Alcohol dehydrogenase and adaptation to ethanol in Drosophila

The subject of this research is activity and allozyme spectra of alcohol dehydrogenase (ADH), and survival of mutant strains of Drosophila kept in standard nutrient medium with added ethanol. In all experiments the ADH of flies revealed greater affinity to isopropanol than ethanol. The mutant strains considerably differed from one another and from the wild type of flies in the level of enzyme activity, which may be connected with genotypic properties in the mutants studied. The ADH variability in mutant strains seems to be caused by different alleles of the structural ADH gene, which was established as a result of investigation of activity, electrophoretic mobility and thermostability of corresponding allozymes. As follows from experiments on the genotypical structure of populations in the conditions of fly selection in the medium containing ethanol (10%), the adaptation of flies to exogenous ethanol takes place via mechanisms of allele control of the ADH activity. Phenotypical manifestation of the ADH locus and its effect on the resistance of Drosophila to alcohol are supposed to depend on complex gene interactions determined by the genotype as a whole.     

Activity and substrate specificity of the alcohol dehydrogenases of n-alkane oxidizing yeasts

The activity and substrate specificity of alcohol dehydrogenases (ADH) in the fractions of cytosol and membrane particles were compared in the yeasts Torulopsis candida, Candida lipolytica and Candida tropicalis grown in media with glucose and hexadecane. In all studied yeast cultures growing in the medium with hexadecane, NAD-dependent ADH specifically dehydrogenating only medium and higher alcohols are induced in the membrane structures of the cells. Soluble ADH are found in the cytosol of the cultures grown either on glucose or on hexadecane. These ADH oxidize all alcohols with the carbon chain length from C2 to C16. As was found by electrophoresis in polyacrylamide gel, the number of ADH molecular forms in the cytosol fraction of the cultures depends on the carbon growth substrate being used and the peculiarities of yeast culture.     

Isolation and characterization of aDatura innoxia cell line resistant to ethanol

A cell line ofDatura innoxia was selected in suspension culture to be resistant to 1% (vol/vol) ethanol (EtOH^R). EtOH^R cells were cross-resistant to 1% (vol/vol) methanol and 1% (vol/vol) 2-propanol but not 1% (vol/vol)n-propanol orn-butanol, whereas wild type (WT) cells were resistant only to methanol. Resistance in EtOH^R cells is probably a result of a very low level of alcohol dehydrogenase (ADH) activity which was only 9 to 10% of that in WT cells and was undetectable during much of the EtOH^R growth cycle. In the absence of ethanol, EtOH^R cells have a I₅₀ for the toxic ethanol analog allyl alcohol, which is nearly 3 times higher than that in WT cells. In the presence of ethanol, EtOH^R cells have an I₅₀ for allyl alcohol which is 12 times more than WT cells. This difference correlated well with the decrease in ADH activity found in EtOH^R cells grown on ethanol. When ethanol was removed from the suspension medium, ADH activity in EtOH^R cells gradually increased to WT levels. When re-exposed to ethanol after 200 cell generations, ADH activity quickly decreased and growth resumed after a 4- to 6-day lag period. Lipid analysis showed a 37% increase in total lipid in EtOH^R cells, mostly in polar lipids, di- and triglycerides. The fatty acid composition of these lipid classes was shifted toward the more polyunsaturated. These lipid changes were probably a reflection of the increased plastid number in the EtOH^R cells and may be a result of growth in ethanol rather than a reason for resistance. EtOH^R cells seem to be regulatory mutants able to quickly lower ADH activity in the presence of ethanol.     

Enhanced production of glycerol in an alcohol dehydrogenase (ADH I) deficient mutant of Saccharomyces cerevisiae

Summary A partial alcohol dehydrogenase, ADH I, deficient mutant, GRF 18-2 of S. cerevisiae has been isolated. The mutant is resistant to allyl alcohol and the spec. activity of ADH I is 15-fold reduced in the mutant. In a batch fermentation the mutant overproduces glycerol. The production is enhanced 6–7 fold compared with the wildtype strain and it amounts to about 40 per cent of the ethanol produced. The yield of ethanol and glycerol is 56 and 24 per cent respectively. Another mutant possibly defect in the gene for ADH II has a reduced capacity to oxidize ethanol.     

