An intergenic alcohol dehydrogenase isozyme in sunflowers

The isozymes of alcohol dehydrogenase (ADH; E.C. 1.1.1.1) in wild and cultivated sunflower (Helianthus annuus) seeds can be resolved electrophoretically into 12 bands. The slowest- and probably the fastest-migrating sets of three are allozymic products of two genes, Adh ₁ and Adh ₂ , each having two alleles, F (for fast) and S (for slow). Evidence from dissociation-recombination experiments utilizing bands excised from starch gels indicates that an intermediately-migrating isozyme is a dimeric intergenic product consisting of ADH-1F and ADH-2S subunits. The hybrid isozyme was unstable in vitro in that its monomers spontaneously dissociated and recombined to produce ADH-1FF and ADH-2SS isozymes. The molecular weights of the hybrid as well as the parental isozymes were estimated at approximately 98,000.Supported by a Graduate School Research grant of the University of Kansas and by NSF grant GB-35853.     

Kinetics and thermodynamics of ethanol oxidation catalyzed by genetic variants of the alcohol dehydrogenase from Drosophila melanogaster and D. simulans

Four naturally occurring variants of the alcohol dehydrogenase enzyme (ADH; EC 1.1.1.1) from Drosophila melanogaster and D. simulans, with different primary structures, have been subjected to kinetic studies of ethanol oxidation at five temperatures. Two amino acid replacements in the N-terminal region which distinguish the ADH of D. simulans from the three ADH allozymes of D. melanogaster generate a significantly different activation enthalpy and entropy, and Gibbs free energy change. The one or two amino acid replacements in the C-terminal region between the ADH allozymes of D. melanogaster do not have such clear-cut effects. All four ADH variants show highly negative activation entropies. Sarcosine oxidation by the ADH-71k variant of D. melanogaster has an activation energy barrier similar to that of ethanol oxidation. Three amino acid differences between the ADH of D. simulans and the ADH-F variant of D. melanogaster influence the kappa cat and kappa cat/Kethm constant by a maximum factor of about 2 and 2.5, respectively, over the whole temperature range. Product inhibition patterns suggest a 'rapid equilibrium random' mechanism of ethanol oxidation by the ADH-71k, and the ADH of D. simulans.     

Redox-elimination reaction catalyzed by yeast alcohol dehydrogenase

Yeast alcohol dehydrogenase (EC 1.1.1.1) catalyzed reduction of N,N-dimethyl-4-nitrosoaniline by NADH. The stoichiometry of reaction, steady-state kinetic parameters, and the pH-profile for this reaction were estimated. On that basis, the minimal mechanism of the above reaction was postulated.     

Thyroid hormones modulate ornithine decarboxylase in the immature rat cerebellum

In this study, we measured ornithine decarboxylase (ODC) activity as a potential parameter to evaluate the response of the developing rat brain to thyroid hormones. In cerebellum, neonatal hyperthyroidism (40 micrograms thyroxine/100 g body weight daily from birth) increased ODC activity at 2 and 5 days of age and then accelerated its developmental decline. Conversely, ODC activity was decreased in 2- and 5-day-old hypothyroid rats (propylthiouracil to the mother), but it was not significantly different from normal thereafter. No significant differences were observed in the forebrain following either treatment. In hypothyroid rat cerebellum, a single injection of triiodothyronine (T3, 100 micrograms/100 g 18 h before sacrifice) increased significantly ODC activity at all ages. A dose-response study showed that 0.5 micrograms T3/100 g is sufficient to obtain maximal stimulation. Finally, administration of antiserum against rat growth hormone had no significant effect on ODC response to T3. These results show that ODC is a useful marker of thyroid state and tissue response in the neonatal rat cerebellum.     

