Beta 2 (Oriental) human liver alcohol dehydrogenases do not exhibit subunit interaction: oxidation of cyclohexanol by homo- and heterodimers

The steady-state kinetics of isozymes of human liver alcohol dehydrogenase (ADH) containing the beta 2 (Oriental) subunit were investigated in order to confirm the supposition [Fong, W.P., & Keung, W. M. (1987) Biochemistry (preceding paper in this issue)] that the subunits of such heterodimeric ADHs act independently and noncooperatively. The ADH isozymes alpha beta 2, beta 2 beta 2, beta 2 gamma 1, and beta 2 gamma 2 as well as gamma 1 gamma 1 were purified by chromatography on DEAE-cellulose, 4-[3-[N-(6-aminocaproyl)amino]propyl]pyrazole--Sepharose, and CM-cellulose. Their kinetics were studied at pH 9.0 with cyclohexanol since this substrate permits maximal differentiation between activities of the heterodimeric subunits. Oxidation of cyclohexanol by the homodimers beta 2 beta 2 and gamma 1 gamma 1 follows conventional Michaelis-Menten kinetics. The values of Km and kcat determined for beta 2 beta 2 and gamma 1 gamma 1 are 0.11 M and 260 min-1 and 79 microM and 45 min-1, respectively, indicating that beta 2 beta 2, like the previously studied beta 1 beta 1, has an unusually low binding affinity for cyclohexanol compared to that of the ADH isozymes formed by the combination of alpha, gamma 1, and gamma 2 chains. Cyclohexanol oxidation by the heterodimers alpha beta 2, beta 2 gamma 1, and beta 2 gamma 2 follows biphasic kinetics which can be fully accounted for by the individual subunits, one exhibiting a high and the other a low substrate-binding affinity. Eadie-Hofstee plots resolve the biphasic kinetics into two linear components, each of which yields a set of kinetic parameters.(ABSTRACT TRUNCATED AT 250 WORDS)     

The human beta 3 alcohol dehydrogenase subunit differs from beta 1 by a Cys for Arg-369 substitution which decreases NAD(H) binding

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.     

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.     

Kinetic and electrophoretic properties of native and recombined isoenzymes of human liver alcohol dehydrogenase

Ten, electrophoretically distinct, molecular forms of alcohol dehydrogenase have been isolated from a single human liver by affinity and ion-exchange chromatography. The starch gel electrophoresis patterns after the dissociation-recombination of the forms are consistent with the hypothesis that they arise from the random combination of alpha, beta 1, gamma 1, and gamma 2 subunits into six heterodimeric and four homodimeric isoenzymes. Large differences in kinetic properties are observed for the homodimeric isoenzymes, alpha alpha, beta 1 beta 1, gamma 1 gamma 1, and gamma 2 gamma 2. At pH 7.5, the Km value of beta 1 beta 1 for ethanol is 0.049 mM and that of alpha alpha is 4.2 mM. Forms gamma 1 gamma 1 and gamma 2 gamma 2 do not obey Michaelis-Menten kinetics at pH 7.5 but exhibit negative cooperativity with Hill coefficients of 0.54 and 0.55 and [S]0.5 values of 1.0 and 0.63 mM, respectively. However, all isoenzymes display Michaelis-Menten kinetics for ethanol oxidation at pH 10.0 with Km values ranging from 1.5 to 3.2 mM. The maximum specific activity of beta 1 beta 1 is considerably lower than that of the other three homodimers at both pH 7.5 and 10.0. The Km values of the four homodimers for NAD+ at pH 7.5 range from 7.4 to 13 microM and those for NADH, from 6.4 to 33 microM. Ki values for NADH range from 0.19 to 1.6 microM. At pH 7.5, the kinetic properties of alpha alpha and beta 1 beta 1, prepared in vitro from dissociated and recombined alpha beta 1, are similar to those of the native homodimers. The forms gamma 1 gamma 1 and gamma 2 gamma 2, prepared from dissociated and recombined alpha gamma 1 and beta 1 gamma 2, respectively, exhibit negative cooperativity with Hill coefficients that are similar to those seen with the respective native homodimers.     

