UMLS:C1332347 - FACTA Search

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Query: UMLS:C1332347 (ADH)
2,230 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Microquantitative measurements of ADH-activity were carried out on the livers of male and female rats, guinea-pigs and horses (two geldings and a mare). Lyophilized cryostat sections of liver parenchyma were microdissected the whole way along the sinusoidal length from the terminal afferent vessels to the terminal efferent venule. ADH activity in samples of about 50-150 ng was measured in a microbiochemical assay using the oil-well technique without enzymatic cycling, by direct luminometric determination of NADH. On the basis of the single measurements, mean values of total hepatic ADH activity could be calculated and the specific distribution patterns graphically demonstrated. Total activity of ADH in the liver of the female rat is 1.6 times higher than in the male; the male distribution pattern exhibits a relative maximum in the intermediary zone of the acinus while the activity in the liver of female rats increases towards a perivenous maximum. Mean values for total ADH activity in the livers of male and female guinea-pigs are almost equal and there is, moreover, no clear intra-acinar gradient. Mare and castrated male horses show high hepatic ADH activity which is evenly distributed in the liver acinus.
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PMID:Microquantitative determination of the distribution patterns of alcohol dehydrogenase activity in the liver of rat, guinea-pig and horse. 293 53

Lipid peroxidation has been invoked as a mechanism of alcoholic liver injury but its role has been controversial and the mechanism by which it occurs is unclear. Catalytic iron is known to play an important role in cellular injury and is produced during mobilization of ferritin iron. In vivo administration of a large acute dose of ethanol (5 g/kg) which produces hepatic lipid peroxidation in chow-fed rats resulted in mobilization of non-heme iron. The generation of NADH from alcohol metabolism via ADH or superoxide from acetaldehyde-xanthine oxidase mobilized iron from horse spleen ferritin in vitro. Chronic feeding of alcohol as 36% of energy for 6 weeks does not itself produce peroxidation in the rat but potentiates acute effects of ethanol. It produced microsomal induction which enhanced iron-stimulated lipid peroxidation and increased hepatic non-heme iron. Carbon monoxide increased rather than decreased accumulation of microsomal peroxidation products in vitro suggesting that cytochrome P-450 reductase mediates peroxidation but cytochrome P-450 may metabolize products. Incubation at lowered oxygen tensions equivalent to those observed in the perivenular zone (pO2 = 24 mmHg) enhanced in vitro iron mobilization but decreased peroxidation. Lipid peroxidation and its stimulation by iron mobilization and microsomal induction may be an important contributory mechanism of alcohol-induced liver injury.
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PMID:Lipid peroxidation as a mechanism of alcoholic liver injury: role of iron mobilization and microsomal induction. 313 9

Increased alcohol tolerance following chronic alcohol administration has been explained by increased mitochondrial oxidation of NADH and or increased activation of MEOS. According to our experiments this increased tolerance after chronic alcohol consumption is connected with an increased activity of ADH.
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PMID:Increase of alcohol dehydrogenase and protein content of liver following chronic ethanol administration. 315 63

Hepatic microsomes catalyze the oxidation of ethanol and other drugs. The mechanisms through which ethanol alters mixed function oxidation are still debated. There is evidence that ethanol and drugs interact at a microsomal level, but there are also claims that ethanol may interfere with drug metabolism indirectly by affecting the supply of NADPH through NADH production in the ADH pathway. To investigate the role of chronic ethanol consumption, deermice with normal liver ADH (ADH+) or genetically lacking ADH (ADH-) were pair-fed liquid diets containing ethanol or isocaloric carbohydrate for 23 days. The acute effects of ethanol were studied in deermice fed standard laboratory chow and tap water ad lib. In vivo and in vitro, the effects of an acute dose of ethanol and chronic ethanol feeding on mixed function oxidation as measured by the demethylation of aminopyrine were similar in both animal strains. Statistical analysis showed no significant differences between ADH+ and ADH- animals under all experimental conditions studied. We conclude that induction and inhibition of mixed function oxidation by ethanol may be related to the interaction of ethanol with hepatic microsomes rather than to redox changes produced by ADH mediated ethanol metabolism.
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PMID:Effects of acute ethanol administration and chronic ethanol feeding on mixed function oxidation in deermice lacking ADH. 316 Mar 66