Oxidation and reduction of 4-hydroxyalkenals catalyzed by isozymes of human alcohol dehydrogenase

4-Hydroxyalkenals, natural cytotoxic products of lipid peroxidation, are substrates for human alcohol dehydrogenases (ADH). Class I and II ADHs reduce aliphatic 4-hydroxyalkenals with chain lengths of from 5 to 15 carbons at pH 7 with kcat and Km values comparable to simple aliphatic aldehydes of the same chain length. Class II is particularly effective in the reduction with kcat values as high as 3300 min-1 for 4-hydroxyundecenal. Class III ADH is essentially inactive toward all of these substrates. The class I and II isozymes also catalyze the oxidation of the 4-hydroxy group at pH 10. However, during the reaction, an NAD(+)-dependent irreversible partial inactivation of the alpha beta 1 isozyme is observed which is attributed, with the aid of computer graphics modeling, to selective modification of the alpha subunit. Both ethanol and 1,10-phenanthroline, known to compete with conventional substrates, instantaneously, reversibly, and competitively inhibit 4-hydroxyalkenal reduction and oxidation, indicating that 4-hydroxyalkenals bind at the same site as do conventional substates. The fact that the class II enzyme pi pi-ADH so far is found only in the liver and that the 4-hydroxyalkenals are the best substrates known for this isozyme suggest that it may play a significant role in cellular defenses in the conversion of the cytotoxic aldehydes to the less reactive alcohols.     

Modulation of alcohol dehydrogenase and ethanol metabolism by sex hormones in the spontaneously hypertensive rat. Effect of chronic ethanol administration

In young (4-week-old) male and female spontaneously hypertensive (SH) rats, ethanol metabolic rate in vivo and hepatic alcohol dehydrogenase activity in vitro are high and not different in the two sexes. In males, ethanol metabolic rate falls markedly between 4 and 10 weeks of age, which coincides with the time of development of sexual maturity in the rat. Alcohol dehydrogenase activity is also markedly diminished in the male SH rat and correlates well with the changes in ethanol metabolism. There is virtually no influence of age on ethanol metabolic rate and alcohol dehydrogenase activity in the female SH rat. Castration of male SH rats prevents the marked decrease in ethanol metabolic rate and alcohol dehydrogenase activity, whereas ovariectomy has no effect on these parameters in female SH rats. Chronic administration of testosterone to castrated male SH rats and to female SH rats decreases ethanol metabolic rate and alcohol dehydrogenase activity to values similar to those found in mature males. Chronic administration of oestradiol-17β to male SH rats results in marked stimulation of ethanol metabolic rate and alcohol dehydrogenase activity to values similar to those found in female SH rats. Chronic administration of ethanol to male SH rats from 4 to 11 weeks of age prevents the marked age-dependent decreases in ethanol metabolic rate and alcohol dehydrogenase activity, but has virtually no effect in castrated rats. In the intoxicated chronically ethanol-fed male SH rats, serum testosterone concentrations are significantly depressed. In vitro, testosterone has no effect on hepatic alcohol dehydrogenase activity of young male and female SH rats. In conclusion, in the male SH rat, ethanol metabolic rate appears to be limited by alcohol dehydrogenase activity and is modulated by testosterone. Testosterone has an inhibitory effect and oestradiol has a testosterone-dependent stimulatory effect on alcohol dehydrogenase activity and ethanol metabolic rate in these animals.     

Physical and enzymatic properties of a class II alcohol dehydrogenase isozyme of human liver: pi-ADH

Homogeneous class II alcohol dehydrogenase (pi-ADH) has been isolated from human liver homogenates by chromatography on DE-52 cellulose, 4-[3-[N-(6-amino-caproyl)amino]propyl]pyrazole-Sepharose, SP-Sephadex C-50, and agarose-hexane-AMP, yielding an enzyme that has a significantly higher specific activity and is markedly more stable than that isolated by an earlier procedure. pi-ADH is composed of two identical 40 000-dalton subunits, contains 4 mol of zinc/dimer, and is readily inhibited by metal-chelating agents. The purified enzyme binds two molecules of coenzyme per dimer, exhibits an absorption maximum at 280 nm, epsilon 280 = 57 000, and exhibits an isoelectric point of 8.6. The class II isozyme catalyzes the oxidation of a variety of alcohols with Km values ranging from 7 microM to 560 mM and with kcat values from 32 min-1 to 600 min-1 and demonstrates a preference for hydrophobic substrates. The kcat/Km ratio for ethanol oxidation exhibits a pH maximum at 10.4.     

