Class 2 aldehyde dehydrogenase. Characterization of the hamster enzyme, sensitive to daidzin and conserved within the family of multiple forms.

Mitochondrial (class 2) hamster aldehyde dehydrogenase has been purified and characterized. Its primary structure has been determined and correlated with the tertiary structure recently established for this class from another species. The protein is found to represent a constant class within a complex family of multiple forms. Variable segments that occur in different species correlate with non-functional segments, in the same manner as in the case of the constant class of alcohol dehydrogenases (class III type) of another protein family, but distinct from the pattern of the corresponding variable enzymes. Hence, in both these protein families, overall variability and segment architectures behave similarly, with at least one 'constant' form in each case, class III in the case of alcohol dehydrogenases, and at least class 2 in the case of aldehyde dehydrogenases.

The mitochondrial monoamine oxidase-aldehyde dehydrogenase pathway: a potential site of action of daidzin.

Recent studies showed that daidzin suppresses ethanol intake in ethanol-preferring laboratory animals. In vitro, it potently and selectively inhibits the mitochondrial aldehyde dehydrogenase (ALDH-2). Further, it inhibits the conversion of monoamines such as serotonin (5-HT) and dopamine (DA) into their respective acid metabolites, 5-hydroxyindole-3-acetic acid (5-HIAA) and 3,4-dihydroxyphenylacetic acid (DOPAC) in isolated hamster or rat liver mitochondria. Studies on the suppression of ethanol intake and inhibition of 5-HIAA (or DOPAC) formation by six structural analogues of daidzin suggested a potential link between these two activities. This, together with the finding that daidzin does not affect the rates of mitochondria-catalyzed oxidative deamination of these monoamines, raised the possibility that the ethanol intake-suppressive (antidipsotropic) action of daidzin is not mediated by the monoamines but rather by their reactive biogenic aldehyde intermediates such as 5-hydroxyindole-3-acetaldehyde (5-HIAL) and/or 3,4-dihydroxyphenylacetaldehyde (DOPAL) which accumulate in the presence of daidzin. To further evaluate this possibility, we synthesized more structural analogues of daidzin and tested and compared their antidipsotropic activities in Syrian golden hamsters with their effects on monoamine metabolism in isolated hamster liver mitochondria using 5-HT as the substrate. Effects of daidzin and its structural analogues on the activities of monoamine oxidase (MAO) and ALDH-2, the key enzymes involved in 5-HT metabolism in the mitochondria, were also examined. Results from these studies reveal a positive correlation between the antidipsotropic activities of these analogues and their abilities to increase 5-HIAL accumulation during 5-HT metabolism in isolated hamster liver mitochondria. Daidzin analogues that potently inhibit ALDH-2 but have no or little effect on MAO are most antidipsotropic, whereas those that also potently inhibit MAO exhibit little, if any, antidipsotropic activity. These results, although inconclusive, are consistent with the hypothesis that daidzin may act via the mitochondrial MAO/ALDH pathway and that a biogenic aldehyde such as 5-HIAL may be important in mediating its antidipsotropic action.

Synthesis of potential antidipsotropic isoflavones: inhibitors of the mitochondrial monoamine oxidase-aldehyde dehydrogenase pathway.

Recently we have shown that daidzin, the major active principle of an ancient herbal treatment for "alcohol addiction", suppresses ethanol intake in alcohol-preferring laboratory animals. Further, we have identified the monoamine oxidase (MAO)-aldehyde dehydrogenase (ALDH-2) pathway of the mitochondria as the potential site of action of daidzin. Daidzin analogues that potently inhibit ALDH-2 but have no or little effect on MAO are most antidipsotropic, whereas those that also inhibit MAO exhibit little, if any, antidipsotropic activity. Therefore, in the design and synthesis of more potent antidipsotropic analogues, structural features important for the inhibition of both ALDH-2 and MAO must be taken into consideration. To gain further information on the structure-activity relationships at the inhibitor binding sites of ALDH-2 and MAO, we prepared 44 analogues of daidzin and determined their potencies for ALDH-2 and MAO inhibition. Results indicate that a sufficient set of criteria for a potent antidipsotropic analogue is an isoflavone with a free 4'-OH function and a straight-chain alkyl substituent at the 7 position that has a terminal polar function such as -OH, -COOH, or -NH(2). The preferable chain lengths for the 7-O-omega-hydroxy, 7-O-omega-carboxy, and 7-O-omega-amino subsitutents are 2 < or = n < or = 6, 5 < or = n < or = 10, and n > or = 4, respectively. Analogues that meet these criteria have increased potency for ALDH-2 inhibition and/or decreased potency for MAO inhibition and therefore are likely to be potent antidipsotropic agents.

