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M Sharkawi 《Life sciences》1984,35(23):2353-2357
The activity of liver alcohol dehydrogenase (LADH) from rats sacrificed two hours after the administration of ethanol 3, 4 or 5 g/kg intraperitoneally was significantly inhibited compared to the activity of LADH from control rats. LADH activity was inversely related to the dose of ethanol administered, to the concentration of ethanol in the liver, and to the concentration of ethanol in the blood. The clearance of blood ethanol in rats was dose-dependent and was inversely related to the dose administered. The half-life of ethanol elimination increased as the dose of ethanol increased. These results suggest that ethanol-induced inhibition of LADH can occur in vivo and that the level of activity of this enzyme determines the rate of oxidation of ethanol.  相似文献   

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Some catalytic properties of human liver alcohol dehydrogenase   总被引:10,自引:0,他引:10  
A H Blair  B L Vallee 《Biochemistry》1966,5(6):2026-2034
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Catalytic properties of human liver alcohol dehydrogenase isoenzymes   总被引:2,自引:0,他引:2  
W F Bosron  T K Li 《Enzyme》1987,37(1-2):19-28
Human liver alcohol dehydrogenase (ADH) exists in multiple molecular forms which arise from the association of eight different types of subunits, alpha, beta 1, beta 2, beta 3, gamma 1, gamma 2, pi, and chi, into active dimeric molecules. A genetic model accounts for this multiplicity as products of five gene loci, ADH1 through ADH5. Polymorphism occurs at two loci, ADH2 and ADH3, which encode the beta and gamma subunits. All of the known homodimeric and heterodimeric isoenzymes have been isolated and purified to homogeneity. Analysis of the steady-state kinetic properties and substrate and inhibitor specificities has shown substantial differences in the catalytic properties of the isoenzymes. For example, the Km values for NAD+ and ethanol vary as much as 1,000-fold among the isoenzymes. Some of the differences in catalytic properties can be related to specific amino acid substitutions in the ADH isoenzymes.  相似文献   

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The human class I alcohol dehydrogenase isozyme beta 2 beta 2 was used as the antigen to raise monoclonal antibodies. Altogether seven lines of hybridomas secreting monoclonal antibodies were obtained. None of the antibodies was isozyme specific and all of them exhibited a similar affinity against all isozymes of the human class I ADH. Five out of the seven monoclonal antibodies had no effect on beta 2 beta 2 activity. Antibody G3 acted as a non-competitive inhibitor with a KI of 3 micrograms/ml at pH 7.5. Increasing pH was effective in reducing the level of inhibition. On the other hand, antibody 1D4 exhibited a pH-dependent activation of ADH activity. In the presence of this antibody, the pH optimum of beta 2 beta 2 was shifted from 9 to 8.5 and total activity was increased by 70% at this optimal pH. Kinetic analysis indicates that 1D4 probably acts as a non-competitive activator and may exert its action by interacting with the coenzyme binding site.  相似文献   

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It is shown that thiochrome inhibits alcohol dehydrogenase. Thiochrome is able to be bound with alcohol dehydrogenase more quickly than other thiamine metabolites. This process is specific and has common features with the process of NAD binding by this enzyme. The inhibition of alcohol dehydrogenase by thiochrome is concurrent to NAD. The constant of alcohol dehydrogenase inhibition by thiochrome is 3.9 x 10(-5) M.  相似文献   

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Hydrophobic anion activation of human liver chi chi alcohol dehydrogenase   总被引:13,自引:0,他引:13  
Class III alcohol dehydrogenase (chi chi-ADH) from human liver binds both ethanol and acetaldehyde so poorly that their Km values cannot be determined, even at ethanol concentrations up to 3 M. However, long-chain carboxylates, e.g., pentanoate, octanoate, deoxycholate, and other anions, substantially enhance the binding of ethanol and other substrates and hence the activity of class III ADH up to 30-fold. Thus, in the presence of 1 mM octanoate, ethanol displays Michaelis-Menten kinetics. The degree of activation depends on the size both of the substrate and of the activator; generally, longer, negatively charged activators result in greater activation. At pH 10, the activator binds to the E-NAD+ form of the enzyme to potentiate substrate binding. Pentanoate activates methylcrotyl alcohol oxidation and methylcrotyl aldehyde reduction 14- and 30-fold, respectively. Such enhancements of both oxidation and reduction are specific for class III ADH; neither class I nor class II shows this effect. The implications as to the nature of the physiological substrate(s) of class III ADH are discussed in light of the recent finding that this ADH and glutathione-dependent formaldehyde dehydrogenase are identical. A new rapid purification procedure for chi chi-ADH is presented.  相似文献   

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Heterogeneity and new molecular forms of human liver alcohol dehydrogenase   总被引:5,自引:0,他引:5  
The distribution of the multiple molecular forms of human liver alcohol dehydrogenase and the specific enzymatic activity of homogenate supernatants were examined in 100 liver specimens from Indianapolis, IN. The specific enzymatic activities of livers with the ADH3 2 phenotype were significantly higher than those with the ADH3 1 or ADH3 2?1 phenotype. By comparison of the electrophoretic pattern and the pH-activity profiles of the homogenate supernatants, sixteen percent of the specimens contained hitherto unknown enzyme forms exhibiting unusual electrophoretic mobility and a pH-optimum of 7.0 for ethanol oxidation. The data confirm that the molecular and catalytic properties of this enzyme are even more diverse than has been known.  相似文献   