The structure and kinetics of the isozymes from Saccharomyces cerevisiae (ADH I, II, III) have been compared, and the ADH I gene was specifically mutagenized in order to substitute amino acid residues of particular interest. A model of the yeast enzyme was constructed on the basis of the structure of the homologous horse liver enzyme. Steady state kinetic studies, at pH 7.3 and 30 degrees C, showed that the enzymes follow the Ordered Bi Bi mechanism. ADH II has a Michaelis constant for ethanol that is 10-fold smaller than the constants found for ADH I or III. Replacement of Met-294 (liver numbering) in the substrate binding pocket of ADH I with Leu, as found in ADH II, could be responsible for the different kinetics. However, the mutant enzyme, ADH I-Leu, had constants with ethanol that were similar to those of ADH I. Nevertheless, the Leu enzyme had better catalytic activity with longer chain alcohols than did the Met enzyme. Other substitutions must account for the differences between ADH I and II. His-47 binds the pyrophosphate of coenzyme, and replacement with Arg (as in the liver enzyme) decreases turnover numbers by 6-fold and dissociation constants for NAD+ and NADH by only 2 to 4-fold. The lower turnover number explains why yeast harboring the mutant Arg enzyme are resistant to poisoning by allyl alcohol. ADH I and ADH I-Arg have maximal activity on ethanol at pH values above a pK of about 7. Replacement of His-51 with Gln reduces activity 12-fold and abolishes the pK value.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Structure and function in yeast alcohol dehydrogenases. 330 37

The beta 3 beta 3 (formerly called beta Indianapolis) and beta 1 beta 1 isoenzymes of human alcohol dehydrogenase differ substantially in their catalytic properties. Specifically, the KM value for NAD+ of beta 3 beta 3 is 70 times greater than that of beta 1 beta 1, and the Ki value for NADH is 35 times greater than that of beta 1 beta 1. To identify the structural basis of these catalytic differences, we sequenced regions of the beta 3 subunit and the beta 3 gene. beta 3 differs from beta 1 by the substitution of Cys for Arg-369. Based on x-ray crystallography of horse ADH, Arg-369 should interact with the nicotinamide phosphate moiety of NAD(H). The Cys for Arg-369 substitution would decrease the enzyme's affinity for coenzyme and, thus, account for the observed kinetic differences between beta 3 beta 3 and beta 1 beta 1.
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PMID:The human beta 3 alcohol dehydrogenase subunit differs from beta 1 by a Cys for Arg-369 substitution which decreases NAD(H) binding. 361 18

The activity of prostaglandin (PG)E2-9-ketoreductase (9KR), an enzyme catalyzing the conversion of PGE2 to PGF2 alpha, was significantly increased in glomerular and cortical homogenates of diabetes insipidus (DI) rats, as compared to normal Long Evans (LE) rats, and did not change with ADH treatment. Medullary 9KR was similar in the three groups and papillary 9KR was increased, but not significantly, in both groups of DI rats. Km values for PGE2 and NADH were compared in the various compartments of the kidney. Levels of 9KR were not correlated with the PGE/PGF ratio in urine or supernatants. The synthesis of PGE2 and PGF2 alpha by isolated glomeruli was increased in DI rats. This was not reversed by ADH treatment, PGE2 synthesis increasing even further, especially in the presence of arachidonic acid. In contrast, medullary slices produced significantly less PGs in DI than in LE rats and returned to normal with ADH treatment. Papillary slices produced similar quantities of prostaglandins in all groups. The results do not support the concept that the alterations in PG synthesis observed in DI rat are related only to changes in 9KR activity, but do not exclude the possibility that the enzyme participates in the regulation of PG biosynthesis.
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PMID:NADH-dependent prostaglandin E2-9-ketoreductase activity and prostaglandin synthesis in the Brattleboro rat kidney: effects of the antidiuretic hormone. 378 10

