Rabbit liver alcohol dehydrogenase: isolation and characterization of class I isozymes

Livers of rabbits contain three classes of alcohol dehydrogenase (ADH) isozymes which are highly analogous to the human classes. Class I ADHs migrate toward cathode on starch gel and are very sensitive to 4-methylpyrazole (4-MePz) inhibition. Class II ADH migrates slowly toward anode and is less sensitive to 4-MePz. Class III ADH migrates rapidly toward anode and is insensitive to 4-MePz. There are one class II, one class III and at least three class I ADH isozymes present in the rabbit liver. The three class I isozymes purified to homogeneity are all dimers with subunit molecular weight of 41700. Two are heterodimers composed of A-, C-chains and B-, C-chains, respectively. The third one is a homodimer, contains only the C-chain. These results indicate that among all the mammals examined, rabbit ADH bears the greatest resemblance to the human enzyme.     

In vitro dissociation and reassociation of human alcohol dehydrogenase class I isozymes

Freezing (-78 degrees C) and thawing (25 degrees C) a heterodimeric human alcohol dehydrogenase class I isozyme in the presence of 0.1 M sodium phosphate/0.1 mM DTT, pH 7.0, and the subsequent separation of the scrambled isozymes by HPLC are used to prepare homodimers from heterodimers, with recovery of enzyme activity ranging from 80 to 95%. The ratio of the three isozymes obtained from a heterodimer follows the binomial distribution of 1:2:1, indicating random reassociation of the two subunits. The physical and enzymatic properties of the reassociated isozymes are the same as those obtained directly from human liver preparations. The nature of subunit-subunit interactions of human ADH class I isozymes is examined by optimizing the conditions required for the formation of the new dimers "in vitro". The effect of a number of reagents previously used in the reversible dissociation of dehydrogenases is investigated. The coenzyme NAD+ is a potent inhibitor of the dissociation of dimers during the freeze/thaw procedure. The presence of sodium phosphate in the enzyme solution is essential during the freezing and thawing experiment. No appreciable dissociation/reassociation occurs in TES, HEPES, or even potassium phosphate. The reversible dissociation is due primarily to the decrease in pH because of the low solubility of Na2HPO4 at low temperatures. The reassociation occurs after thawing in a temperature-dependent process. There is no reactivation if the enzyme is incubated at 0 degrees C after thawing, while at 25 degrees C high recovery in activity is achieved in a time period ranging from 15 to 90 min.(ABSTRACT TRUNCATED AT 250 WORDS)     

A human liver alcohol dehydrogenase enzyme-linked immunosorbent assay method specific for class I, II, and III isozymes

A sensitive and convenient method for the quantitative measurement of human alcohol dehydrogenase (ADH) isozymes based on enzyme-linked immunosorbent assay has been devised. The procedure was optimized with respect to antigen coating density, antiserum dilution, and incubation times with rabbit antisera raised against beta 1 beta 1-ADH to achieve a limit of sensitivity of 1 ng/ml for this isozyme when purified. Using the optimal conditions established, quantitative measurement of alpha beta 1, alpha gamma 1, beta 1 gamma 1, pi, and chi-ADH were obtained with antisera raised in rabbits toward these individual isozymes. The incorporation into the procedure of thimerosal (ethyl(4-mercaptobenzoato-S)mercury) or other sulfhydryl specific reagents improved the soluble phase antiserum avidity for all ADH isozymes, thereby increasing the sensitivity. Thimerosal is an absolute requirement for chi-ADH antigen-antibody binding. The polyclonal rabbit antisera elicited by the individual isozymes of the three classes of ADH exhibit a high degree of isozyme class specificity. Cross-reactivity of the antibodies with the beta 1 beta 1, alpha gamma 1, alpha gamma 2, alpha beta 1, beta 1 gamma 1, beta 1 gamma 2, pi and chi isozymes were evaluated. Antisera against the class I isozymes beta 1 beta 1 and beta 1 gamma 1 cross-react with all class I isozymes and with pi-ADH. Antibodies against pi and chi-ADH are selective and specific only for their respective antigens. Neither one cross-reacts with any class I isozyme. Conformational effects resulting from subunit interactions likely account for differences in cross-immunoreactivity between the closely homologous class I isozymes.     