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 By the use of a newly developed technique of ultrathin-layer electrophoresis, class I and class II alcohol dehydrogenase activity could be demonstrated in microdissected samples of the periportal, intermediate, and perivenous zones of the liver acinus in men and women. It could be demonstrated that both classes exhibit low activity in the periportal zone. From there, a rising gradient in the direction of the perivenous end was apparent. This increase, however, was found to be significant only in women. The analysis of class I alcohol dehydrogenase isoenzymes showed that the expression of α-, β-, and γ-containing isoforms did not differ in relation to the intraacinar position. The constant proportions of the isoenzymes to the maxima and minima of the total alcohol dehydrogenase activity support the view that the adult liver-specific isoenzyme pattern is determined during postnatal development. Accepted: 1 February 1999  相似文献   

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The rate-limiting step of ethanol oxidation by alcohol dehydrogenase (E) at substrate inhibitory conditions (greater than 500 mM ethanol) is shown to be the dissociation rate of NADH from the abortive E-ethanol-NADH complex. The dissociation rate constant of NADH decreased hyperbolically from 5.2 to 1.4 s-1 in the presence of ethanol causing a decrease in the Kd of NADH binding from 0.3 microM for the binary complex to 0.1 microM for the abortive complex. Correspondingly, ethanol binding to E-NADH (Kd = 37 mM) was tighter than to enzyme (Kd = 109 mM). The binding rate of NAD+ (7 X 10(5) M-1s-1) to enzyme was not affected by the presence of ethanol, further substantiating that substrate inhibition is totally due to a decrease in the dissociation rate constant of NADH from the abortive complex. Substrate inhibition was also observed with the coenzyme analog, APAD+, but a single transient was not found to be rate limiting. Nevertheless, the presence of substrate inhibition with APAD+ is ascribed to a decrease in the dissociation rate of APADH from 120 to 22 s-1 for the abortive complex. Studies to discern the additional limiting transient(s) in turnover with APAD+ and NAD+ were unsuccessful but showed that any isomerization of the enzyme-reduced coenzyme-aldehyde complex is not rate limiting. Chloride increases the rate of ethanol oxidation by hyperbolically increasing the dissociation rate constant of NADH from enzyme and the abortive complex to 12 and 2.8 s-1, respectively. The chloride effect is attributed to the binding of chloride to these complexes, destabilizing the binding of NADH while not affecting the binding of ethanol.  相似文献   

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All adult and infant human liver homogenates studied thus far show two previously unreported forms of alcohol dehydrogenase on starch gel electrophoresis. Under the conditions employed, these forms migrate toward the anode and readily stain for pentanol but virtually not for ethanol oxidizing activity. In contrast, all human ADH isoenzymes identified previously are cathodic and react equally well with either substrate. These new ADH forms have been separated from the other known ones by DEAE-cellulose chromatography and are then purified on Agarose-hexane-AMP. Although the physical characteristics of the new anodic ADH forms are similar to those of the known human ADH isoenzymes, the former are not inhibited by 12 mM 4-methyl pyrazole, oxidize ethanol very poorly and appear to prefer longer chain alcohols as substrates.  相似文献   

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Previous studies showed that natural human liver alcohol dehydrogenase gamma exhibits negative cooperativity (substrate activation) with ethanol. Studies with the recombinant gamma(2) isoenzyme now confirm that observation and show that the saturation kinetics with other alcohols are also nonhyperbolic, whereas the kinetics for reactions with NAD(+), NADH, and acetaldehyde are hyperbolic. The substrate activation with ethanol and 1-butanol are explained by an ordered mechanism with an abortive enzyme-NADH-alcohol complex that releases NADH more rapidly than does the enzyme-NADH complex. In contrast, high concentrations of cyclohexanol produce noncompetitive substrate inhibition against varied concentrations of NAD(+) and decrease the maximum velocity to 25% of the value that is observed at optimal concentrations of cyclohexanol. Transient kinetics experiments show that cyclohexanol inhibition is due to a slower rate of dissociation of NADH from the abortive enzyme-NADH-cyclohexanol complex than from the enzyme-NADH complex. Fluorescence quenching experiments confirm that the alcohols bind to the enzyme-NADH complex. The nonhyperbolic saturation kinetics for oxidation of ethanol, cyclohexanol, and 1-butanol are quantitatively explained with the abortive complex mechanism. Physiologically relevant concentrations of ethanol would be oxidized predominantly by the abortive complex pathway.  相似文献   

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The alpha subunit of human liver alcohol dehydrogenase has been submitted to structural analysis. Together with earlier work on the beta and gamma subunits, the results allow conclusions on the relationship of all known forms of the class I type of the enzyme. Two segments of the alpha subunit were determined; one was also reinvestigated in the beta and gamma subunits. The results establish 11 residue replacements among class I subunits in the segments analyzed and show that the alpha, beta, and gamma protein chains each are structurally distinct in the active site regions, where replacements affect positions influencing coenzyme binding (position 47; Gly in alpha, Arg in beta and gamma) and substrate specificity (position 48; Thr in alpha and beta, Ser in gamma). Residue 128, previously not detected in beta and gamma subunits, corresponds to a position of another isozyme difference (Arg in beta and gamma, Ser in alpha). The many amino acid replacements in alcohol dehydrogenases even at their active sites illustrate that in judgements of enzyme functions absolute importance of single residues should not be overemphasized. Available data suggest that alpha and gamma are the more dissimilar forms within the family of the three class I subunits that have resulted from two gene duplications. The class distinction of alcohol dehydrogenases previously suggested from enzymatic, electrophoretic, and immunological properties therefore also holds true in relation to their structures.  相似文献   

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