Genetic sexing in the mediterranean fruit fly,Ceratitis capitata,using the alcohol dehydrogenase locus

Summary Using the alcohol dehydrogenase (ADH) locus a genetic sexing system is being developed in the Mediterranean fruit fly Ceratitis capitata based on the sensitivity of ADH null mutations to environmental ethanol. A series of null mutants have been induced at this locus, however, none proved viable as homozygotes. One of these null mutants was translocated to the male determining chromosome and this line can be used for genetic sexing. When larvae from this line were reared on larval medium containing various concentrations of allyl alcohol, 97% of the emerging adults were males; in the absence of the allyl alcohol the sex ratio in the line is distorted in favour of the females. It is proposed that the higher ADH activity of the females (homozygous positive) in comparison with the males (heterozygous null) is responsible for their lower survival in larval medium containing allyl alcohol. ADH converts the allyl alcohol to the lethal ketone. The possible use of this line to sex large populations of medflies for use in sterile insect release programmes is discussed.     

Alcohol dehydrogenase (ADH) in yeasts. II. NAD+-and NADP+-dependent alcohol dehydrogenases in Saccharomycopsis lipolytica.

In Sm. lipolytica one NAD+-dependent and three NADP+-dependent alcohol dehydrogenases are detectable by polyacrylamide gelelectrophoresis. The NAD+-dependent ADH (ADH I), with a molecular weight of 240,000 daltons, reacts more intensively with long-chain alcohols (octanol) than with short-chain alcohols (methanol, ethanol). The ADH I is not or only minimally subject to glucose repression. Besides the ADH I band no additional inducible NAD+-dependent ADH band is gel-electrophoretically detectable during growth of yeast cells in medium containing ethanol or paraffin. The ADH I band is very probably formed by two ADH enzymes with the same electrophoretic mobility. The NADP+-dependent alcohol dehydrogenases (ADH II--IV) react with methanol, ethanol and octanol with different intensity. In polyacrylamide gradients two bands of NADP+-dependent ADH are detectable: one with a molecular weight of 70,000 daltons and the other with 120,000 daltons. The occurrence of the three NADP+-dependent alcohol dehydrogenases is regulated by the carbon source of the medium. Sm. lipolytica shows a high tolerance against allylalcohol. Resistant mutants can be isolated only at concentrations of 1 M allylalcohol in the medium. All isolates of allylalcohol-resistant mutants show identical growth in medium containing ethanol as the wild type strain.     

Sex differences, alcohol dehydrogenase, acetaldehyde burst, and aversion to ethanol in the rat: a systems perspective

Individuals who carry the most active alcohol dehydrogenase (ADH) isoforms are protected against alcoholism. This work addresses the mechanism by which a high ADH activity leads to low ethanol intake in animals. Male and female ethanol drinker rats (UChB) were allowed access to 10% ethanol for 1 h. Females showed 70% higher hepatic ADH activity and displayed 60% lower voluntary ethanol intake than males. Following ethanol administration (1 g/kg ip), females generated a transient blood acetaldehyde increase ("burst") with levels that were 2.5-fold greater than in males (P < 0.02). Castration of males led to 1) an increased ADH activity (+50%, P < 0.001), 2) the appearance of an acetaldehyde burst (3- to 4-fold vs. sham), and 3) a reduction of voluntary ethanol intake comparable with that of na?ve females. The ADH inhibitor 4-methylpyrazole blocked the appearance of arterial acetaldehyde and increased ethanol intake. Since the release of NADH from the ADH.NADH complex constitutes the rate-limiting step of ADH (but not of ALDH2) activity, endogenous NADH oxidizing substrates present at the time of ethanol intake may contribute to the acetaldehyde burst. Sodium pyruvate given at the time of ethanol administration led to an abrupt acetaldehyde burst and a greatly reduced voluntary ethanol intake. Overall, a transient surge of arterial acetaldehyde occurs upon ethanol administration due to 1) high ADH levels and 2) available metabolites that can oxidize hepatic NADH. The acetaldehyde burst is strongly associated with a marked reduction in ethanol intake.     