Physical and enzymatic properties of a class III isozyme of human liver alcohol dehydrogenase: chi-ADH

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.     

Dissociation-recombination of intergenic sunflower alcohol dehydrogenase isozymes and relative isozyme activities

Two unlinked genes, Adh ₁ and Adh ₂, control the production of alcohol dehydrogenase (ADH) in seeds of the annual sunflower (Helianthus annuus). Each gene is polymorphic, having F and S alleles. Starch gel electrophoretic zymograms of the four possible double homozygotes have three bands, representing two homodimers and an intermediately migrating intergenic isozyme. Zymograms of double heterozygotes consist of nine bands produced by ten isozymes: six intragenics and four intergenics, two of which are coincident. Results of dissociation-recombination (D-R) experiments are reported which demonstrate the subunit composition of the intergenic isozymes, thus supporting the relationships suggested by genetic studies. Densitometric tracings of the zymogram of a cleared gel and measurements of activities of homodimer isozymes eluted from gels following D-R of an intergenic isozyme showed that the Adh ₂ isozymes were more than twice as active as those of Adh ₁. Measurements of activities of crude extracts from the four possible double homozygous genotypes indicated that the seeds of the genotype Adh ₁ ^F /Adh ₁ ^F , Adh ₂ ^S /Adh ₂ ^S produced more activity than the other three. This genotype is the most common one found in wild and cultivated stocks. Isozymes eluted following electrophoresis of the same extracts had averages of 19%, 70%, and 11% of total activity contributed by the Adh ₁, Adh₂, and intergenic isozymes, respectively. A simple but efficient method of isozyme elution from starch gels is described which resulted in nearly full expected recovery (approximately 46%) of the ADH activity in the applied sample.Supported by Graduate School and BioMed grants and by NSF Grant GB35853.     

Population genetic studies on aldehyde dehydrogenase isozyme deficiency and alcohol sensitivity

Population genetic studies on aldehyde dehydrogenase polymorphism using hair-root samples were performed on Europeans, Liberians, Sudanese, Egyptians, Kenyans, Vietnamese, Japanese, Indonesians, Chinese, Thais, and South American Indians. A possible correlation between ALDH I deficiency and sensitivity to alcohol in Oriental populations is discussed.     

Effect of intersubunit interaction in horse liver alcohol dehydrogenase on the kinetics of ethanol oxidation]

The kinetics of enzymatic oxidation of ethanol in the presence of alcohol dehydrogenase within a wide range of ethanol and NAD concentrations (pH 6.0--11.5) were studied. It was shown that high concentrations of ethanol (greater than 0.7--5 mM, depending on pH) and NAD (greater than 0.4--0.8 mM) activate alcohol dehydrogenase from horse liver within the pH range of 6.0--7.9. A mechanism of activation based on negative cooperativity of ADH subunits for binding of ethanol and NAD was proposed. The catalytic and Michaelis constants for alcohol dehydrogenase were calculated from ethanol and NAD at all pH values studied. The changes resulting from the subunit cooperativity were revealed. The nature of ionogenic groups of alcohol dehydrogenase, which affect the formation of complexes between the enzyme and NAD and ethanol, and the rate constants for catalytic oxidation of ethanol was assumed. The biological significance of the enzyme capacity for activation by high concentrations of ethanol within the physiological range of pH in the blood under excessive use of alcohol is discussed.     