Therapeutic lessons from traditional Oriental medicine to contemporary Occidental pharmacology.

An extract of Radix Puerariae (RP), an herb long used in traditional Chinese medicine for alcohol addiction and intoxication, was shown to suppress the free-choice ethanol intake of ethanol-preferring Syrian golden hamsters. Two isoflavones, diadzein (4',7-dihydroxyisoflavone) and daidzin (7-glucoside of daidzein), isolated from the extract were shown to account for this effect. Daidzin administered intraperitoneally at 150 mg/kg/day suppressed free-choice ethanol intake by > or = 50%. Such effect has been confirmed in a total of 79 consecutive hamsters studied over a period of more than a year. Daidzein was less potent and a higher dose (230 mg/kg/day) was required to produce similar effect. RP-, daidzin-, and daidzein-treated hamsters appeared to remain healthy and exhibited no significant change in body weight and water or food intake. In vitro, daidzin and daidzein inhibited human mitochondrial aldehyde dehydrogenase (ALDH-2) and gamma gamma-alcohol dehydrogenase (gamma gamma-ADH), respectively. However, at doses that suppressed ethanol intake, daidzin and daidzein had no effect on overall acetaldehyde and ethanol metabolism in hamsters. These findings clearly distinguish the action(s) of daidzin and daidzein from those of the classic, broad acting inhibitors of ALDH (e.g. disulfiram) and class I ADH isozymes (e.g. 4-methylpyrazole), and identify them as a new class of compounds that offer promise as safe and effective therapeutic agents for alcohol abuse.

Bovine adrenal 3beta-hydroxysteroid dehydrogenase (E.C. 1.1.1. 145)/5-ene-4-ene isomerase (E.C. 5.3.3.1): characterization and its inhibition by isoflavones.

The isoflavones daidzein, genistein, biochanin A and formononetin inhibit potently and preferentially the gamma-isozymes of mammalian alcohol dehydrogenase (gammagamma-ADH), the only ADH isozyme that catalyzes the oxidation of 3beta-hydroxysteroids. Based on these results, we proposed that these isoflavones might also act on other enzymes involved in 3beta-hydroxysteroid metabolism. Recently, we showed that they indeed are potent inhibitors of a bacterial beta-hydroxysteroid dehydrogenase (beta-HSD). To extend this finding to the mammalian systems, we hereby purified, characterized and studied the effects of isoflavones and structurally related compounds on, a bovine adrenal 3beta-hydroxysteroid dehydrogenase (3beta-HSD). This enzyme catalyzes the oxidation of 3beta-hydroxysteroids but not 3alpha-, 11beta- or 17beta-hydroxysteroids. The same enzyme also catalyzes 5-ene-4-ene isomerization, converting 5-pregnen 3, 20-dione to progesterone. The K(m) values of its dehydrogenase activity determined for a list of 3beta-hydroxysteroid substrates are similar (1 to 2 microM) and that of its isomerase activity, determined with 5-pregnen 3, 20-dione as a substrate, is 10 microM. The k(cat) value determined for its isomerase activity (18.2 min(-1)) is also higher than that for its dehydrogenase activity (1.4-2.4 min(-1)). A survey of more than 30 isoflavones and structurally related compounds revealed that daidzein, genistein, biochanin A and formononetin inhibit both the dehydrogenase and isomerase activity of this enzyme. Inhibition is potent and concentration dependent. IC(50) values determined for these compounds range from 0.4 to 11 microM, within the plasma and urine concentration ranges of daidzein and genistein of individuals on vegetarian diet or semi-vegetarian diet. These results suggest that dietary isoflavones may exert their biological effects by inhibiting the action of 3beta-HSD, a key enzyme of neurosteroid and/or steroid hormone biosynthesis.