The role of dissimilar subunits of NAD-specific isocitrate dehydrogenase from pig heart. Evaluation using affinity labeling

NAD-specific isocitrate dehydrogenase from pig heart is composed of three dissimilar subunits present in the native enzyme as 2 alpha:1 beta: 1 gamma, with a tetramer being the smallest form of complete enzyme. The role of these subunits has been explored using affinity labeling. Specifically labeled subunits are separated and then recombined with unmodified subunits to form dimers. Recombination of beta or gamma subunits modified by the isocitrate analogues, 3-bromo-2-ketoglutarate and 3,4-didehydro-2-ketoglutarate, with unmodified alpha subunit led to the same activity in the dimer as when unmodified beta or gamma was combined with alpha. Contrastingly, modification of alpha with these isocitrate analogues led to loss in activity either alone or when recombined with beta or gamma. Hence, the isocitrate site on alpha is required for catalytic activity but the isocitrate sites on beta or gamma are not necessary for the activity of the functional dimer. Reaction of isolated subunits with 3-bromo-2-ketoglutarate shows that alpha and the alpha beta dimer are modified at about the same rate as holoenzyme, suggestive of similarity of the isocitrate site in native enzyme and in isolated active entities containing alpha subunit; in contrast, beta and gamma subunits react more slowly. Modification by the 2',3'-dialdehyde derivative of the allosteric effector, ADP, led to loss of activity in reconstituted dimers, independent of which subunit was modified. Reaction of isolated subunits with the dialdehyde derivative of ADP is slow compared to the initial reaction with native enzyme, indicating differences in the effects of ADP on intact enzyme and subunits. The ADP sites on all subunits may thus be important in intersubunit interactions, which in turn modulate catalytic activity.     

Purification and characterization of glutathione S-transferases of human kidney.

Several forms of glutathione S-transferase (GST) are present in human kidney, and the overall isoenzyme pattern of kidney differs significantly from those of other human tissues. All the three major classes of GST isoenzymes (alpha, mu and pi) are present in significant amounts in kidney, indicating that GST1, GST2 and GST3 gene loci are expressed in this tissue. More than one form of GST is present in each of these classes of enzymes, and individual variations are observed for these classes. The structural, immunological and functional properties of GST isoenzymes of three classes differ significantly from each other, whereas the isoenzymes belonging to the same class have similar properties. All the cationic GST isoenzymes of human kidney except for GST 9.1 are heterodimers of 26,500-Mr and 24,500-Mr subunits. GST 9.1 is a dimer of 24,500-Mr subunits. All the cationic isoenzymes of kidney GST cross-react with antibodies raised against a mixture of GST alpha, beta, gamma, delta and epsilon isoenzymes of liver. GST 6.6 and GST 5.5 of kidney are dimers of 26,500-Mr subunits and are immunologically similar to GST psi of liver. Unlike other human tissues, kidney has at least two isoenzymes (pI 4.7 and 4.9) associated with the GST3 locus. Both these isoenzymes are dimers of 22,500-Mr subunits and are immunologically similar to GST pi of placenta. Some of the isoenzymes of kidney do not correspond to known GST isoenzymes from other human tissues and may be specific to this tissue.     

Purification and steady-state kinetic characterization of human liver beta 3 beta 3 alcohol dehydrogenase

Human liver alcohol dehydrogenase catalyzes the NAD+-dependent oxidation of alcohols. Isoenzymes are produced in liver by five different genes, two of which are polymorphic. We have studied the three beta beta isoenzymes produced at ADH2 because they exhibit very different kinetic properties and they appear with different frequencies in different racial populations. The beta 3 beta 3 isoenzyme which appears in 25% of black Americans was purified to homogeneity, and conditions were found to stabilize this labile isoenzyme. The comparison of substrate specificity among beta beta isoenzymes for primary straight-chain alcohols indicates that there is a positive correlation between Vmax/KM and the log octanol/water partition coefficient for alcohols with beta 2 beta 2 and beta 3 beta 3 but not with beta 1 beta 1. Methyl substitutions at C1 or C2 of these alcohols reduce the catalytic efficiency with all three isoenzymes. The KM and Ki values of beta 3 beta 3 for NAD+ and NADH are substantially higher than values for beta 1 beta 1 or beta 2 beta 2. The Vmax of beta 3 beta 3 ethanol oxidation is 90 times that of beta 1 beta 1. Sequencing of the beta 3 subunit and gene indicates that the polymorphism results from a single amino acid exchange of Cys-369 in beta 3 for Arg-369 in beta 1 and beta 2 [Burnell et al. (1987) Biochem. Biophys. Res. Commun. 146, 1227-1233]. In horse alcohol dehydrogenase and beta 1 beta 1, the guanidino group of Arg-369 is thought to stabilize the NAD(H)-enzyme complex by bonding to one of the pyrophosphate oxygens.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure of three class I human alcohol dehydrogenases complexed with isoenzyme specific formamide inhibitors

