Alcohol dehydrogenase polymorphism inDrosophila: Enzyme kinetics of product inhibition

Summary Because natural populations ofDrosophila melanogaster are polymorphic for different allozymes of alcohol dehydrogenase (ADH) and becauseD. melanogaster is more tolerant to the toxic effects of ethanol than its sibling speciesD. simulans, information regarding the sensitivities of the different forms of ADH to the products of ethanol degradation are of ecological importance. ADH-F, ADH-S, ADH-71k ofD. melanogaster and the ADH ofD. simulans were inhibited by NADH, but the inhibition was relieved by NAD⁺. The order of sensitivity of NADH was ADH-F<ADH-71k, ADH-S<ADH-simulans with ADH-F being about four times less sensitive than theD. melanogaster enzymes and 12 times less sensitive than theD. simulans enzyme. Acetaldehyde inhibited the ethanolto-acetaldehyde activity of the ADHs, but at low acetaldehyde concentrations ethanol and NAD⁺ reduced the inhibition. ADH-71k and ADH-F were more subject to the inhibitory action of acetaldehyde than ADH-S and ADH-simulans, with ADH-71k being seven times more sensitive than ADH-S. The pattern of product inhibition of ADH-71k suggests a rapid equilibrium random mechanism for ethanol oxidation. Thus, although the ADH variants only differ by a few amino acids, these differences exert a far larger impact on their intrinsic properties than previously thought. How differences in product inhibition may be of significance in the evolution of the ADHs is discussed.     

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.     

An association between ADH protein levels and polymorphic nucleotide variation in the Adh gene of Drosophila melanogaster.

Southern analysis of the Adh region of 212 Drosophila melanogaster lines collected from the Tahbilk winery revealed linkage disequilibrium between a 37-bp insertion [designated delta 2 by Kreitman (1983)] and the fast electrophoretic variant of alcohol dehydrogenase (ADH-F). Among these lines 34% contained the insert and encoded ADH-F, 33.5% encoded ADH-F and did not have the insert, and 32.5% encoded the slow electrophoretic variant of alcohol dehydrogenase (ADH-S). Strong linkage association between this insert and ADH-F is evident worldwide. Twenty-nine of the second chromosome lines were characterized for ADH protein quantity by using radial immunodiffusion. ADH quantity was estimated in both larvae and adult males raised in the presence and absence of alcohol supplement to each of two different food media. Analyses of variance indicated higher levels of ADH protein in larvae from lines with the insert (all ADH-F), compared with those without (both ADH-F and ADH-S), independent of either dietary alcohol or media type. No such difference in ADH quantity between insert- and noninsert-containing ADH-F lines was detected in adults, although the expected higher levels occurred in ADH-F lines compared with ADH-S lines. Given the high levels of linkage disequilibrium in the Adh region, these data suggest that either polymorphic nucleotide-site variants positively associated with delta 2 on the second chromosome or delta 2 itself increases larval levels of ADH protein.     

Analysis of the gene encoding the multifunctional alcohol dehydrogenase allozyme ADH-71k of Drosophila melanogaster

The nucleotide sequence of the alcohol dehydrogenase gene Adh71k has been determined. The Adh71k allele encodes the thermostable and multifunctional ADH-71k allozyme of Drosophila melanogaster. Comparison with the sequences of AdhS, AdhF, and AdhFChD reveals differences in the coding and noncoding regions of the gene. Conceptual translation of the Adh71k sequence indicates that ADH-71k shares with ADH-F and ADH-FCHD an amino acid replacement at residue 192 and with ADH-FCHD an additional replacement of serine for proline at residue 214. Three unique differences were found in the nontranslated regions. It is proposed that a nucleotide deletion in the adult intron is related to the difference in expression level of the Adh71k allele, relative to the other alleles. An insertion of five nucleotides, additional to a single base deletion at that site, was detected in one of the larval enhancer regions in the 5' flanking region of the Adh71k allele, creating a palindromic structure in that area.     

ADH enzyme activity and Adh gene expression in Drosophila melanogaster lines differentially selected for increased alcohol tolerance

In Drosophila melanogaster, alcohol dehydrogenase (ADH) activity is essential for ethanol tolerance, but its role may not be restricted to alcohol metabolism alone. Here we describe ADH activity and Adh expression level upon selection for increased alcohol tolerance in different life-stages of D. melanogaster lines with two distinct Adh genotypes: Adh(FF) and Adh(SS). We demonstrate a positive within genotype response for increased alcohol tolerance. Life-stage dependent selection was observed in larvae only. A slight constitutive increase in adult ADH activity for all selection regimes and genotypes was observed, that was not paralleled by Adh expression. Larval Adh expression showed a constitutive increase, that was not reflected in ADH activity. Upon exposure to environmental ethanol, sex, selection regime life stage and genotype appear to have differential effects. Increased ADH activity accompanies increased ethanol tolerance in D. melanogaster but this increase is not paralleled by expression of the Adh gene.     