Structural basis for substrate specificity differences of horse liver alcohol dehydrogenase isozymes

A structure determination in combination with a kinetic study of the steroid converting isozyme of horse liver alcohol dehydrogenase, SS-ADH, is presented. Kinetic parameters for the substrates, 5beta-androstane-3beta,17beta-ol, 5beta-androstane-17beta-ol-3-one, ethanol, and various secondary alcohols and the corresponding ketones are compared for the SS- and EE-isozymes which differ by nine amino acid substitutions and one deletion. Differences in substrate specificity and stereoselectivity are explained on the basis of individual kinetic rate constants for the underlying ordered bi-bi mechanism. SS-ADH was crystallized in complex with 3alpha,7alpha,12alpha-trihydroxy-5beta-cholan -24-acid (cholic acid) and NAD(+), but microspectrophotometric analysis of single crystals proved it to be a mixed complex containing 60-70% NAD(+) and 30-40% NADH. The crystals belong to the space group P2(1) with cell dimensions a = 55.0 A, b = 73.2 A, c = 92.5 A, and beta = 102.5 degrees. A 98% complete data set to 1.54-A resolution was collected at 100 K using synchrotron radiation. The structure was solved by the molecular replacement method utilizing EE-ADH as the search model. The major structural difference between the isozymes is a widening of the substrate channel. The largest shifts in C(alpha) carbon positions (about 5 A) are observed in the loop region, in which a deletion of Asp115 is found in the SS isozyme. SS-ADH easily accommodates cholic acid, whereas steroid substrates of similar bulkiness would not fit into the EE-ADH substrate site. In the ternary complex with NAD(+)/NADH, we find that the carboxyl group of cholic acid ligates to the active site zinc ion, which probably contributes to the strong binding in the ternary NAD(+) complex.     

Kinetic properties of human liver alcohol dehydrogenase: oxidation of alcohols by class I isoenzymes

Class I isoenzymes of alcohol dehydrogenase (ADH) were isolated by chromatography of human liver homogenates on DEAE-cellulose, 4-[3-[N-(6-aminocaproyl)-amino]propyl]pyrazole--Sepharose and CM-cellulose. Eight isoenzymes of different subunit composition (alpha gamma 2, gamma 2 gamma 2, alpha gamma 1, alpha beta 1, beta 1 gamma 2, gamma 1 gamma 1, beta 1 gamma 1, and beta 1 beta 1) were purified, and their activities were measured at pH 10.0 by using ethanol, ethylene glycol, methanol, benzyl alcohol, octanol, cyclohexanol, and 16-hydroxyhexadecanoic acid as substrates. Values of Km and kcat for all the isoenzymes, except beta 1 beta 1-ADH, were similar for the oxidation of ethanol but varied markedly for other alcohols. The kcat values for beta 1 beta 1-ADH were invariant (approximately 10 min-1) and much lower (5-15-fold) than those for any other class I isoenzyme studied. Km values for methanol and ethylene glycol were from 5- to 100-fold greater than those for ethanol, depending on the isoenzyme, while those for benzyl alcohol, octanol, and 16-hydroxyhexadecanoic acid were usually 100-1000-fold lower than those for ethanol. The homodimer beta 1 beta 1 had the lowest kcat/Km value for all alcohols studied except methanol and ethylene glycol; kcat values were relatively constant for all isoenzymes acting on all alcohols, and, hence, specificity was manifested principally in the value of Km. Values of Km and kcat/Km revealed for all enzymes examined that the short chain alcohols are the poorest while alcohols with bulky substituents are much better substrates. The experimental values of the kinetic parameters for heterodimers deviate from the calculated average of those of their parent homodimers and, hence, cannot be predicted from the behavior of the latter. Thus, the specificities of both the hetero- and homodimeric isoenzymes of ADH toward a given substrate are characteristics of each. Ethanol proved to be one of the "poorest" substrates examined for all class I isoenzymes which are the predominant forms of the human enzyme. On the basis of kinetic criteria, none of the isoenzymes of class I studied oxidized ethanol in a manner that would indicate an enzymatic preference for that alcohol.     