Kudzu root: an ancient Chinese source of modern antidipsotropic agents.

Kudzu (Pueraria lobata) is one of the earliest medicinal plants used in traditional Chinese medicine. It has many profound pharmacological actions including antidipsotropic (antialcohol abuse) activity. Although both the roots and flowers of kudzu, Radix and Flos puerariae, respectively, have been used to treat alcohol abuse safely and effectively in China for more than a millennium, their true efficacy, active constituents, sites and mechanisms of action have never been critically examined. Recently, we have demonstrated that a crude extract of Radix puerariae suppresses the free-choice ethanol intake of ethanol-preferring golden Syrian hamsters and have identified two of its isoflavones, daidzin and daidzein, that account for this effect. Since then, we and other investigators have confirmed these findings in rats that were either trained or genetically bred to prefer and consume large amounts of ethanol. This article summarizes recent progress on the pharmacological and biochemical studies of the antidipsotropic isoflavones isolated from Radix puerariae.

The cytolytic effect of cobra cardiotoxin on Ehrlich ascites tumor cells and its inhibition by Ca2+.

In the presence of cobra cardiotoxin, cellular constituents from Ehrlich ascites tumor cells leak out into the medium. The leakage is detrimental to important cell functions. The rate of cardiotoxininduced cytolysis is dose-dependent and is not affected by cell concentration. Calcium ion inhibits the cytolysis reversibly; addition of calcium ion stops the cytolytic action whereas removal of calcium ion by EDTA abolishes the the inhibitory effect. Among the alkaline earth metals studied, Ca2+, Sr2+ and Ba2+ inhibit whereas Mg2+ potentiates the cytolysis. Progression of cytolysis requires a continuous presence of cardiotoxin; removal of cardiotoxin molecules by cardiotoxin antiserum completely abolishes the cytolytic activity. The ability of calcium ion to inhibit cardiotoxin-induced cytolysis is probably due to an interference of the binding of cardiotoxin molecules to the cell membrane.

The effect of pH on the kinetics of iron release from diferric ovotransferrin induced by pyrophosphate.

Pyrophosphate-induced iron release from diferric ovotransferrin follows biphasic kinetics in the pH range from 6.6 to 8.6 except at pH 8.0 where the kinetics become monophasic. The rates of formation of the four molecular species, Fe2OT, FeOTN, FeOTC, and ApoOT, were studied by urea gel electrophoresis and the four microscopic rate constants were calculated at various pH values. Below pH 8.0, these intrinsic rate constants for iron release from Fe2OT follow the order k2N greater than k1N greater than k2C greater than k1C. Each constant diminishes almost proportionally with an increase in pH with the faster rate constants being affected more by the fall in hydrogen ions than the slower ones. Around pH 8.0 the four rates are approximately equal, resulting in monophasic kinetics. However, the rate constants from the C-site become faster than that from the N-site at pH above 8.2. At low pH, there is a marked preference for iron to be released from the N-site rather than from the C-site and such preference becomes less distinct as pH increases. A rather weak positive cooperativity between the two sites is demonstrated in pH between 6.8 and 7.8. The ligand responsible for the transition from biphasic to monophasic kinetics at pH 8.0 is not known. It is possible that there are different anions such as [CO3(2-)] and [HCO3-] at the two iron-binding sites, which might explain the preferential rates of iron release from these sites during protonation.

Metal binding to angiotensin converting enzyme: implications for the metal binding site.

