Isolation of Protease-Free Alcohol Dehydrogenase (ADH) from Drosophila simulans and Several Homozygous and Heterozygous Drosophila melanogaster Variants

The enzyme alcohol dehydrogenase (ADH) fromseveral naturally occurring ADH variants ofDrosophila melanogaster and Drosophilasimulans was isolated. Affinity chromatography withthe ligand Cibacron Blue and elution with NAD⁺ showed similarbehavior for D. melanogaster ADH-FF, ADH-71k,and D. simulans ADH. Introduction of a secondCibacron Blue affinity chromatography step, withgradient elution with NAD⁺, resulted in pure and stable enzymes. D.melanogaster ADH-SS cannot be eluted from theaffinity chromatography column at a high concentrationof NAD⁺ and required a pH gradient for itspurification, preceded by a wash step with a high concentration ofNAD⁺. Hybrid Drosophila melanogasteralcohol dehydrogenase FS has been isolated fromheterozygous flies, using affinity chromatography withfirst elution at a high concentration NAD⁺, directlyfollowed by affinity chromatography elution with a pHgradient. Incubation of equal amounts of pure homodimersof Drosophila melanogaster ADH-FF and ADH-SS,in the presence of 3 M urea at pH 8.6, for 30 min at roomtemperature, followed by reassociation yielded activeDrosophila melanogaster ADH-FS heterodimers. Noproteolytic degradation was found after incubation ofpurified enzyme preparations in the absence or presenceof SDS, except for some degradation of ADH-SS after verylong incubation times. The thermostabilities of D.melanogaster ADH-71k and ADH-SS were almostidentical and were higher than those of D.melanogaster ADH-FF and D. simulans ADH. Thethermostability of D. melanogaster ADH-FS waslower than those of D. melanogaster ADH-FF andADH-SS. D. melanogaster ADH-FF and ADH-71k have identical inhibition constantswith the ligand Cibacron Blue at pH 8.6, which are twotimes higher at pH 9.5. The K_i values forD. simulans ADH are three times lower at bothpH values. D. melanogaster ADH-SS and ADH-FS havesimilar K_i values, which are lower than thosefor D. melanogaster ADH-FF at pH 8.6. But at pH9.5 the K_i value for ADH-FS is the same as atpH 8.6, while that of ADH-SS is seven times higher. Kinetic parameters ofDrosophila melanogaster ADH-FF, ADH-SS, andADH-71k and Drosophila simulans ADH, at pH 8.6and 9.5, showed little or no variation inK_m ^eth values. TheK_m ^NAD values measured at pH 9.5for Drosophila alcohol dehydrogenases are alllower than those measured at pH 8.6. The rate constants(k_cat) determined for all fourDrosophila alcohol dehydrogenases are higher at pH 9.5 than at pH 8.6. D.melanogaster ADH-FS showed nonlinear kinetics.     

Ethanol Tolerance and Alcohol Dehydrogenase (ADH; EC1.1.1.1) Activity in Species of the cardini Group of Drosophila

Ethanol tolerance, alcohol dehydrogenase (ADH;EC1.1.1.1) activity, and tissue-specific expression wereexamined in species of the cardini group ofDrosophila using D. melanogaster as astandard of comparison. In contrast to most fruit-breeding species, allcardini species examined, two from the cardini subgroupand five from the dunni subgroup, were ethanol sensitive(LC₅₀ 2.05%) and the mean ADH activityof males ranges from only 8 to 16% that of D.melanogaster Adh^FF. Among all sevencardini species, there were small but significantdifferences in ethanol tolerance and ADH activity.Differences in enzyme mobility were in accordance with the proposedphylogeny for the dunni-subgroup species. ADH isexpressed in the fat body and midgut. Males of D.acutilabella and of D. belladunni havesignificantly less ethanol tolerance and express less ADH activitythan females in zymograms and histologicalpreparations.     