Isolation of alcohol dehydrogenases from germinating seeds of pea,broad-bean,lentil and kidney-bean

The maximum of alcohol dehydrogenase (ADH) activity of germinating pea and broad-bean seeds sediments from 40 to 60% ammonium sulfate saturation, from lentil and kidney-bean seeds between 40 and 50%. This operation increased the specific activity of ADH preparations roughly tenfold. Chromatography on DEAE-eellulose and gel filtration increased the activity of the resulting preparation when compared with the initial preparation 178 times with pea, 334 times with broad-bean, 122 times with lentil and 77 times with kidney-bean. The ADHs resemble each other in coenzyme specificity: the reaction rate with NAD is one hundred times greater than with NADP. The substrate specificity is quite wide: besides ethanol, these enzymes oxidize 2-propene-l-ol (actually faster than ethanol), 2-butene-l-ol (at the rate of one half t h a t of ethanol) and butanol (even more slowly). In general, saturated alcohol analogues are oxidized more slowly than unsaturated ones. Methanol is a substrate for the enzym from pea only. The ADHs of the plants studied did not oxidize diols, sugar alcohols and cyclic alcohols. The enzyme from pea has the widest substrate specificity oxidizing isobutanol, phenylalcohol and mercaptoethanol. ADHs, which are widely encountered in plants, resemble each other to a certain degree — they have identical coenzymes, equal K_m values and equal values of the pH optimum, they differ in the purification process and in substrate specificity.     

Developmental and environmental influences in the production of a single NAD-dependent fermentative alcohol dehydrogenase by the zygomycete Mucor rouxii

A soluble NAD-dependent alcohol dehydrogenase (ADH) activity was detected in mycelium and yeast cells of wild-type Mucor rouxii. In the mycelium of cells grown in the absence of oxygen, the enzyme activity was high, whereas in yeast cells, ADH activity was high regardless of the presence or absence of oxygen. The enzyme from aerobically or anaerobically grown mycelium or yeast cells exhibited a similar optimum pH for the oxidation of ethanol to acetaldehyde (∼pH 8.5) and for the reduction of acetaldehyde to ethanol (∼pH 7.5). Zymogram analysis conducted with cell-free extracts of the wild-type and an alcohol-dehydrogenase-deficient mutant strain indicated the existence of a single ADH enzyme that was independent of the developmental stage of dimorphism, the growth atmosphere, or the carbon source in the growth medium. Purified ADH from aerobically grown mycelium was found to be a tetramer consisting of subunits of 43 kDa. The enzyme oxidized primary and secondary alcohols, although much higher activity was displayed with primary alcohols. K _m values obtained for acetaldehyde, ethanol, NADH₂, and NAD⁺ indicated that physiologically the enzyme works mainly in the reduction of acetaldehyde to ethanol. Received: 11 March 1999 / Accepted: 14 July 1999     

Purification and properties of alcohol dehydrogenase from the acid- and ethanol-tolerant yeast Candida solicola

Two alcohol dehydrogenases (EC 1.1.1.1) from the acid- and ethanol-tolerant yeast Candida solicola WY-1 have been purified and characterized. The microbial strain cultured in a medium containing ethanol as a sole carbon source was disrupted in a Dyno-mill. From the cell-free extract obtained by centrifugation at 105,000 × g for 60 min, two alcohol dehydrogenases (ADH 1, ADH 2) were separated by DEAE-Toyopearl 650 M chromatography. ADH 1 was further purified by affinity chromatography using Matrex Blue A, ADH 2 was purified by chromatofocusing using Polybuffer Exchanger (PBE) 94 and affinity chromatography using Matrex Blue A. ADH 1 and ADH 2 had the same optimum pH, 7.0. ADH 1 was stable between pH 7.0 and 7.5, and ADH 2 at pH 7.0. The molecular weights of ADH 1 and ADH 2 were calculated to be about 160,000 and 162,000, while the isoelectric points were 5.3 and 5.25, respectively. The optimum temperature of ADH 1 was 30°C, while that of ADH 2 was 55°C. ADH 1 was stable at temperatures below 50°C, whereas ADH 2 was unstable at temperatures above 25°C.     