The effect of temperature on biochemical and molecular properties ofDrosophila alcohol dehydrogenase

The gene products of the two major alleles of alcohol dehydrogenase (ADH-F and ADH-S) have been subjected to kinetic and biochemical analyses over a range of temperatures. Although temperature was found to have a significant effect on both kinetic and biochemical properties of Drosophila ADH, no significant differential effect was observed between the major ADH allozymes. The results are discussed within the context of the selective maintenance of Adh polymorphism in natural populations.     

Deletion of a conserved regulatory element in the Drosophila Adh gene leads to increased alcohol dehydrogenase activity but also delays development

In vivo levels of enzymatic activity may be increased through either structural or regulatory changes. Here we use Drosophila melanogaster alcohol dehydrogenase (ADH) in an experimental test for selective differences between these two mechanisms. The well-known ADH-Slow (S)/Fast (F) amino acid replacement leads to a twofold increase in activity by increasing the catalytic efficiency of the enzyme. Disruption of a highly conserved, negative regulatory element in the Adh 3' UTR also leads to a twofold increase in activity, although this is achieved by increasing in vivo Adh mRNA and protein concentrations. These two changes appear to be under different types of selection, with positive selection favoring the amino acid replacement and purifying selection maintaining the 3' UTR sequence. Using transgenic experiments we show that deletion of the conserved 3' UTR element increases adult and larval Adh expression in both the ADH-F and ADH-S genetic backgrounds. However, the 3' UTR deletion also leads to a significant increase in developmental time in both backgrounds. ADH allozyme type has no detectable effect on development. These results demonstrate a negative fitness effect associated with Adh overexpression. This provides a mechanism whereby natural selection can discriminate between alternative pathways of increasing enzymatic activity.     

Gene-enzyme system of alcohol dehydrogenase and adaptation of Drosophila to increased temperature]

Properties and allelic ADH (alcohol dehydrogenase) control in Drosophila melanogaster were studied upon flies' cultivation under conditions of hypotherm of different intensity and duration. Lines homozygotic for F allele (vg) and S allele (cn) of the Adh gene as well as genetically enriched experimental cn' and vg' populations containing a small number of AdhF/AdhS heterozygotes at the initial stage were used. It was found out that physiological adaptation of the species to momentary influence of elevated temperature is accompanied by modification of physical properties of ADH-F according to ADH-S. Constant influence (during the life span of 25 generations) of elevated temperature on the population changes its genetic structure, due to selective advantages of the S allele of Adh under these conditions.     

An electrophoretically cryptic alcohol dehydrogenase variant in Drosophila melanogaster. I. Activity ratios, thermostability, genetic localization and comparison with two other thermostable variants

The alcohol dehydrogenase (ADH) variant ADH-FCh.D. has a secondary alcohol/primary alcohol activity ratio characteristic of ADH-S although it has an electrophoretic mobility inseparable from ADH-F. ADH-FCh.D. is distinguished from these two common ADH variants by being much more thermostable. Genetic analysis suggests tht ADH-FCh.D. is specified by an allele at the Adh locus. Biochemical comparisons show that ADH-FCh.D. has the same electrophoretic mobility, activity ratio and thermostability as the two other heat-resistant variants which have been reported, ADH-F71K in Europe and ADH-Fr in North America. The geographically widespread distribution of a thermostable ADH variant within the ADH-F electrophoretic class indicates that it should be considered in attempts to explain the Adh polymorphism in natural populations.     

A MULTILEVEL APPROACH TO THE SIGNIFICANCE OF GENETIC VARIATION IN ALCOHOL DEHYDROGENASE OF DROSOPHILA

Prior studies showed that differences in alcohol dehydrogenase (ADH) activity across genotypes of Drosophila are decisive for the outcome of selection by ethanol. In the present paper, the effect on ADH activity and egg-to-adult survival of combinations of ethanol, propan-2-ol, and acetone in naturally occurring concentrations is examined. Propan-2-ol is converted into acetone by ADH in vitro. Acetone is considered a competitive inhibitor of ethanol for the ADH enzymes. The melanogaster-ADH-S allozyme is two times more sensitive towards inhibition by acetone than either simulans-ADH or melanogaster-ADH-F. The physiological implications of these in vitro differences for larvae were studied in short-term in vivo and long-term exposure experiments. No major differences in acetone accumulation or fitness parameters were found between the strains in response to ecologically relevant concentrations of acetone or propan-2-ol. Ethanol, however, strongly decreased egg-to-pupal survival in both Drosophila simulans strains and increased developmental time in four out of the five strains tested. Therefore, under physiological conditions only ethanol was shown to act as a selective agent on the ADH polymorphism during egg-to-pupa development in Drosophila.     