Chemical Selection of Alcohol Dehydrogenase Negative Mutants in Drosophila

We describe a selection procedure which utilizes the vapor from an unsaturated alcohol, 1-pentene-3-ol, for the detection and isolation of mutant flies with little or no alcohol dehydrogenase activity. ADH-negative flies are unaffected by exposure to the unsaturated alcohol, but ADH positives (wild-types) die after short exposure. The technique can be used to select rare ADH-negative individuals from large populations of wild-type flies.     

Post-Translational Control of Alcohol Dehydrogenase Levels in Drosophila melanogaster

A trans-acting regulatory gene that alters in vivo protein levels of alcohol dehydrogenase (ADH) has been mapped to a region of the third chromosome of Drosophila melanogaster. The gene has been found to affect the in vivo stability of ADH protein. It was not found to alter levels of total protein of two other enzymes assayed. The action of the gene over development and its possible mode of control are discussed.     

Physiological Significance of the Alcohol Dehydrogenase Polymorphism in Larvae of Drosophila

This study deals with biochemical and metabolic-physiological aspects of the relationship between variation in in vivo alcohol dehydrogenase activity and fitness in larvae homozygous for the alleles Adh71k, AdhF, AdhS, of Drosophila melanogaster, and for the common Adh allele of Drosophila simulans. The Adh genotypes differ in the maximum oxidation rates of propan-2-ol into acetone in vivo. There are smaller differences between the Adh genotypes in rates of ethanol elimination. Rates of accumulation of ethanol in vivo are negatively associated with larval-to-adult survival of the Adh genotypes. The rank order of the maximum rates of the ADHs in elimination of propan-2-ol, as well as ethanol, is ADH-71k greater than ADH-F greater than ADH-S greater than simulans-ADH. The ratio of this maximum rate to ADH quantity reveals the rank order of ADH-S greater than ADH-F greater than ADH-71k greater than simulans-ADH, suggesting a compensation for allozymic efficiency by the ADH quantity in D. melanogaster.Our findings show that natural selection may act on the Adh polymorphism in larvae via differences in rates of alcohol metabolism.     

Enzymic and Structural Studies on Drosophila Alcohol Dehydrogenase and Other Short-Chain Dehydrogenases/Reductases

Enzymic and structural studies on Drosophila alcohol dehydrogenases and other short-chain dehydrogenases/reductases (SDRs) are presented. Like alcohol dehydrogenases from other Drosophila species, the enzyme from D. simulans is more active on secondary than on primary alcohols, although ethanol is its only known physiological substrate. Several secondary alcohols were used to determine the kinetic parameters k_cat and K_m. The results of these experiments indicate that the substrate-binding region of the enzyme allows optimal binding of a short ethyl side-chain in a small binding pocket, and of a propyl or butyl side-chain in large binding pocket, with stereospecificity for R(−) alcohols. At a high concentration of R(−) alcohols substrate activation occurs. The k_cat and K_m values determined under these conditions are about two-fold, and two orders of magnitude, respectively, higher than those at low substrate concentrations. Sequence alignment of several SDRs of known, and unknown three-dimensional structures, indicate the presence of several conserved residues in addition to those involved in the catalyzed reactions. Structural roles of these conserved residues could be derived from observations made on superpositioned structures of several SDRs with known structures. Several residues are conserved in tetrameric SDRs, but not in dimeric ones. Two halohydrin-halide-lyases show significant homology with SDRs in the catalytic domains of these enzymes, but they do not have the structural features required for binding NAD⁺. Probably these lyases descend from an SDR, which has lost the capability to bind NAD⁺, but the enzyme reaction mechanisms may still be similar. Received: 23 May 2000 / Accepted: 4 January 2001     

