Latitudinal Adh allozymic variation and ethanol tolerance in Indian populations of Drosophila melanogaster

Ten Indian geographical populations of D. melanogaster were assayed electrophoretically for Adh genic variation. The Indian geographical populations of D. melanogaster revealed significant clinal variation (3 % for 1 d? latitude) at Adh locus and Adh^F allelic frequency correlated significantly with increase in latitude. It was suggested that the abundance of secondary alcohols in the southern Indian tropical and humid environment might exert selective pressure favouring higher frequency of Adh^S allele. Patterns of ethanol utilization as well as ethanol tolerance were analyzed in larval and adult individuals of six geographical populations of D. melanogaster. Latitudinal variation in ethanol tolerance was observed in D. melanogaster populations from India. The parallel occurrence of latitudinal variation it Adh locus as well as ethanol tolerance in Indian geographical populations of D. melanogaster could be maintained by balancing natural selection varying spatially along the north-south axis of the Indian sub-continent.     

The alcohol dehydrogenase alleloenzymes AdhS and AdhF from the fruitfly Drosophila melanogaster: An enzymatic rate assay to determine the active-site concentration

A rapid and reproducible enzymatic rate assay for the quantitative determination of the concentration of active sites is presented for the alleloenzymes Adh^S and Adh^F from Drosophila melanogaster. Using this procedure the turnover numbers as catalytic-center activities were found to be 12.2 sec^–1 for Adh^F and 3.4 sec^–1 for Adh^S with secondary alcohols. This showed a slower dissociation of the coenzyme from the binary enzyme-NADH complex with Adh^S and hence a stronger binding of NADH to this alleloenzyme. With ethanol, the catalytic-center activity was 1.4 sec^–1 for Adh^S and 2.8 sec^–1 for Adh^F, and hence the single amino acid mutation distinguishing the two alleloenzymes also affected hydride transfer.     

Variation in alcohol dehydrogenase activity in vitro in flies from natural populations ofDrosophila melanogaster

Alcohol dehydrogenase (ADH) activity variation in male flies taken directly from seven natural populations ofDrosophila melanogaster is largely accounted for by segregation of alleles at theAdh structural gene locus. There was little overlap in the ADH activities ofAdh ^F andAdh ^s homozygotes. Body weights varied only slightly betweenAdh genotypes and contributed little to ADH variation. Between and within population variation in ADH activity and ADH protein in flies in the wild is mainly due to the relative frequencies ofAdh ^F andAdh ^s.     

Extension of life duration by dietary ethanol in Drosophila melanogaster: response to selection in two strains of different origins

Lines homozygous for the Adh ^S and Adh ^F alleles were extracted from a French and an African natural population of D. melanogaster. The lines from each geographic region were then crossed and the Mendelian F₂ constituted the first generation subjected to selection for an increase in adult survival in the presence of 2% ethanol.The responses to selection were similar in the two strains, in spite of their different ethanol tolerance. In less than 10 generations, life span with ethanol increased from about 7 to more than 12 days, with realized heritabilities of 0.14 and 0.18. This extension of longevity was also observed with other concentrations of ethanol but not with water alone. The increase in life span in presence of alcohol appears to result from unknown metabolic processes, which are not obligatorily related to the capacity of the flies to tolerate starvation, nor to their size, their lipid content of their ethanol tolerance. In the two lines, however, the Adh ^S allele was quickly eliminated, suggesting a selective advantage for the F allele.     

Genetic regulation of liver alcohol dehydrogenase in Peromyscus

Data from genetic crosses of Peromyscus maniculatus and P. polionotus suggest that electrophoretic variants of liver alcohol dehydrogenase are coded by alleles at a single locus. These alleles, designated Adh ^F , Adh ^S , and Adh ^N , determine, respectively, the fast, slow, and not detectable (null) ADH electrophoretic phenotypes. Heterozygotes (Adh ^F /Adh ^S ) exhibit three bands on zymograms, suggesting a dimeric subunit structure for the enzyme. However, Adh ^F /Adh ^N and Adh ^S /Adh ^N animals exhibit a single band, suggesting that the Adh ^N allele does not produce a polypeptide subunit capable of dimerizing into an active molecule. Fast and slow electrophoretic phenotypes exhibit multiple bands which can be converted into single major fast and slow bands, respectively, upon treatment with oxidized or reduced NAD. Addition of NAD also stabilizes both the fast and slow enzyme to heat inactivation at 60 C for at least 30 min.This work was supported by Predoctoral Fellowship AA-05067 from the National Institute of Alcohol Abuse and Alcoholism to K. G. B. and South Carolina Commission on Alcohol and Drug Abuse Grant 7607. Also, partial support was provided by NIH Grant CA-16184.     