Formamides are aldehyde analogues that have demonstrated potent and selective inhibition of human alcohol dehydrogenase isoenzymes. The alphaalpha, beta(1)beta(1), gamma(2)gamma(2), and sigmasigma isoforms have all been found to be strongly inhibited by substituted formamides. In this paper, the structure of the alphaalpha isoform of human alcohol dehydrogenase complexed with N-cyclopentyl-N-cyclobutylformamide was determined by X-ray crystallography to 2.5 A resolution, the beta(1)beta(1) isoform of human alcohol dehydrogenase complexed with N-benzylformamide and with N-heptylformamide was determined to 1.6 and 1.65 A resolution, respectively, and the structure of the gamma(2)gamma(2) isoform complexed with N-1-methylheptylformamide was determined to 1.45 A resolution. These structures provide the first substrate-level view of the local structural differences that give rise to the individual substrate preferences shown by these highly related isoenzymes. Consistent with previous work, the carbonyl oxygen of the inhibitors interacts directly with the catalytic zinc and the hydroxyl group of Thr48 (Ser48 for gamma(2)gamma(2)) of the enzyme. The benzene ring of N-benzylformamide and the carbon chains of N-heptylformamide and N-1-methylheptylformamide interact with the sides of the hydrophobic substrate pocket whose size and shape is dictated by residue exchanges between the beta(1)beta(1) and gamma(2)gamma(2) isoenzymes. In particular, the exchange of Ser for Thr at position 48 and the exchange of Val for Leu at position 141 in the gamma(2)gamma(2) isoenzyme create an environment with stereoselectivity for the R-enantiomer of the branched N-1-methylheptylformamide inhibitor in this isoenzyme. The primary feature of the alphaalpha isoform is the Ala for Phe93 exchange that enlarges the active site near the catalytic zinc and creates the specificity for the branched N-cyclopentyl-N-cyclobutylformamide inhibitor, which shows the greatest selectivity for this unique isoenzyme of any of the formamide inhibitors.     

Identification of human alcohol dehydrogenase isozymes by disc polyacrylamide gel electrophoresis in 7 M urea

Polyacrylamide gel electrophoresis in the presence of 7 M urea provides a simple, reproducible method for the identification of cathodic alcohol dehydrogenase (ADH) isozymes. Treatment of native ADH dimers with 7 M urea and 1 mM dithiothreitol results in a complete dissociation of the 40,000 Mr subunits. Electrophoresis of urea-dissociated ADH isozymes yields a single protein band for homodimers and two bands of equal intensity for heterodimers. The ADH subunits pi, alpha, gamma 2, gamma 1, and beta exhibit electrophoretic mobilities of 0.71, 0.79, 0.88, 0.95, and 1.0, respectively. Thus, the identity of any cathodic ADH isozyme can be determined from the electrophoretic mobilities of its component subunits.     

Genotyping of human alcohol dehydrogenases at the ADH2 and ADH3 loci following DNA sequence amplification

Humans are polymorphic at two of the alcohol dehydrogenase (ADH) loci important in ethanol metabolism, ADH2 and ADH3. Although the coding regions of these genes are 94% identical, they produce subunits that differ greatly in kinetic properties in vitro. These differences are likely to be reflected in the pharmacokinetics of alcohol metabolism, but studies have been hampered by the need to use liver biopsy specimens to determine the ADH phenotype. This problem has now been overcome by determining the genotype at these loci using DNA that has been amplified in vitro by the polymerase chain reaction. We report here the identification of all three of the ADH2 alleles and both of the ADH3 alleles. Any pair of ADH2 or ADH3 alleles can be distinguished using allele-specific oligonucleotide probes directed at their single base pair difference. In addition, ADH2(2) can be distinguished from ADH2(1) and ADH2(3) by detecting a new MaeIII site created in the third exon by the single base pair alteration in ADH2(2).     

Some molecular properties of rat-liver lysosomal beta-glucuronidase isoenzymes.