Effect of Zinc Ions on Conformational Stability of Yeast Alcohol Dehydrogenase

Yeast alcohol dehydrogenase preparations were prepared with the conformational zinc ion removed (Apo-I YADH) and with both the conformational and catalytic zinc ions removed (Apo-II YADH). The unfolding of Apo-I YADH and Apo-II YADH during denaturation in urea solutions was then followed by fluorescence emission, circular dichroism, and second-derivative optical spectroscopies. Compared with the native enzyme, Apo-I YADH incurred some slight unfolding, and its stability against urea was markedly decreased, while Apo-II YADH incurred marked unfolding but contained residual ordered structure even at high urea concentrations. The results show that native YADH is more conformationally stable against urea denaturation than Apo-I YADH, indicating that the conformational Zn²⁺ plays an important role in stabilizing the conformation of the YADH molecule. However, unfolding of the region around the conformational zinc ion is shown not to be the rate limited step in the unfolding of the molecule by the fact that the unfolding and inactivation rate constants of native and Apo-I YADH are the same. It is suggested that the catalytic zinc ion is more important in maintaining the structure of YADH. YADH lost its cooperative unfolding ability after the zinc ions were removed. The shape of the transition curves of Apo-I YADH suggests the existence of an unfolding intermediate. For both native and Apo-I YADH, inactivation occurs at much lower urea concentrations than that needed to produce significant conformational changes of the enzyme molecule. At urea concentration above 4 M, the inactivation rate constants are much higher than those of the fast phase of the reaction of unfolding. These results support the suggestion of flexibility at the active site of the enzyme (C. L. Tsou (1986) Trends Biochem. Sci., 11, 427-429; (1993) Science, 262, 308-381).     

Reexamination of Alcohol Dehydrogenase Structural Mutants in Drosophila Using Protein Blotting

Using protein blotting and an immuno-overlay procedure, we have reexamined the cross-reacting material produced by ADH null-activity mutants generated with ethyl methanesulfonate (EMS). Of the 13 mutants, 11 have an immunodetectable polypeptide of wild-type size. The native and urea denatured isoelectric points (pI) establish that 7 of 13 of the mutations have no effect on protein charge. The electrophoretic mobilities of each variant on increasing percent acrylamide gels (Ferguson analysis), reveal that 9 of the 11 immunodetectable mutants have retained the ability to form dimers under native conditions. None of the inactive mutant proteins has the ability to form the "adduct-bound" isozyme. We have found no correlation between protein pI and in vivo stability. The observed frequencies of specific charge class alterations do not dispute the propensity of G:A transitions previously found for EMS mutagenesis.     

Analysis of Autosomal Dosage Compensation Involving the Alcohol Dehydrogenase Locus in Drosophila Melanogaster

An example of autosomal dosage compensation involving the expression of the alcohol dehydrogenase (Adh) locus is described. Flies trisomic for a quarter of the length of the left arm of chromosome two, including Adh, have diploid levels of enzyme activity and alcohol dehydrogenase messenger RNA. Subdivision of the compensating trisomic into smaller ones revealed a region that exerts an inverse regulatory effect on alcohol dehydrogenase activity and messenger RNA levels and a smaller region surrounding the structural gene that exhibits a direct gene dosage response. The two opposing effects are of sufficient magnitude that they cancel when simultaneously present resulting in the observed compensation in the larger aneuploid. An Adh promoter-white structural gene fusion construct is affected by the inverse regulatory region indicating that the effect is mediated through the Adh promoter sequences. The role of autosomal dosage compensation in understanding aneuploid syndromes and karyotype evolution in Drosophila species is discussed.     

Divergence of the Regulation of alpha-Amylase Activity in Drosophila melanogaster, Drosophila funebris, and Drosophila saltans

The regulation of amylase activity in threeDrosophila species, D. melanogaster,D. funebris and D. saltans, wasanalyzed by measuring the specific activity levels infour dietary environments, cornmeal, glucose, 5% starch, and 10% starch, at threedevelopmental stages, i.e., the third-instar larval,pupal, and 2-day-old adult stages. The developmentalprofiles of amylase activity for the threeDrosophila species showed that the level of activity washigh at the larval and adult stages but substantiallylow at the pupal stage, suggesting thatDrosophila does not utilize starch at the pupalstage. Divergence in the regulation of amylase was observed amongthe three Drosophila species on the followingpoints. (1) The order of amylase specific activity wasD. melanogaster > D. funebris >D. saltans. (2) The response pattern to the dietary environment varied amongthe species and changed during development. (3) Thetiming of the switch in the response pattern to thedietary environment during development was before pupation in D. funebris and D.saltans but after pupation in D.melanogaster. The significance of the divergence inthe regulation of amylase activity for adaptation to astarch environment in Drosophila is discussed.     