Molecular evolution of mammalian class I alcohol dehydrogenase

Phylogenetic relationship and the rates of evolution of mammalian alcohol dehydrogenases (ADHs) have been studied by using the amino acid sequences from the human (ADH alpha, ADH beta, and ADH gamma), rat, mouse, and horse (ADH E and ADH S). With the maize ADH1 and ADH2 used as references, the patterns of the amino acid replacements in the beta-sheets, alpha-helices, and random coils in each of the catalytic and coenzyme-binding domains were analyzed separately. The phylogenetic trees based on the different sets of amino acid substitutions consistently showed that (1) multiple ADHs in human and horse have arisen after mammalian radiation, (2) the common ancestor of human ADHs alpha and beta diverged from the ancestor of ADH gamma first and the former two ADHs diverged from each other more recently, and (3) the human ADHs are more closely related to the rodent ADHs than to the horse ADHs. Furthermore, the estimated branch lengths showed that the rodent ADHs are evolving faster than the other ADHs. This difference in evolutionary rate between the two groups of organisms is explainable either in terms of the difference in the number of cell generations per year or in terms of reduction of functional constraints.     

Rat liver alcohol dehydrogenase of class III. Primary structure, functional consequences and relationships to other alcohol dehydrogenases

The amino acid sequence of alcohol dehydrogenase of class III from rat liver (the enzyme ADH-2) has been determined. This type of structure is quite different from those of both the class I and the class II alcohol dehydrogenases. The rat class III structure differs from the rat and human class I structures by 133-138 residues (exact value depending on species and isozyme type); and from that of human class II by 132 residues. In contrast, the rat/human species difference within the class III enzymes is only 21 residues. The protein was carboxymethylated with iodo[2(14)C]acetate, and cleaved with CNBr and proteolytic enzymes. Peptides purified by exclusion chromatography and reverse-phase high-performance liquid chromatography were analyzed by degradation with a gas-phase sequencer and with the manual 4-N,N-dimethylaminoazobenzene-4'-isothiocyanate double-coupling method. The protein chain has 373 residues with a blocked N terminus. No evidence was obtained for heterogeneity. The rat ADH-2 enzyme of class III contains an insertion of Cys at position 60 in relation to the class I enzymes, while the latter alcohol dehydrogenase in rat (ADH-3) has another Cys insertion (at position 111) relative to ADH-2. The structure deduced explains the characteristic differences of the class III alcohol dehydrogenase in relation to the other classes of alcohol dehydrogenase, including a high absorbance, an anodic electrophoretic mobility and special kinetic properties. The main amino acid substitutions are found in the catalytic domain and in the subunit interacting segments of the coenzyme-binding domain, the latter explaining the lack of hybrid dimers between subunits of different classes. Several substitutions provide an enlarged and more hydrophilic substrate-binding pocket, which appears compatible with a higher water content in the pocket and hence could possibly explain the higher Km for all substrates as compared with the corresponding values for the class I enzymes. Finally the class III structure supports evolutionary relationships suggesting that the three classes constitute clearly separate enzymes within the group of mammalian zinc-containing alcohol dehydrogenases.     