Angiotensin converting enzyme interacts with the chelator, 1,10-phenanthroline (OP) to form an OP-Zn-ACE ternary complex, which subsequently dissociates to OP-Zn and apoenzyme. The association and dissociation rate constants for the reaction OP + Zn-ACE in equilibrium OP-Zn-ACE have been determined and compared with those of known OP-metal complexes. Such constants were also used to calculate the rate constant for formation of the OP-Zn complex from OP-Zn-ACE. The rate of dissociation of zinc from ACE has been measured in the presence of EDTA (which acts only as a metal scavenger) as a function of chelator concentration, at different pH values, and with different buffers. The stability constant for the binding of zinc to apoACE log Kc = 8.2, determined by equilibrium dialysis using atomic absorption spectroscopy to assess metal concentration, is much smaller than that for Zn-carboxypeptidase A. Zn-thermolysin, or Zn-carbonic anhydrase. This weak binding is attributable to the zinc dissociation rate constant of ACE, 7.5 X 10(-3) sec-1 at pH 7.0, which is much greater than that of the other zinc metalloenzymes. These results lead to inferences regarding the metal binding site of ACE.

Kinetics of pyrophosphate induced iron release from diferric ovotransferrin.

The kinetics of pyrophosphate-induced iron release from diferric ovotransferrin were studied spectrophotometrically at 37 degrees C in 0.1 M HEPES, pH 7.0. At high pyrophosphate concentrations, the kinetics are biphasic, indicating that the rates of iron release from the two, presumably noninteracting iron-binding sites of ovotransferrin are different. The pseudo-first-order rate constants for iron release from both the fast and slow sites exhibit a hyperbolic dependence on pyrophosphate concentrations. The data suggest that pyrophosphate forms complexes with the two iron-binding sites of ovotransferrin prior to iron removal. The stability constants of the complex formed with the fast site (Keqf) and slow site (Keqs) are 8.3 M-1 and 40.4 M-1, respectively. The first-order rate constants for the dissociation of ferric-pyrophosphate from the fast site (k2f) and the slow site (k2s) are 0.062 and 0.0044 min-1, respectively. Results from urea gel electrophoresis studies suggest that iron is released at a much faster rate from the N-terminal binding site of ovotransferrin. At high pyrophosphate concentration, only C-monoferric-ovotransferrin is detected during the course of iron release. At low pyrophosphate concentration, however, a detectable amount of N-monoferric-ovotransferrin is accumulated. This result is consistent with the kinetic finding that the site with a higher k2 (0.062 min-1) has a lower affinity toward pyrophosphate (Keq = 8.3 M-1) whereas the site with a lower k2 (0.0044 min-1) has a higher affinity for pyrophosphate (Keq = 40.4 M-1).

Biogenic aldehyde(s) derived from the action of monoamine oxidase may mediate the antidipsotropic effect of daidzin.

Daidzin, a major active principle of an ancient herbal treatment for 'alcohol addiction', was first shown to suppress ethanol intake in Syrian golden hamsters. Since then this activity has been confirmed in Wistar rats, Fawn hooded rats, genetically bred alcohol preferring P rats and African green moneys under various experimental conditions, including two-level operant, two-bottle free-choice, limited access, and alcohol-deprivation paradigms. In vitro, daidzin is a potent and selective inhibitor of mitochondrial aldehyde dehydrogenase (ALDH-2). However, in vivo, it does not affect overall acetaldehyde metabolism in golden hamsters. Using isolated hamster liver mitochondria and 5-hydroxytryptamine (5-HT) and dopamine (DA) as the substrates, we demonstrated that daidzin inhibits the second but not the first step of the MAO/ALDH-2 pathway, the major pathway that catalyzes monoamine metabolism in mitochondria. Correlation studies using structural analogs of daidzin led to the hypothesis that the mitochondrial MAO/ALDH-2 pathway may be the site of action of daidzin and that one or more biogenic aldehydes such as 5-hydroxyindole-3-acetaldehyde (5-HIAL) and/or DOPAL derived from the action of monoamine oxidase (MAO) may be mediators of its antidipsotropic action.

Human liver alcohol dehydrogenases catalyze the oxidation of the intermediary alcohols of the shunt pathway of mevalonate metabolism.