A long-term study on interactions between the Adh and αGpdh allozyme polymorphisms and the chromosomal inversion In(2L)t in a seminatural population of D. melanogaster

The Adh and αGpdh allozyme loci (both located on the second chromosome) showed considerable fluctuations in allele frequencies in a seminatural population of Drosophila melanogaster during 1972–97. Both long-term and short-term fluctuations were observed. The short-term fluctuations occurred within almost all years and comparison of allele frequencies between winters and summers showed significantly higher Adh^S (P < 0.001) and αGpdh^F (P < 0.01) allele frequencies in summers. Frequencies of these alleles were significantly positively correlated with environmental temperature, suggesting the adaptive significance of these allozyme polymorphisms. Frequency changes of the Odh locus (located on the third chromosome) showed no seasonal pattern and were not correlated with environmental temperature. Almost all short-term and long-term increases in Adh^S frequency were accompanied by a corresponding decrease in αGpdh^S frequency (r = –0.82, P < 0.001) and vice versa. Further analysis showed that gametic disequilibria between the Adh and αGpdh loci, which frequently occurred, were due to the presence of inversion In(2L)t located on the same chromosome arm and In(2L)t frequencies were positively correlated with environmental temperature. Gametic disequilibria between Adh and Odh and between Odh and αGpdh were hardly observed. Because In(2L)t is exclusively associated with the Adh^S/αGpdh^F allele combination, the observed correlated response in Adh/αGpdh allele frequencies is (at least partly) explained by hitchhiking effects with In(2L)t. This means that the adaptive value of the allozyme polymorphisms has been overestimated by ignoring In(2L)t polymorphism. Fluctuations in Adh allele frequencies are fully explained by selection on In(2L)t polymorphism, whereas we have shown that αGpdh frequency fluctuations are only partly explained by chromosomal hitchhiking, indicating the presence of selective differences among αGpdh genotypes in relation with temperature and independent of In(2L)t. Frequency fluctuations of αGpdh and In(2L)t are consistent with their latitudinal distributions, assuming that temperature is the main environmental factor varying with latitude that causes directly or indirectly these frequency distributions. However, the results of the tropical greenhouse population show no correlation of Adh (independent of In(2L)t) and Odh allele frequencies with environmental temperature, which may indicate that the latitudinal distribution in allele frequencies for these loci is not the result of selection on the F/S polymorphism in a direct way.     

Association of Chromosome and Enzyme Polymorphisms in Natural and Cage Populations of DROSOPHILA MELANOGASTER

The frequencies of a polymorphic inversion, In(2L)t, and of Adh and αGpdh alleles were analyzed in three natural populations of Drosophila melanogaster from Japan. Significant positive correlations between the frequencies of In(2L)t and Adh^S or αGpdh^F were detected due to tight linkage. An analysis of correlation with latitude showed that the negative cline of Adh^S frequency could be explained entirely by its linkage with In(2L)t; the frequency of Adh^S on the standard chromosome did not show a latitudinal cline. To the contrary, the cline of αGpdh^F frequency itself was positive, and its linkage with In(2L)t makes the positive cline unclear. These results suggest that the two allozymes themselves respond to latitudinal natural selection in different ways. When these populations were transferred to laboratory cages and maintained for a long time, they lost the chromosomal polymorphism but retained stable enzyme polymorphisms, although allele frequencies in the cage were not the same as in nature. The frequencies of Adh and αGpdh alleles were close to those in earlier cage populations of the same geographical origin.     