Class III human liver alcohol dehydrogenase: a novel structural type equidistantly related to the class I and class II enzymes

The primary structure of class III alcohol dehydrogenase (dimeric with chi subunits) from human liver has been determined by peptide analyses. The protein chain is a clearly distinct type of subunit distantly related to those of both human class I and class II alcohol dehydrogenases (with alpha, beta, gamma, and pi subunits, respectively). Disregarding a few gaps, residue differences in the chi protein chain with respect to beta 1 and pi occur at 139 and 140 positions, respectively. Compared to class I, the 373-residue chi structure has an extra residue, Cys after position 60, and two missing ones, the first two residues relative to class I, although the N-terminus is acetylated like that for those enzymes. The chi subunit contains two more tryptophan residues than the class I subunits, accounting for the increased absorbance at 280 nm. There are also four additional acidic and two fewer basic side chains than in the class I beta structure, compatible with the markedly different electrophoretic mobility of the class III enzyme. Residue differences between class III and the other classes occur with nearly equal frequency in the coenzyme-binding and catalytic domains. The similarity in the number of exchanges relative to that of the enzymes of the other two classes supports conclusions that the three classes of alcohol dehydrogenase reflect stages in the development of separate enzymes with distinct functional roles. In spite of the many exchanges, the residues critical to basic functional properties are either completely unchanged--all zinc ligands and space-restricted Gly residues--or partly unchanged--residues at the coenzyme-binding pocket.(ABSTRACT TRUNCATED AT 250 WORDS)     

Narcan inhibition of human liver alcohol dehydrogenase

Narcan, the pharmaceutical agent for the administration of naloxone, has been reported to antagonize ethanol intoxication. In addition to naloxone, Narcan contains the antioxidant esters methyl- and propylparaben. Pure naloxone and these two esters were examined for their capacity to inhibit ethanol oxidation by purified isozymes of human liver alcohol dehydrogenase (ADH). Naloxone (400 micromolar) fails completely to inactivate any of the three ADH isozyme classes. In contrast, methyl- and propylparaben, and some related esters, competitively inhibit the oxidation of ethanol and reduction of acetaldehyde by all isozymes examined. The reported effects of Narcan on ethanol-intoxicated animals or cells cannot be attributed to the action of naloxone.     

cDNA sequence of human class III alcohol dehydrogenase

A human placental cDNA library was screened using oligonucleotide probes based on the peptide sequence of the human class III alcohol dehydrogenase. An incomplete cDNA clone covering most of the coding sequence of class III alcohol dehydrogenase was isolated from a human placental cDNA library. This was subsequently used as a probe to obtain a full-length clone from a human testicular library. The cDNA sequence codes for a protein that is identical to the enzyme purified from human liver. Southern analysis of human genomic DNA suggests that it may contain more than a single copy per haploid genome.     

Simian liver alcohol dehydrogenase: isolation and characterization of isozymes from Macaca nemestrina

Three classes of hepatic alcohol dehydrogenase (ADH), analogous to those of human liver, are present in Macaca nemestrina. Their functional, compositional, and structural features have been established with isozymes purified to homogeneity by affinity and conventional ion-exchange chromatography. One unusual molecular form of M. nemestrina ADH is electrophoretically indistinguishable as it comigrates with one of the cathodic class I isozymes on starch gel electrophoresis. While its substrate and inhibitor specificity, a high Km value for ethanol (50 mM at pH 10), and lack of binding to the pyrazole affinity resin are consistent with the kinetics of class II ADH, the physiochemical and compositional properties are virtually identical with all other known mammalian alcohol dehydrogenases. The unexpected presence of this previously unknown ADH variant in livers of M. nemestrina demonstrates the need for prudence in assignment of ADH isozymes. Classification based solely on electrophoretic position in starch gels and enzymatic properties of human ADH but without isolation and characterization of individual isozymes may prove insufficient and inadequate. The genetic or phenotypic nature of this isozyme remains to be demonstrated.     