Effects of differential alcohol dehydrogenase activity on the developmental toxicity of ethanol in Drosophila melanogaster

The role of alcohol dehydrogenase (ADH) activity in ethanol toxicity was investigated in Drosophila melanogaster. Flies from three congenic Adh strains (high, medium, and low ADH activity) were allowed to deposit eggs on medium containing 0, 4, or 8% ethanol. The resulting larvae were allowed to complete their development in the medium, and emerging flies were examined for defects. Flies with high ADH activity had malformation incidences of 0.8, 2.4, and 5.2% at 0, 4, and 8% ethanol, respectively. The comparable incidences for the low ADH strain were 1.0, 4.1, and 8.4%, while those for the medium ADH strain were intermediate in value. These results indicate that ethanol teratogenesis may be inversely related to ADH activity. When larvae were treated with ethanol for different lengths of time during development, the incidence of defects in flies from the high ADH strain was 3.9% when exposure started at the first instar and 3.09% when exposure started at the third instar. Results of the same exposures for the intermediate ADH strain were 5.2 and 3.4%, respectively, while those for the low ADH strain were 6.9 and 5.5%, respectively. Thus, length of ethanol exposure was directly related to the increased incidence of malformations in all tested Drosophila strains. For all tested strains, defect incidences appeared to be dose-related as well, regardless of length of exposure. ADH in Drosophila has a dual function and thus can catalyze oxidation of both ethanol and its toxic metabolite, acetaldehyde. This suggests that ethanol is the proximate teratogen in Drosophila.     

Variation in amount of enzyme protein in natural populations

Among strains of Drosophila melanogaster each derived from a single fertilized female taken from natural populations, there is variation in both alcohol dehydrogenase (ADH) activity and the amount of ADH protein. The correlation between ADH activity and number of molecules over all strains examined is 0.87 or 0.96 in late third instar larvae depending on whether the substrate is 2-propanol or ethanol. With respect to the two common electrophoretic allozymic forms, F and S, segregating in these populations, the FF strains on the whole have higher ADH activities and numbers of ADH molecules than the SS strains. Over all strains examined, enzyme extracts from FF strains have a mean catalytic efficiency per enzyme molecule higher than that of enzyme extracts from SS strains when ethanol is the substrate, and much higher when 2-propanol is the substrate. One FF strain had an ADH activity/ADH protein ratio characteristic of SS strains.     

Variations of alcohol dehydrogenase activity and fermentative pyruvate,ethanol production of F. equiseti and F. acuminatum depend on the yeast extract and urea concentrations

In this study, pyruvate production of Fusarium equiseti was significantly increased when the yeast extract concentration was raised from 5 to 25 g/L while it was increased to only up to 10 g/L yeast extract in F. acuminatum. Upon supplementation with urea as an alternative nitrogen source, production of pyruvate for both of the Fusarium species were decreased with respect to increase in urea concentration in medium. On the other hand, ethanol production and alcohol dehydrogenase activity of F. equiseti were decreased approximately 1.9- and 1.6-fold with an increase in yeast concentration from 5 to 25 whereas the levels of F. acuminatum were increased 2.3- and 1.8-fold, respectively. In addition, ethanol productions and ADH activities in F. equiseti and F. acuminatum significantly increased on the 12th day up to 15 and 25 g/L urea concentrations, respectively. However, they were significantly decreased under these conditions at higher nitrogen sources. In addition, ethanol production and alcohol dehydrogenase activity in urea supplemented medium were higher than yeast extract supplemented. The results may suggest that the pyruvate, ethanol production and ADH enzyme activity variations and balance between aerobic and anaerobic respiration in F. equiseti and F. acuminatum were effected from yeast extract and urea concentrations in the nutrient medium.     

Colloidal bismuth subcitrate and omeprazole inhibit alcohol dehydrogenase mediated acetaldehyde production by Helicobacter pylori

We have recently shown that Helicobacter pylori possesses marked alcohol dehydrogenase (ADH) activity and is capable - when incubated with an ethanol containing solution in vitro - of producing large amounts of acetaldehyde. In the present study we report that some drugs commonly used for the eradication of H. pylori and for the treatment of gastroduodenal diseases are potent ADH inhibitors and, consequently, effectively prevent bacterial oxidation of ethanol to acetaldehyde. Colloidal bismuth subcitrate (CBS), already at a concentration of 0.01 mM, inhibited H. pylori ADH by 93% at 0.5 M ethanol and decreased oxidation of 22 mM ethanol to acetaldehyde to 82% of control. At concentrations above 5 mM, CBS almost totally inhibited acetaldehyde formation. Omeprazole, a drug also known to suppress growth of H. pylori, also inhibited H. pylori ADH and suppressed bacterial acetaldehyde formation significantly to 69% of control at a drug concentration of 0.1 mM. By contrast, the H₂-receptor antagonists ranitidine and famotidine showed only modest effect on bacterial ADH and acetaldehyde production. We suggest that inhibition of bacterial ADH and a consequent suppression of acetaldehyde production from endogenous or exogenous ethanol may be a novel mechanism by which CBS and omeprazole exert their effect both on the growth of H. pylori as well as on H. pylori associated gastric injury.     