Distinct electrophoretic polymorphism pattern at alcohol dehydrogenase (<Emphasis Type="Italic">Adh</Emphasis>) locus of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> natural populations from Turkey

Small number of Drosophila melanogaster populations from two distinct geographical regions of Turkey, Central Anatolia and Black Sea, were studied. Populations sampled were electrophoresed for a single locus, alcohol dehydrogenase (Adh) to assess population differentiation. Both the magnitude of genetic differentiation levels and the population structure based on hierarchical F-statistics allow populations to be grouped on two genetically divergent area, Central Anatolian and Black Sea. One ecological correlate, average yearly maximum rainfall, R _year, seems to track this Adh genetic variation pattern. The study also shows that a typical pattern of geographical Adh polymorphism can emerge with a handfull of populations sampled across a relatively small distance. The text was submitted by the author in English.     

Analysis of genetic variation affecting the relative activities of fast and slow ADH dimers in Drosophila melanogaster heterozygotes

When Adh ^F /Adh ^S heterozygote homogenates are stained after electrophoresis, considerable variation is observed in the activity ratio of the FF dimer to the SS dimer. Two Adh ^S strains showed a sharp, consistent difference when crossed to a common Adh ^F strain. Optical scanning and genetic analysis confirmed that this difference originates close to the Adh locus. Since the morphs varied concordantly in their activities on numerous alcohols, and since aging and heat-treatment experiments failed to reveal a stability difference, it is proposed that the difference is regulatory in nature, affecting ADH synthesis and primarily cis-acting. A survey of wild flies revealed additional variation in the FF/SS activity ratio. Further genetic analysis showed that the basis of this variation is not restricted to the second chromosome. Furthermore, modification of the activity ratio implies some degree of allelespecificity on the part of the modifiers.This work was supported in part by money collected by Jewish Community of Iowa City, Iowa, and by NSF Grant 76-01903 to Roger Milkman.     

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.     

Alcohol dehydrogenase allozymes in the safflower genus Carthamus L.

The ADH allozyme pattern was tested in seeds of 1553 varieties of the world collection of safflower (Carthamus tinctorius L.) and 36 collections belonging to 14 wild species of the genus Carthamus L. with different chromosome numbers (n=10, 11, 12, 22, and 32). Two genes, Adh ₁ and Adh ₂, have been identified. The Adh ₁ locus controls the allozyme bands found in the faster-moving anodal zone, and the Adh ₂ gene controls the cathodal band. A third group of bands which migrates slowly toward the anode and stains weakly is probably interaction products of the two genes. Two codominant alleles Adh ₁ ^S and Adh ₁ ^F , specifying allozymes with different migration rates in the fast-moving anodal zone, were found in cultivated safflower. The frequency of the Adh ₁ ^F allele was very low. A third homologous allele, Adh ₁ ^T , was present only in the polyploid wild species. The Adh ₂ was stable, without any variation in migration rate. In addition to the variation in migration rates, there was also variation in activity levels of the products of both the Adh ₁ and Adh ₂ genes. The contribution of this study to our understanding of the origin of the polyploid species C. lanatus, C. baeticus, and C. turkestanicus is discussed.This research has been financed in part by a grant made to A. Ashri by the U.S. Department of Agriculture, Agricultural Research Service, authorized by P.L. 480, Project No. A10-CR-18, Grant No. FG-Is-234.Based in part on a thesis submitted by M. P. to the Faculty of Agriculture, The Hebrew University, Rehovot, in partial fulfillment of the requirements for the M.Sc. degree.Graduate Student, Faculty of Agriculture.     

Drosophila melanogaster alcohol dehydrogenase: An electrophoretic study of the AdhS,AdhF, and AdhUF alleloenzymes

The nature and the interconversion of the three multiple forms Adh-5, Adh-4, and Adh-3 of the purified alleloenzymes Adh^S, Adh^F, and Adh^UF from the fruitflyDrosophila melanogaster have been examined. The experiments show that these multiple forms differ from those in crude extracts of flies homozygous at the Adh locus. On electrophoresis in a starch gel containing NAD or NADH, of purified Adh^S which consists of the three Adh forms S-5, S-4, and S-3, five enzymatically active zones appear. This contrasts with the single active zone that arises with crude extracts. Of the five zones that appear with purified enzyme, S-5 gives rise to one, while the other four zones come from the two minor forms S-4 and S-3. The occurrence of the three multiple forms Adh-5, Adh-4, and Adh-3 for each of the purified alleloenzymes is considered due to Adh-5 and, in the case of Adh-4 and Adh-3, deamidation of Adh-5, with the Adh-3 fraction also containing some reversible modified Adh-5. Of the labile amides, at least one must be located in the coenzyme binding region with deamidation preventing coenzyme binding. Pure NAD does not convert Adh-5 to Adh-3 and Adh-1. To produce conversion, the presence of either acetone or butanone along with NAD is necessary. Increased amounts of either acetone or butanone result in increased conversion. In contrast to this, none of the carbonyl compounds cyclohexanone, (+)- and (−)-verbenone, acetaldehyde, acrolein, or crotonaldehyde produces conversion. The ketone group binds to the alcohol binding site in the enzyme-NAD complex. Conversion is considered due to the ketone group binding to a nucleophilic amino acid residue and forming a bridge to the C-4 of the nicotinamide moiety of NAD.     