Thyroid hormones and the reactivities of genetic variants of human erythrocytic glucose-6-phosphate dehydrogenase

Thyroid hormones, throxine (T4) and triiodothyronine (T3) which are known to activate glucose-6-phosphate dehydrogenase (G6PD) activity in vivo act as substrate inhibitors of G6PD in vitro. T4 competitively inhibits NADP in human erythrocyte G6PD variants G6PDA, G6PDB and G6PDA- with inhibition constants of 2.40 +/- 0.90 X 10(-6), 3.44 +/- 0.63 X 10(-6) and 6.53 +/- 0.60 X 10(-6) mol/l, respectively. The inhibition is, however, noncompetitive with respect to G6P in the three variants. T3 also has similar inhibition pattern to T4 with inhibition constants for NADP of 1.9 +/- 0.08 X 10(-5) and 1.28 +/- 0.17 X 10(-5) mol/l for G6PDB and G6PDA-, respectively. cAMP on the other hand inhibits G6P competitively with inhibition constants 1.50 +/- 0.22 X 10(-4), 1.06 +/- 0.24 X 10(-4) and 1.76 +/- 0.14 X 10(-4) mol/l for G6PDB, G6PDA and G6PDA-, respectively. There are significant differences in the inhibition effects of T4 and cAMP with respect to NADP as substrates for the normal enzyme G6PDA or G6PDB and the deficient enzyme G6PDA- when NADP is the substrate, the latter being much more inhibited. The activation effect of thyroid hormones in vivo may therefore not be a direct result of thyroid hormone binding to the G6PD enzyme nor mediated through the action of cAMP but plausibly be through complexation of inhibitory trace metal ions by the thyroid hormones T4 and T3.     

Liver alcohol dehydrogenase and aldehyde dehydrogenase in the Japanese: isozyme variation and its possible role in alcohol intoxication.

Forty autopsy livers from Japanese individuals were studied concerning alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) isozymes using electrophoretic and enzyme assay methods. A remarkably high frequency (85%) was found for the atypical ADH phenotype. The gene frequencies of ADH22 and ADH32 were .625 and .05, respectively. The usual ALDH phenotype showed two major isozyme bands, a faster migrating (low Km for acetaldehyde) and a slower migrating isozyme (high Km for acetaldehyde). Fifty-two percent of the specimens had an unusual phenotype of ALDH, which showed only the slower migrating isozyme. The usual phenotype was inhibited about 20%--30% by disulfiram and the unusual type up to 90%. Such a high incidence in the Japanese of the unusual phenotype, which lacks in the low Km isozyme, suggests that the initial intoxicating symptoms after alcohol drinking in these subjects might be due to delayed oxidation of acetaldehyde rather than its higher-than-normal production by typical or atypical ADH.     

Aldehyde dehydrogenase isozyme deficiency and alcohol sensitivity in four different Chinese populations

Four different populations of China were studied regarding aldehyde dehydrogenase isozyme variation and incidence of alcohol sensitivity. While Korean and Mongolian minorities in the north showed an isozyme I deficiency with a frequency of about 25 and 30%, 45-50% of Zhuang and Han were deficient, respectively. Adverse reactions after alcohol drinking were mainly reported by those subjects who showed the lack of aldehyde dehydrogenase isozyme I.     

乙醇脱氢酶与葡萄糖脱氢酶偶联催化制备(S)-1-(2,6-二氯-3-氟苯基)乙醇

(S)-1-(2,6-二氯-3-氟苯基)乙醇是抗癌药物克唑替尼的手性合成前体,可由2,6-二氯-3-氟苯乙酮经乙醇脱氢酶催化还原制备,还原中所需的还原型辅酶Ⅱ再生是该反应的技术瓶颈.本研究构建重组大肠杆菌E.coli BL21-ADH和E.coli BL21-GDH,实现了葡萄糖脱氢酶和乙醇脱氢酶的共表达,并进行偶联转化.结果表明,当在反应温度为30℃,pH为7的条件下,(S)-l-(2,6-二氯-3-氟苯基)乙醇的产量达到最高,在投料量为6％时,该体系转化率为93.75％.