Variability of Alcohol Dehydrogenase Activity in a Natural Population of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

MANY natural populations of Drosophila melanogaster are polymorphic for genetically determined electrophoretic variants of the enzyme alcohol dehydrogenase (ADH). Two alleles have been found, ADH-S (the slow variant) and ADH-F (the fast variant)¹ and crude extracts of ADH-F homozygotes typically have a higher enzyme activity than extracts from ADH-S homozygotes^{2, 3}.     

Differential regulation of duplicate alcohol dehydrogenase genes in Drosophila mojavensis

These studies report the existence of multiple forms of alcohol dehydrogenase in extracts of Drosophila mojavensis. The existence of these forms can be best explained by the hypothesis of a duplication for the Adh locus in D. mojavensis. Electrophoretic variants at each locus have been identified and crosses between individuals carrying alternative alleles at each locus result in F1 progeny with six bands of ADH. This pattern is consistent with these individuals being heterozygous at two loci. The loci have been named Adh-1 and Adh-2. Examination of the isozyme content during development shows that the two Adh genes are not coordinately controlled but have separate developmental programs. In embryos and first and second instar larvae only Adh-1 is expressed. At about the time of the second molt Adh-2 expression commences in some of the same cells that previously expressed and continue to express Adh-1. This is evidenced by the existence of an interlocus heterodimer in third instar larvae. Both genes are expressed throughout pupation. Shortly after emergence Adh-1 expression declines. In mature males only ADH-2 is present. In mature females both Adh-1 and Adh-2 are expressed but not in the same cells since the interlocus heterodimer is absent. Examination of specific tissues reveals that most of the larval ADH is found in fat body cells and as in most tissues of third instar larvae both Adh-1 and Adh-2 are expressed. The single exception appears to be larval gut which contains ADH-1 but little if any ADH-2. In mature males and female flies all ADH containing tissues have only ADH-2. However, mature ovaries contain substantial quantities of ADH-1 which is apparently deposited into eggs. Given the extensive amount of available information on the Adh gene-enzyme system of D. melanogaster and the tools that can be applied to the analysis of homologous systems, the ADH duplication of D. mojavensis, and its regulation may be a useful one for studying differential gene regulation in specific cell types.     

Substrate and inhibitor specificities of the thermostable alcohol dehydrogenase allozymes ADH-71k and ADH-FCh.D. ofDrosophila melanogaster

Purified thermostable alcohol dehydrogenase allozymes ADH-71k and ADH-FCh.D. ofDrosophila melanogaster have been compared with the two common enzyme forms ADH-F and ADH-S. Enzyme kinetic parameters for various primary and secondary alcohols were determined under standard conditions used previously. Both ADH-71k and ADH-FCh.D. show ADH-S-like reaction kinetics andK _m values, due to retrograde evolution at site 214, Pro Ser. Inhibition studies with alcohol dehydrogenase inhibitors pyrazole, 4-methylpyrazole, and cibacron blue 3GA were also performed. Activity measurements on crude extracts of larvae and flies from isogenic lines of ADH-FCh.D. revealed a consistently higher activity than in ADH-71k-containing strains, in contrast to the original strains.K.Th.E is indebted to the Royal Norwegian Council for Technological and Scientific Research for their postdoctoral fellowship. Prof. J. S. McKinley-McKee gave me the opportunity to work in his laboratory. I thank Dr. Knut Sletten of the Biochemical Institute for the kind gift of 2-methoxyethanol and amino acid analysis of some samples. The Biological Institute, Oslo, Section of General Genetics, is gratefully acknowledged for enabling me to use their fly-breeding facilities. Dr. John B. Gibson provided us with a sample of FCh.D. flies for the construction of isogenic lines in which Dr. Johan Hageman participated, owing to Postdoctoral Grant 436-931-P from the Foundation of Biological Research (BION), which is subsidized by the Netherlands Organization for Scientific Research (NWO). J. H. and Paula Truyens were involved in the measurements on the crude extracts. Work at Victoria University was supported by the VUW Internal Grant Committee.     

