar to those seen after 24 hours or 5 weeks. The rapidity of the increase indicated that SIAM represents an activation rather than an adaptation. Pathways responsible for the swift increase in alcohol metabolism (SIAM) in the perfused rat liver were investigated through the use of ouabain and were found to be related to diminished glycolysis and another unidentified pathway. Investigation of pathways responsible for the increase in ethanol metabolism in vivo following ethanol treatment implicated the alcohol dehydrogenase pathway as that mainly responsible for the adaptive increase, although a catalase-H2O2-dependent component was also involved. The rate of NADH reoxidation generally appeared to be the rate-limiting step. In addition, the genetic aspect of SIAM was indicated through selective breeding resulting in F1 generations of non-SIAM and SIAM rats.
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PMID:The adaptive increase in ethanol metabolism due to pretreatment with ethanol: a rapid phenomenon. 51 Jan 61

The spectrophotometric determination of the catalase-H2O2 intermediate (Compound I) was extended to the liver in situ in anaesthetized rats. The rate of H2O2 production was determined for the liver in situ with endogenous substrates, and in the presence of excess of glycollate. Glycollate infusion doubled H2O2 production rate in the liver of air-breathing rats, and caused a fourfold increase when rats breathed O2 at 1 times 10(5) Pa. Hyperbaric O2 up to 6 times 10(5) Pa did not increase H2O2 generation supported by endogenous substrates, nor did it increase H2O2 production above that produced by 1 times 10(5) Pa O2 in glycollate-supplemented rats. The rates of ethanol oxidation via hepatic catalase and via alcohol dehydrogenase in the whole body were separately measured. The contribution of hepatic catalase to ethanol oxidation was found to be approx. 10 percent in endogenous conditions and increased to 30 percent or more of the total ethanol oxidation in rats supplemented with glycolate.
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PMID:Optical measurement of the catalase-hydrogen peroxide intermediate (Compound I) in the liver of anaesthetized rats and its implication to hydrogen peroxide production in situ. 114 5

The strong inhibition of horse liver alcohol dehydrogenase (HLAD) by p-methylbenzyl hydroperoxide (XyHP) is only transient, XyHP behaves also as a pseudo-substrate of the enzyme and in the presence of NAD+, is degraded by HLAD to (as yet unidentified) non-inhibiting products while the NAD+ is converted to a derivative similar to the "NADX", originally observed in an analogous reaction of HLAD with hydrogen peroxide. The apparent KM for XyHP is approximately 10(4) times smaller than that for H2O2. The catalytic constant kcat for HLAD degradation of XyHP is two orders of magnitude less than that for ethanol dehydrogenation. XyHP inhibits both directions of the alcohol-aldehyde interconversion with equal potency. The first step of the inhibition mechanism is a tight binding of XyHP to the binary HLAD-NAD+ complex.
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PMID:Hydroperoxidic inhibitor of horse liver alcohol dehydrogenase activity, tightly bound to the enzyme-NAD+ complex, characteristically degrades the coenzyme. 128 58

We have studied the damage of alcohol dehydrogenase (ADH) and glyceraldehyde 3-phosphate dehydrogenase (GAPD) induced by Fe++/EDTA + H2O2 in combination with UV-A (main output at 365 nm). Enzyme inactivation, formation of hydroxyl radicals (measured in the absence of enzymes), increase in protein carbonyls, oxidation of sulfhydryl (SH) groups, loss of native protein fluorescence, and enhanced protease degradation were used to determine protein damage. Hydroxyl radical production was greatly enhanced by the combination of UV-A with Fe++/EDTA + H2O2. The combined treatment increased protein carbonyls but decreased native protein fluorescence and SH groups. The combined treatment caused turbidity in GAPD but not in ADH, whereas trypsin susceptibility was increased more in ADH than in GAPD. These measurements of protein oxidation correlated well with enzyme activities. Glyceraldehyde 3-phosphate dehydrogenase and dithiothreitol were most protective against such damage, while hydroxyl radical and singlet oxygen scavengers were partially effective. Superoxide dismutase had no effect. Thus, UV-A potentiation of protein damage induced by FE++/EDTA + H2O2 appeared to involve hydroxyl radicals and perhaps singlet oxygen but not superoxide radicals. The damage to proteins induced by combination of UV-A with physiological oxidants, iron ions and H2O2 may be relevant to UV-A-induced skin and tissue damage.
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PMID:Potentiation of oxidative damage to proteins by ultraviolet-A and protection by antioxidants. 143 70

Entamoeba histolytica can reduce nitro-blue tetrazolium (NBT) in Hank's balanced salt solution to almost the same extent as in Eagle's minimal medium. Further, this reduction was stimulated only to a minor degree by glucose, pyruvate and DL-serine, substrates known to support respiratory activity (O2 uptake) in E. histolytica. However, both NADH and NADPH increased NBT reduction several-fold, the effect being greater with NADPH. A sizeable proportion of this endogenous dye-reducing capability (in Hank's solution) was associated with low-speed sediments obtainable from amoebic homogenates, which also shared the bulk of 125I labelling (when the homogenates were prepared after surface labelling with Na 125I). Conversion of the dye to formazan was strongly inhibited by -SH blocking agents, but was not influenced by rotenone and antimycin A. The activity was also inhibited by H2O2, but stimulated by catalase. Superoxide dismutase only slightly curtailed NBT reduction in intact cells, but inhibited it in homogenates in a concentration-dependent manner to a maximal extent of 33%. Almost the same degree of curtailment of this activity was induced by anaerobic conditions. Both concanavalin A (Con A) and phorbol myristate acetate stimulated the activity in intact cells, though the effect of Con A was nullified by alpha-methyl mannoside. Both NBT-reducing capability and alcohol dehydrogenase activities were higher in the more virulent IP:106 strain, and they increased with time in cultures of NIH:200 in a cholesterol-enriched environment.
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PMID:Oxido-reductive functions of Entamoeba histolytica in relation to virulence. 144 72

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