The isoenzymes of rat-liver lysosomal beta-glucuronidase (beta-D-glucuronide glucuronosohydrolase (EC 3.2.1.31)) were inactivated at different rates at 0 degrees C in 3M guanidinium chloride solutions adjusted to pH 5.0 In 4 M urea buffered by 0.01 M glycylglycine, pH 7.0 isoenzymes I, III, and V were reversibly inhibited 80%. Sodium dodecyl sulfate (SDS), 0.1% in 0.01 M phosphate buffer, pH 7.0 irreversibly inhibited at 37 degrees C all five isoenzymes. Sedimentation analysis showed that loss of catalytic activity in these denaturing media is accompanied by dissociation into slower sedimenting subunits. SDS gel electrophoresis revealed that the isoenzymes are apparently tetramers made up of different proportions of subunits alpha, beta, and gamma having apparent molecular weights of 62,900, 60,200, and 58,700, respectively. The three subunits appear to be glycoproteins.     

Characterization of three isoenzymes of rat alcohol dehydrogenase. Tissue distribution and physical and enzymatic properties

Rat tissues contain three different isoenzymes of alcohol dehydrogenase (ADH) that we have named ADH-1, ADH-2 and ADH-3, ADH-1 is an anodic isoenzyme present in high amounts in the ocular tissues, stomach and lung. ADH-2 is also anodic and has been found in all the rat organs examined. ADH-3 is the group of cathodic ADH forms, mainly present in liver, that has been the subject of the majority of the previous studies on rat ADH. The three isoenzymes have been purified to homogeneity and characterized. All of them have similar physical characteristics: Mr 80,000, with two subunits of Mr 40,000; they contain four atoms of Zn per molecule, and prefer NAD+ as cofactor. Isoelectric points are, however, different: 5.1 for ADH-1, 5.95-6.3 for ADH-2 and 8.25-8.4 for ADH-3. ADH-3 exhibits a Km for ethanol of 1.4 mM, a broad substrate specificity and is strongly inhibited by pyrazole (Ki = 0.4 microM). ADH-2 shows substrate specificity toward long-chain alcohols and aldehydes, cannot be saturated by ethanol and is practically insensitive to pyrazole (Ki = 78.4 mM). ADH-1 has intermediate properties, with a Km for ethanol of 340 mM, a broad substrate specificity and Ki for pyrazole of 0.56 mM. Rat ADH-1, ADH-2 and ADH-3 exhibit many analogies with human ADH classes II, III and I respectively. The specific localization and kinetic properties of rat ADH isoenzymes suggest that ADH-1 and ADH-3 may act as metabolic barriers to external alcohols and aldehydes whereas ADH-2 may have a function in the metabolism of the endogenous long-chain alcohols and aldehydes.     

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)     

Synergistic activation of a family of phosphoinositide 3-kinase via G-protein coupled and tyrosine kinase-related receptors.

Phosphoinositide 3-kinase (PI 3-kinase) is a key signaling enzyme implicated in a variety of receptor-stimulated cell responses. Stimulation of receptors possessing (or coupling to) protein-tyrosine kinase activates heterodimeric PI 3-kinases, which consist of an 85-kDa regulatory subunit (p85) containing Src-homology 2 (SH2) domains and a 110-kDa catalytic subunit (p110 alpha or p110 beta). Thus, this form of PI 3-kinases could be activated in vitro by a phosphotyrosyl peptide containing a YMXM motif that binds to the SH2 domains of p85. Receptors coupling to alpha beta gamma-trimeric G proteins also stimulate the lipid kinase activity of a novel p110 gamma isoform, which is not associated with p85, and thereby is not activated by tyrosine kinase receptors. The activation of p110 gamma PI 3-kinase appears to be mediated through the beta gamma subunits of the G protein (G beta gamma). In addition, rat liver heterodimeric PI 3-kinases containing the p110 beta catalytic subunit are synergistically activated by the phosphotyrosyl peptide plus G beta gamma. Such enzymatic properties were also observed with a recombinant p110 beta/p85 alpha expressed in COS-7 cells. In contrast, another heterodimeric PI 3-kinase consisting of p110 alpha and p85 in the same rat liver, together with a recombinant p110 alpha/p85 alpha, was not activated by G beta gamma, though their activities were stimulated by the phosphotyrosyl peptide. Synergistic activation of PI 3-kinase by the stimulation of the two major receptor types was indeed observed in intact cells, such as chemotactic peptide (N-formyl-Met-Leu-Phe) plus insulin (or Fc gamma II) receptors in differentiated THP-1 and CHO cells and adenosine (A1) plus insulin receptors in rat adipocytes. Thus, PI 3-kinase isoforms consisting of p110 beta catalytic and SH2-containing (p85 or its related) regulatory subunits appeared to function as a 'cross-talk' enzyme between the two signal transduction pathways mediated through tyrosine kinase and G protein-coupled receptors.     