Organ-specific human alcohol dehydrogenase: isolation and characterization of isozymes from testis

Class III alcohol dehydrogenase (ADH) predominates in human testis. The two isozymes of this class were isolated jointly by affinity and conventional ion exchange chromatography. They display anodic electrophoretic mobility at pH 8.2, are completely insensitive to 4-methylpyrazole inhibition and oxidize ethanol and other short-chain primary alcohols very poorly. Thus, their kinetic and inhibition characteristics are identical to human liver class III ADH. In contrast, class I ADH is a barely detectable component of testicular alcohol dehydrogenase. The physicochemical characteristics of class III ADH are virtually identical to those of alcohol dehydrogenases found in other organs.     

Computer-graphics interpretations of residue exchanges between the alpha, beta and gamma subunits of human-liver alcohol dehydrogenase class I isozymes

Three-dimensional models of human alcohol dehydrogenase subunits have been constructed, based on the homologous horse enzyme, with computer graphics. All types of class I subunits (alpha, beta, and gamma) and the major allelic variants (beta 1/beta 2 and gamma 1/gamma 2) have been studied. Residue differences between the E-type subunit of the horse enzyme and any of the subunits of the human isozymes occur at 64 positions, about half of which are isozyme-specific. About two thirds of the substitutions are at the surface and all differences can be accommodated in highly conserved three-dimensional structures. The model of the gamma isozyme is most similar to the crystallographically analyzed horse liver E-type alcohol dehydrogenase, and has all the functional residues identical to those of the E subunit except for one which is slightly smaller: Val-141 in the substrate pocket. The residues involved in coenzyme binding are generally conserved between the horse enzyme and the alpha, beta, and gamma types of the human enzyme. In contrast, single exchanges of these residues are the ones involved in the major allelic differences (beta 1 versus beta 2 and gamma 1 versus gamma 2), which affects the overall rate of alcohol oxidation since NADH dissociation is the rate-determining step. Residue 47 is His in beta 2 and Arg in the beta 1, gamma 1, and gamma 2 subunits, and in horse liver alcohol dehydrogenase. Both His and Arg can make a hydrogen bond to a phosphate oxygen atom of NAD; hence the lower turnover rate of beta 1 apparently derives from a charge effect. The substitution to Gly in the alpha subunit results in one less hydrogen bond in NAD binding, and consequently in rapid dissociation. This may explain why the overall rate is an order of magnitude faster than that of beta 1. The important difference between gamma 1 and gamma 2 is an exchange at position 271 from Arg to Gln which can give a hydrogen bond from Gln in gamma 2 to the adenine of NAD. The tighter binding to gamma 2 can account for the slower overall catalytic rate in this isozyme. The kinetics and interactions of cyclohexanol and benzyl alcohol with the isozymes were judged by docking experiments using an interactive fitting program.(ABSTRACT TRUNCATED AT 400 WORDS)     

Catalytic properties of human liver alcohol dehydrogenase isoenzymes

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.     

Genetic control of alcohol dehydrogenase isozymes in maize

By means of horizontal gel electrophoresis and the zymogram technique, genetic variants and the formation of a hybrid molecule of the enzyme alcohol dehydrogenase (ADH) have been found in Zea mays. Each inbred homozygous stock examined showed two types of ADH isozyme patterns: a fast faint zone and a slower deeply staining zone, both anode-migrating at pH 8.5. The variants found differed in that each of the ADH zones varied in its electrophoretic mobility when compared to its counterpart in the other strain. When appropriate genetic crosses were made, the resulting heterozygotes showed the parental ADH zones, and, in addition, a band of intermediate mobility was formed between the deep-staining ADH bands. However, in the fast-moving zone only the parental isozymes were represented in the heterozygote. The formation of the hybrid molecule and the apparent gene dosage effects support the hypothesis that ADH-2 in maize exists as a dimer, whereas ADH-1 may exist as a monomer.This work was supported by the U.S. Atomic Energy Commission, under contract No. AT(11-1)-1338.