Acute alcohol intoxication is far more commonly observed in Orientals than Caucasians. The human liver contains several cytosolic and microsomal ADHs. One of the major cytosolic ADH isozymes controlled by a gene at the ADH2 locus differs between Caucasians and Orientals. Most Caucasians have the usual enzyme consisting of usual beta 1 subunit, while nearly 90% of Orientals have the atypical enzyme consisting of the atypical beta 2 subunit. The specific activity of the atypical enzyme is several times higher at pH 10 and nearly 100 times higher at physiologic pH than the usual enzyme. Km values for ethanol, NAD, acetaldehyde, and NADH are several times higher for the atypical enzyme than for the usual enzyme. The usual enzyme is rapidly inactivated by iodoacetate, indicating the existence of an "active-site cysteine" in the molecule. In contrast, the atypical enzyme is resistant to iodoacetate inactivation. Peptide mapping analysis revealed that the active site Cys in the usual beta 1 subunit is replaced by His in the atypical beta 2 subunit. A remarkable structural homology exists at the active site of horse and human enzymes. In the usual beta 1 beta 1 enzyme, as in the horse enzyme, the catalytic Zn is expected to link to the sensitive Cys at position 47, His at position 67, and Cys (presumably) at position 174, thus forming the active site. In contrast, the active site of the atypical beta 2 beta 2 enzyme is expected to consist of the catalytic Zn linked to His at position 47, His at position 67, and Cys (presumably) at position 174. The resistance of the atypical beta 2 beta 2 to inactivation by iodoacetate is a direct consequence of the replacement of the sensitive Cys at position 47 by His. Liver ALDH components also differ between Caucasians and Orientals. Virtually all Caucasians have two major ALDH isozymes, ALDH1 and ALDH2, while approximately 50% of Orientals have only the ALDH1 isozyme (cytosolic) missing ALDH2 isozyme (presumably mitochondrial). ALDH1 consists of four subunits with a molecular weight of 56,500, and ALDH2 consists of four subunits with a molecular weight of 52,600. The two isozymes do not share any common subunit. Examination of liver extracts by two-dimensional crossed immunoelectrophoresis revealed that an atypical Oriental liver with no ALDH2 isozyme contained an enzymatically inactive but immunologically cross-reactive material corresponding to ALDH2, besides the active ALDH1 isozyme.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Differences in the isozymes involved in alcohol metabolism between caucasians and orientals. 635 99

Alcohol dehydrogenase activity in mouse liver homogenate-supernatants is 1.7 times greater in the C57BL/10 strain than in the BALB/c strain, regardless of whether activity is expressed in units per gram liver, total liver, or milligram DNA. The Km values for ethanol and NAD+, approximately 0.4 and 0.03 mM, respectively, of enzyme purified from both strains are similar. Moreover, the Ki for NADH, 1 microM, the pH optimum for ethanol oxidation, 10.5, and the Vmax for ethanol oxidation, 160 min-1, for ADH from the C57BL/10 and BALB/c strains are similar. Therefore, the difference in ADH activity in the two strains cannot be due to differences in the catalytic properties of the enzyme. The electrophoretic and isoelectric focusing patterns and two-dimensional tryptic peptide maps of the purified enzyme from both strains are identical. Thus the amino acid sequences of enzyme from C57BL/10 and BALB/c mice must also be identical or very similar. The difference in ADH activity in the two strains is most likely the result of genetic differences in the content of ADH protein in liver.
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PMID:Purification and characterization of mouse alcohol dehydrogenase from two inbred strains that differ in total liver enzyme activity. 637 Feb 28

chi-Alcohol dehydrogenase (chi-ADH), a class III isozyme characterized by its anodic electrophoretic mobility and lack of inhibition by 4-methylpyrazole, has been isolated from human liver and purified to homogeneity in a reducing medium. chi-ADH resembles other human liver ADH isozymes of classes I and II with respect to its molecular weight, dimeric structure, stoichiometry of zinc and NADH binding, and pH optima for the oxidation of alcohols. This homodimer exhibits subtle differences in its absorption spectrum and amino acid composition relative to those of other human isozymes but differs markedly from their specificity toward alcohols and aldehydes. chi-ADH oxidizes ethanol very poorly. The reaction is bimolecular, and an apparent Km cannot be discerned up to 2.3 M ethanol. The enzyme is inactive toward methanol, ethylene glycol, digitoxigenin, digoxigenin, and gitoxigenin , but alcohols with carbon chain lengths greater than four are oxidized rapidly with Km values decreasing with increasing carbon chain length. Taken jointly, the composition, structure, and enzymatic properties of the ADH isozymes purified and studied so far strongly imply that their metabolic roles, yet to be discovered, will give a new perspective to ethanol metabolism and pathology.
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PMID:Physical and enzymatic properties of a class III isozyme of human liver alcohol dehydrogenase: chi-ADH. 637 18

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