Identification of P-450ALC in microsomes from alcohol dehydrogenase-deficient deermice: contribution to ethanol elimination in vivo

Isozyme 3a of rabbit hepatic cytochrome P-450, also termed P-450ALC, was previously isolated and characterized and was shown to be induced 3- to 5-fold by exposure to ethanol. In the present study, antibody against rabbit P-450ALC was used to identify a homologous protein in alcohol dehydrogenase-negative (ADH-) and -positive (ADH+) deermice, Peromyscus maniculatus. The antibody reacts with a single protein having an apparent molecular weight of 52,000 on immunoblots of hepatic microsomes from untreated and ethanol-treated deermice from both strains. The level of the homologous protein was about 2-fold greater in microsomes from naive ADH- than from naive ADH+ animals. Ethanol treatment induced the protein about 3-fold in the ADH+ strain and about 4-fold in the ADH- strain. The antibody to rabbit P-450ALC inhibited the microsomal metabolism of ethanol and aniline. The homologous protein, termed deermouse P-450ALC, catalyzed from 70 to 80% of the oxidation of ethanol and about 90% of the hydroxylation of aniline by microsomes from both strains after ethanol treatment. The antibody-inhibited portion of the microsomal activities, which are attributable to the P-450ALC homolog, increased about 3-fold upon ethanol treatment in the ADH+ strain and about 4-fold in the ADH- strain, in excellent agreement with the results from immunoblots. The total microsomal P-450 content and the rate of ethanol oxidation were induced 1.4-fold and 2.2-fold, respectively, by ethanol in the ADH+ strain and 1.9-fold and 3.3-fold, respectively, in the ADH- strain. Thus, the total microsomal P-450 content and ethanol oxidation underestimate the induction of the P-450ALC homolog in both strains. A comparison of the rates of microsomal ethanol oxidation in vitro with rates of ethanol elimination in vivo indicates that deermouse P-450ALC could account optimally for 3 and 8% of total ethanol elimination in naive ADH+ and ADH- strains, respectively. After chronic ethanol treatment, P-450ALC could account maximally for 8% of the total ethanol elimination in the ADH+ strain and 22% in the ADH- strain. Further, cytochrome P-450ALC appears to be responsible for about one-half of the increase in the rate of ethanol elimination in vivo after chronic treatment with ethanol. These results indicate that the contribution of P-450ALC to ethanol oxidation in the deermouse is relatively small. Desferrioxamine had no effect on rates of ethanol uptake by perfused livers from ADH-negative deermice, indicating that ethanol oxidation by a hydroxyl radical-mediated mechanism was not involved in ethanol metabolism in this mutant.(ABSTRACT TRUNCATED AT 400 WORDS)     

Acetic acid tolerance in Drosophila is a prerequisite for ethanol tolerance

Acetic acid tolerance compared with ethanol tolerance of Drosophila simulans and six Drosophila melanogaster strains shows a curvilinear relation with apparent asymptotic hyperbolic profile. The upper limit of acetic acid tolerance is lower than that for ethanol. We compared strains which had pairwise identical alcohol dehydrogenase (ADH) coding regions but different genetic backgrounds. A positive regression existed for ethanol tolerance on ADH activity. Adh-null mutants with very low ethanol tolerances had appreciable acetic acid tolerances and as a consequence did not fit the curve. ADH-F and ADH-S strains selected for high ethanol tolerances had the ability to tolerate high ethanol concentrations even after selection had been relaxed for several years. These selected lines tolerated higher acetic acid concentrations than the non-selected original strains. We propose that intake of high concentrations of ethanol and oxidation into acetic acid induces esterification of ethanol and acetic acid into ethylacetate. This cannot take place after the intake of acetic acid only, which also gives a lower energy yield.     

Synthesis of Drosophila melanogaster alcohol dehydrogenase in yeast

Expression systems for the heterologous expression of Drosophila melanogaster alcohol dehydrogenase (ADH) in Saccharomyces cerevisiae have been designed, analyzed and compared. Four different yeast/Escherichia coli shuttle vectors were constructed and used to transform four different yeast strains. Expression was detectable in ADH- yeast strains, from either a constitutive promoter, yeast ADH1 promoter (ADCp), or a regulated promoter, yeast GALp. The highest amount of D. melanogaster ADH was obtained from a multicopy plasmid with the D. melanogaster Adh gene expressed constitutively under the control of yeast ADCp promoter. The D. melanogaster enzyme was produced in cell extracts, as assessed by Coomassie blue staining and Western blotting after polyacrylamide-gel electrophoresis and it was fully active and able to complement the yeast ADH deficiency. Results show that D. melanogaster ADH subunits synthesized in yeast are able to assemble into functional dimeric forms. The synthesized D. melanogaster ADH represents up to 3.5% of the total extracted yeast protein.     

Introduction of single-stranded ADH genes into Drosophila results in tissue-specific expression

We injected single-stranded circular DNA containing a Drosophila Adh gene into ADH-negative embryos of Drosophila melanogaster and performed ADH histochemical staining on third instar larvae of the injected generation. Introduction of either the coding or non-coding strand resulted in correct tissue-specific expression of the Adh gene in larvae. Southern blotting revealed that the bulk of the injected DNA became double-stranded shortly after injection and was not integrated into the genome.     

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.