Human liver alcohol dehydrogenase (ADH) catalyzes the oxidation of 3,3-dimethylallyl alcohol, the intermediary alcohol of the shunt pathway of mevalonate metabolism. ADH isozymes differ in their activities toward this alcohol in the order gamma 1 gamma 1 greater than gamma 2 gamma 2 approximately alfa alfa greater pi pi approximately beta 2 beta 2 approximately beta 1 beta 1 much greater than chi chi; kcat/Km values are 1.4 x 10(8), 1.9 x 10(7), 1.4 x 10(7), 5.6 x 10(6), 3.6 x 10(6), 1.6 x 10(6) and 2.5 x 10(3) M-1 min-1, respectively. The intermediary alcohols geraniol and farnesol of the proposed branch pathways of mevalonate metabolism are also oxidized by these isozymes with similar relative efficiencies. The genetic determinants of ADH isozymes may contribute to the observed differences in serum cholesterol levels among and within various populations.

Dietary estrogenic isoflavones are potent inhibitors of beta-hydroxysteroid dehydrogenase of P. testosteronii.

The isoflavones daidzein, genistein, biochanin A and formononetin selectively inhibit the gamma-isozymes of mammalian alcohol dehydrogenase (ADH). Since gamma-ADH is the only ADH isoform that catalyzes 3 beta-hydroxysteroid oxidation, it was conjectured that these isoflavones might also inhibit other enzymes involved in 3 beta-hydroxysteroid metabolism. P. testosteronii beta-hydroxysteroid dehydrogenase (beta-HSD) was used to evaluate this hypothesis. Indeed, all isoflavones that inhibit gamma-ADH were found to be potent inhibitors of beta-HSD. Both the 3 beta- and 17 beta-HSD activities of the enzyme are inhibited. Kinetic analyses with pregnenolone (3-beta-OH) and testosterone (17-beta-OH) as substrates reveal that daidzein and genistein inhibit beta-HSD competitively with respect to the sterol substrates. Their Ki values are very similar and range from 0.013 to 0.02 microM. These results suggest that isoflavones may exert some of their biological effects by modulating activities of enzymes that metabolize steroids critical to hormonal and/or neuronal functions.

Isolation and characterization of three alcohol dehydrogenase isozymes from Syrian golden hamsters.

Electrophoresis of freshly prepared tissue homogenates of the Syrian golden hamster (Mesocricetus auratus) on starch gel followed by activity staining with ethanol as the substrate revealed three major alcohol dehydrogenase (ADH) isozymes. One of these isozymes, TT-ADH, found only in the testes of golden hamsters was previously purified and partially characterized (Keung WM: Biochem. Biophys. Res. Commun. 156:38-45, 1988). The other two, AA- and BB-ADH, which are most abundant in the liver, have now been purified by affinity chromatography on 4-(3-(N-(6-aminocaproyl)amino)propyl)pyrazole-sepharose and testosterone-17 beta-hemisuccinate-agarose. Hamster AA-, BB-, and TT-ADH are all homodimers of molecular weight near 80,000 and each contains 4 atoms of zinc. Amino acid analyses show that BB-ADH is most closely related to the gamma-form of human class I ADH, whereas AA- and TT-ADH are most closely related to the beta-form of the human enzyme. BB-ADH is the only hamster ADH that is active toward sterols and sensitive to testosterone and isoflavone inhibition. These results suggest that hamster BB- and human gamma gamma-ADH also share similar catalytic properties. AA- and TT-ADH are neither active toward sterols nor sensitive to testosterone or isoflavone inhibition; thus, they are functionally different from the human alpha alpha- or gamma gamma-ADHs. Compared with AA- and BB-ADH, TT-ADH exhibits much higher Km values toward primary aliphatic alcohols and cyclohexanol. AA- and BB-ADH share similar substrate specificities toward primary aliphatic alcohols. However, they exhibit different stereospecificities for secondary alcohols. BB-ADH prefers the (R)-(-)-isomer of 2-butanol, whereas AA-ADH prefers the (S)-(-)-isomer. These results further demonstrate that catalytically, hamster BB- and AA-ADH belong to different subfamilies of class I ADH.