神经tau聚集物诱导乳酸脱氢酶的失活与构象变化

在37℃,pH 7.2条件下,人类神经tau经过保温形成自聚集物,从而丧失对微管蛋白组装的功能.进一步的实验表明,天然tau具有促进乳酸脱氢酶活性的作用,而tau聚集物却诱导乳酸脱氢酶活性的降低.     

Origin and Evolution of a New Gene Descended from Alcohol Dehydrogenase in Drosophila

Drosophila alcohol dehydrogenase (Adh) is highly conserved in size, organization, and amino acid sequence. Adh-ψ was hypothesized to be a pseudogene derived from an Adh duplication in the repleta group of Drosophila; however, several results from molecular analyses of this gene conflict with currently held notions of molecular evolution. Perhaps the most difficult observations to reconcile with the pseudogene hypothesis are that the hypothetical replacement sites of Adh-ψ evolve only slightly more quickly than replacement sites of closely related, functional Adh genes, and that the replacement sites of the pseudogenes evolve considerably more slowly than neighboring silent sites. The data have been presented as a paradox that challenges our understanding of the mechanisms underlying DNA sequence divergence. Here I show that Adh-ψ is actually a new, functional gene recently descended from an Adh duplication. This descendant recruited ~60 new N-terminal amino acids, is considerably more basic than ADH, and is evolving at a faster rate than Adh. Furthermore, though the descendant is clearly functional, as inferred from molecular evolution and population genetic data, it retains no obvious ADH activity. This probably reflects functional divergence from its Adh ancestor.     

The Effect of an Intronic Polymorphism on Alcohol Dehydrogenase Expression in Drosophila Melanogaster

Several lines of evidence indicate that natural selection controls the frequencies of an allozyme polymorphism at the alcohol dehydrogenase (Adh) locus in Drosophila melanogaster. However, because of associations among sequence polymorphisms in the Adh region, it is not clear whether selection acts directly (or solely) on the allozymic site. This problem has been approached by using in vitro mutagenesis to distinguish among the effects on Adh expression of individual polymorphisms. This study shows that a polymorphism within the first Adh intron ( &1) has a significant effect on the level of ADH protein. Like the allozyme, & shows a geographic cline in frequency, indicating that it may also be a target of natural selection. These results suggest that multisite selection models may be required to understand the evolutionary dynamics of individual loci.     

Shaping of Drosophila Alcohol Dehydrogenase Through Evolution: Relationship with Enzyme Functionality

Drosophilidae is a large, widely distributed family of Diptera including 61 genera, of which Drosophila is the most representative. Drosophila feeding is part of the saprophytic trophic chain, because of its dependence upon decomposing organic matter. Many species have adapted to fermenting fruit feeding or to artificial (man-made) fermentation habitats, such as cellars and breweries. Actually, the efficient exploitation of niches with alcohols is considered one of the reasons for the worldwide success of this genus. Drosophila alcohol dehydrogenase (ADH), a member of the short-chain dehydrogenase/reductase family (SDR), is responsible for the oxidation of alcohols, but its direct involvement in fitness, including alcohol tolerance and utilization, gives rise to much controversy. Thus, it remains unclear whether ADH differentiation through evolution is somehow associated with natural adaptation to new feeding niches, and thus maybe to Drosophila speciation, or if it is a simple reflection of neutral divergence correlated with time separation between species. To build a hypothesis which could shed light on this dilemma, we analyzed the amino acid variability found in the 57 protein ADH sequences reported up to now, identified the taxon-specific residues, and localized them in a three-dimensional ADH model. Our results define three regions whose shaping has been crucial for ADH differentiation and would be compatible with a contribution of ADH to Drosophila speciation. Received: 11 August 1997 / Accepted: 30 December 1997     