A new alcohol dehydrogenase, reactive towards methanol, from Bacillus stearothermophilus.

An NAD+-dependent alcohol dehydrogenase (ADH) was purified to homogeneity from an aerobic strain of Bacillus stearothermophilus, DSM 2334 (ADH 2334), and compared with the ADH from B. stearothermophilus NCA 1503 (ADH 1503). When an antibody raised against ADH 2334 was used, no cross-reactivity with ADH 1503 was observed on Western blots; by means of an enzyme-linked-immunoabsorbent-assay ('e.l.i.s.a.') procedure, it was found that ADH 1503 had less than 6% of the antigenic activity of ADH 2334. Amino acid analyses detected very small differences in composition, equivalent to about 40 sequence changes, between the two enzymes. The new enzyme has the same six-amino-acid N-terminal sequence as ADH 1503. ADH 2334, but not ADH 1503, is reactive towards methanol; both enzymes can oxidize ethanol, propan-1-ol, butan-1-ol and butan-2-ol. The new enzyme has a distinctive pH optimum at pH 5.5-6 and has significantly lower KEthanolm and kEthanolcat. values than those of ADH 1503. From steady-state kinetic parameters of the reaction with ethanol, propan-1-ol and butan-1-ol, it was shown that ADH 2334 has an ordered mechanism in both directions, with NAD+ being the compulsory first substrate in alcohol oxidation and NADH release being the rate-limiting step. ADH 1503 has an ordered addition of NAD+ and alcohol, but NADH release is not rate-limiting.     

Novel mitochondrial alcohol metabolizing enzymes of <Emphasis Type="Italic">Euglena gracilis</Emphasis>

Ethanol is one of the most efficient carbon sources for Euglena gracilis. Thus, an in-depth investigation of the distribution of ethanol metabolizing enzymes in this organism was conducted. Cellular fractionation indicated localization of the ethanol metabolizing enzymes in both cytosol and mitochondria. Isolated mitochondria were able to generate a transmembrane electrical gradient (Δψ) after the addition of ethanol. However, upon the addition of acetaldehyde no Δψ was formed. Furthermore, acetaldehyde collapsed Δψ generated by ethanol or malate but not by D-lactate. Pyrazole, a specific inhibitor of alcohol dehydrogenase (ADH), abolished the effect of acetaldehyde on Δψ, suggesting that the mitochondrial ADH, by actively consuming NADH to reduce acetaldehyde to ethanol, was able to collapse Δψ. When mitochondria were fractionated, 27% and 60% of ADH and aldehyde dehydrogenase (ALDH) activities were found in the inner membrane fraction. ADH activity showed two kinetic components, suggesting the presence of two isozymes in the membrane fraction, while ALDH kinetics was monotonic. The ADH Km values were 0.64–6.5 mM for ethanol, and 0.16–0.88 mM for NAD⁺, while the ALDH Km values were 1.7–5.3 μM for acetaldehyde and 33–47 μM for NAD⁺. These novel enzymes were also able to use aliphatic substrates of different chain length and could be involved in the metabolism of fatty alcohol and aldehydes released from wax esters stored by this microorganism.     

乙醇脱氢酶（ADH）产酶菌株的选育

从食醋生产企业的醋醅中采集样品,以乙醇为唯一碳源,用碳酸钙透明圈平板法分离出185株菌株,然后以产酸量和耐乙醇能力为标准,瓶发酵选育出20株ADH产酶菌株;A5-2产酸量为49.85 g/L,耐乙醇能力强,A5-2的菌种形态学和16S rDNA序列分析初步鉴定为巴斯德醋酸杆菌（ Acetobacter pasteurianus）;A5-2乙醇脱氢酶酶学性质研究表明：最适作用温度和pH分别为45℃和pH 4.0,具有一定的耐热性和良好的耐酸碱性;A5-2乙醇脱氢酶粗酶制备条件为硫酸铵饱和度70%~80%,回收率84%。     

New human liver alcohol dehydrogenase forms with unique kinetic characteristics

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