Cellular distribution and developmental expression of AMP-activated protein kinase isoforms in mouse central nervous system

The mammalian AMP-activated protein kinase is a heterotrimeric serine/threonine protein kinase with multiple isoforms for each subunit (alpha, beta, and gamma) and is activated under conditions of metabolic stress. It is widely expressed in many tissues, including the brain, although its expression pattern throughout the CNS is unknown. We show that brain mRNA levels for the alpha2 and beta2 subunits were increased between embryonic days 10 and 14, whereas expression of alpha1, beta1, and gamma1 subunits was consistent at all ages examined. Immunostaining revealed a mainly neuronal distribution of all isoforms. The alpha2 catalytic subunit was highly expressed in neurons and activated astrocytes, whereas the alpha1 catalytic subunit showed low expression in neuropil. The gamma1 noncatalytic subunit was highly expressed by neurons, but not by astrocytes. Expression of the beta1 and beta2 noncatalytic subunits varied, but some neurons, such as granule cells of olfactory bulb, did not express detectable levels of either beta isoform. Preferential nuclear localization of the alpha2, beta1, and gamma1 subunits suggests new functions of the AMP-activated protein kinase, and the different expression patterns and cellular localization between the two catalytic subunits alpha1 and alpha2 point to different physiological roles.     

The concerted nature between three catalytic subunits driving the F1 rotary motor

F(1), a rotational molecular motor, shows strong cooperativity during ATP catalysis when driving the rotation of the central gamma subunit surrounded by the alpha(3)beta(3) subunits. To understand how the three catalytic beta subunits cooperate to drive rotation, we made a hybrid F(1) containing one or two mutant beta subunits with altered catalytic kinetics and observed its rotations. Analysis of the asymmetric stepwise rotations elucidated a concerted nature inside the F(1) complex where all three beta subunits participate to rotate the gamma subunit with a 120 degrees phase. In addition, observing hybrid F(1) rotations at various solution conditions, such as ADP, P(i) and the ATPase inhibitor 2,3-butanedione 2-monoxime (BDM) provides additional information for each elementary event. This novel experimental system, which combines single molecule observations and biochemical methods, enables us to dynamically visualize the catalytic coordination inside active enzymes and shed light on how biological machines provide unidirectional functions and rectify information from stochastic reactions.     

Oxidation of thiodiglycol (2,2'-thiobis-ethanol) by alcohol dehydrogenase: comparison of human isoenzymes

Sulfur mustard is a chemical warfare agent that causes blistering of the skin and damages the eyes and airway after environmental exposure. We have previously reported that thiodiglycol (TDG, 2,2'-bis-thiodiethanol), the hydrolysis product of sulfur mustard, is oxidized by alcohol dehydrogenase (ADH) purified from horse liver or present in mouse liver and human skin cytosol. Humans express four functional classes of ADH composed of several different isozymes, which vary in their tissue distribution, some occurring in skin. To help us evaluate the potential contribution of the various human isozymes toward toxicity in skin and in other tissues, we have compared the catalytic activity of purified human class I alphaalpha-, beta1beta1-, beta2beta2-, and gamma1gamma1-ADH, class II pi-ADH, class III chi-ADH, and class IV sigma-ADH with respect to TDG oxidation and their relative sensitivities to inhibition by pyrazole. Specific activities toward TDG were 123, 79, 347, 647, and 12 nmol/min/mg for the class I alphaalpha-, beta1,beta1-, beta2beta2-, and gamma1gamma1-ADH and class II pi-ADH, respectively. TDG was not a substrate for class III chi-ADH. The specific activity of class IV sigma-ADH was estimated at about 1630 nmol/min/mg. 1 mM pyrazole, a potent inhibitor of class I ADH, inhibited the class I alphaalpha, beta1beta1, beta2beta2, and gamma1gamma1 ADH and class IV sigma-ADH by 83, 100, 56, 90, and 73%, respectively. The class I alphaalpha- and beta1beta1-ADH oxidized TDG with kcat/Km value of 7-8 mM(-1) min(-1), beta2beta2-ADH with a value 19 mM(-1) min(-1) and class I gamma1gamma1-ADH with a value of 176 mM(-1) min(-1). The kcat/Km value for class IV sigma-ADH was estimated at 4 mM(-1) min(-1). The activities of class IV sigma-ADH and class I gamma1gamma1-ADH are of significant interest because of their prevalence in eyes, lungs, stomach, and skin, all target organs of sulfur mustard toxicity.