Partial Correction of Structural Defects in Alcohol Dehydrogenase through Interallelic Complementation in Drosophila melanogaster

Alcohol dehydrogenases (ADH) from the F₁ progeny of all pairwise crosses between 12 null-activity mutants and crosses between these mutants and four active variants, ADHⁿ⁵ ADH^F, ADH^D and ADH^S, were analyzed for the presence of active or inactive heterodimers. Gels were stained for ADH enzyme activity, and protein blots of duplicate gels were probed with ADH-specific antibody to detect cross-reacting material. Crosses between the three major electrophoretic variants. ADH^F, ADH^S and ADH^D, all produced active heterodimers. Four mutant proteins (ADHⁿ², ADHⁿ⁴, ADHⁿ¹⁰ and ADHⁿ¹³) did not form heterodimers with any other ADH subunit tested. Of the 28 crosses involving the remaining null activity mutants, 22 produce heterodimers. Twelve of these exhibit partial restoration of enzyme activity. In five cases of active heterodimers from null-activity crosses, Adhⁿ¹¹ supplied one of the subunits. In two crosses involving the active variant ADH^D, the null activity mutant subunits (ADHⁿ⁸ and ADHⁿ³) destabilized the heterodimer sufficiently to cause inactivation of the ADH^D subunit. In the cross between Adh^F and Adhⁿ³, the activity of the ADH^F subunit was also greatly reduced in association with the ADHⁿ³ subunit. Two crosses (Adhⁿ¹ x Adhⁿ¹¹ and Adhⁿ⁵ x Adhⁿ¹²) result in partial restoration of one of the homodimeric proteins (ADH ⁿ¹ and ADHⁿ¹², respectively), as well as forming active heterodimers.     

SDS-PAGE Pattern Polymorphism of X-Chromosomal Glue Proteins in Natural Populations of Two Drosophila nasuta Subgroup Species

For the first time, the glue protein patternpolymorphism in natural populations of D. n.nasuta and D. s. neonasuta has beenanalyzed by SDS-PAGE. The study involving 200 and 185isofemale lines comprising 2028 and 1900 individuals of D. n.nasuta and D. s. neonasuta, respectively,revealed the occurrence of eight variant glue proteinphenotypes in D. n. nasuta and seven in D.s. neonasuta. The number and frequency of variant phenotypes in differentpopulations of both species were found to vary. Analysisof glue protein patterns in the F₁ progeny ofcrosses involving parents with variant glue proteinphenotypes revealed that the polymorphic fractions areproduced by co-dominant genes located on the Xchromosome. More than 87% of the naturally inseminatedadult females were found to produce polymorphic progeny. The heterozygous female larvae were found toexceed the homozygotes in the isofemale line progeny ofmost of the populations.     

Molecular Population Genetics of an Electrophoretically Monomorphic Protein in the Alcohol Dehydrogenase Region of Drosophila Pseudoobscura

Nucleotide sequence data from the alcohol dehydrogenase (Adh) region of 18 isochromosomal strains of Drosophila pseudoobscura were used to determine whether the lack of amino acid polymorphism in ADH results from a low neutral mutation rate or a recent directional selection event. We estimated the neutral mutation parameter, 4Nmu, in synonymous sites for 17 subregions of Adh. The nucleotide diversity data were tested for departures from an equilibrium neutral model with two statistical tests. The Tajima test and the Hudson, Kreitman and Aguade test each failed to reject a neutral model. These results suggest that the ADH enzyme of D. pseudoobscura lacks amino acid polymorphisms because the neutral mutation rate of nonsynonymous sites is low. The neutral mutation parameter for synonymous sites is heterogeneous between domains of the Adh region. These data indicate that selective constrains on synonymous sites can vary between functional domains.