Biochemical studies of a new class of alcohol dehydrogenase inhibitors from Radix puerariae.

Two potent, reversible inhibitors of human alcohol dehydrogenase (ADH) isozymes were isolated from Radix puerariae (RP, commonly known as kudzu root) and identified as the isoflavones diadzein and genistein. The 4'-methoxy derivatives of daidzein (trivial name, formononetin) and genistein (biochanin A), minor constituents of RP, were also shown to be ADH inhibitors. All of these isoflavones inhibit the human gamma 2 gamma 2-ADH isozyme competitively with respect to ethanol and uncompetitively with respect to NAD+. A survey of more than 40 structurally related compounds revealed one more isoflavone (prunetin) and four flavones (7-hydroxyflavone, apigenin, galangin, and kaempferol) that inhibit ADH. The isoflavone inhibitors, however, are far more potent than the flavone inhibitors. Among the isoflavones studied, genistein is the most potent with Ki = 0.1 microM toward gamma 2 gamma 2-ADH. Human ADH isozymes differ in their sensitivity to these inhibitors in the order gamma 2 gamma 2-, gamma 1 gamma 1- > alpha alpha-, pi pi- > chi chi-ADH. These inhibitors do not affect the beta 1 beta 1- and beta 2 beta 2-ADH isozymes at concentrations as high as 20 microM. Rat and rabbit class I ADHs are also inhibited by these isoflavone inhibitors. The 7-O-glucosyl derivatives of daidzein, genistein, formononetin, and biochanin A do not inhibit ADH, but are potent aldehyde dehydrogenase inhibitors.

A genuine organ specific alcohol dehydrogenase from hamster testes: isolation, characterization and developmental changes.

Testes of golden hamsters (Mesocricetus auratus) contain a unique form of alcohol dehydrogenase. The enzyme purified to homogeneity is a dimer composed of two identical 41000 dalton subunits and was inhibited by 4-methylpyrazole and 1, 10-phenanthroline. The enzyme prefers primary over secondary alcohol substrates and oxidizes vitamin A (retinol) most efficiently. Its activity in the testis increases during the prepubertal development and such increase is concomitant with, but preceding slightly, the increase in testicular weight and plasma testosterone. These results may implicate the involvement of this enzyme in the development of male hamsters' reproductive system.

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.

Substrate specificity of human class I alcohol dehydrogenase homo- and heterodimers containing the beta 2 (Oriental) subunit.

In order to gain a better understanding of the metabolism of ethanol in Orientals, the kinetic properties of human alcohol dehydrogenase (ADH) isozymes containing the beta 2 (Oriental) subunit, i.e., alpha beta 2, beta 2 gamma 1, beta 2 beta 2, beta 2 gamma 2, as well as gamma 1 gamma 1, were examined by using primary and secondary alcohol substrates of various chain lengths and compared with those of the corresponding beta 1 (Caucasian) subunit containing isozymes already on record [Wagner, F. W., Burger, A. R., & Vallee, B. L. (1983) Biochemistry 22, 1857-1863]. With primary alcohols, these isozymes follow typical Michaelis-Menten kinetics with a preference for long-chain alcohols, as indicated by Km and kcat/Km values. The kcat values obtained with primary alcohols, except methanol, do not vary greatly, i.e., less than 3-fold, whereas the corresponding Km values span a 3600-fold range, i.e., from 26 microM to 94 mM, indicating that the specificity of these isozymes manifests principally in substrate binding. As a consequence, ethanol--which might be thought to be the principal in vivo substrate for ADH--is oxidized rather poorly, i.e., from 50- to 90-fold less effectively than octanol. Secondary alcohol oxidation by the homodimers beta 2 beta 2 and gamma 1 gamma 1 also follows normal Michaelis-Menten kinetics. Again, values of Km and kcat/Km reveal that both isozymes prefer long carbon chains. For all secondary alcohols studied, the Km and kcat values for beta 2 beta 2 are much higher than those for gamma 1 gamma 1, i.e., 25- to 360-fold and 6- to 16-fold, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

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)