Selection against homozygotes in the ADH polymorphic system of Drosophila melanogaster associated with the lethal factor l(2) Stm

In the natural populations ⁺Tüb, ⁺Prov, and ⁺Rov, similar Adh ^F allele frequencies occur (q _F=0.11, 0.18, and 0.08, respectively). However, there is a discrepancy in that the Adh ^F allele in ⁺Tüb is closely linked to the lethal factor 1(2)Stm, which reduces relative fitness of the F phenotype to zero. In spite of this, polymorphism is maintained also in ⁺Tüb, because the heterozygotes are superior to the homozygous S type (relative fitness=0.88). Under laboratory culture conditions, in ⁺Tüb the relative fitness of the S genotype further decreases to 0.6. After outcrossing the lethal factor, relative fitnesses for S, FS, and F become 0.6, 1, and 0.48, respectively, implying that fitness for S remains the same. Relative values for S, FS, and F in ⁺Prov, not affected by the lethal factor, are calculated by the maximum average fitness method to be 1, 1.2, and 0.2 under the assumption that heterozygous FS are similarly superior to S as in the natural ⁺Tüb population and all allele frequencies found are stable equilibrium values.     

Association and the Adh locus with a lethal factor (l(2) Stm) in Drosophila melanogaster

Keeping Drosophila cultures at 28 C results in elimination of all minor multiple ADH bands, thought to be due to conformational change. Thus in diploid and triploid adults heterozygous for the Adh ^F and Adh ^Salleles, relative staining intensities are found for the three bands which were in conformity with the assumption that both alleles are equally expressed. Among all polymorphic strains derived from natural Central European and Mediterranean populations, the strain ⁺Tüb is unique in that its Adh ^Fallele is closely linked to a new recessive lethal factor, named 1(2)Stm. All Adh ^F 1/Adh^F 1 pupae are unable to emerge, and die. The lethal effect is obvious 50 hr earlier by retarded eye, bristle, and body wall pigmentation. Although all pupae of the phenotype F die, Adh ^F allele frequency scarcely seems to be lowered in this natural population.     

Genetic analysis of Drosophila vitellogenesis: A molecular weight variant of yolk polypeptide-2 in Drosophila simulans

Summary To assess the likelihood of finding genetic variants for the three major yolk polypeptides (YPs) within the species Drosophila melanogaster, YPs from the five species most closely related to D. melanogaster were investigated. The relative positions of the three YPs were characteristic for each species, and in all cases the mobilities of the YP in the ovary corresponded to that of the YP in the hemolymph of the same species.Different stocks of Drosophila simulans were found to have either of two forms of yolk polypeptide-2 (YP2). The YP2^S polypeptide migrated more slowly than YP2^F by an apparent molecular weight difference of about 700 daltons. The genetic factor responsible for this difference mapped to locus 35 on the X chromosome. The Yp2 allele present specified the mobility of the YP2 polypeptide in both the hemolymph and the ovary. YP1 and YP3 were the same in both Yp2 ^S and Yp2 ^F stocks indicating that they are not affected by the Yp2 gene. Densitometric scans of gels showed that there was more than twice as much YP2^F as YP2^S in the ovaries and hemolymph of homozygous animals. Yp2 ^S/Yp2 ^F heterozygotes contained both fast and slowly migrating YP2. The amount of each YP2 in Yp2 ^F/Yp2 ^S heterozygotes was about half that found in each homozygote. These dosage results suggest that this locus is the structural gene. Peptide mapping showed that the structural element contributing to retarded mobility of YP2^S is unlikely to reside at either end of the molecule. These experiments suggest a cytogenetic location in which to concentrate further investigations on the genetic regulation of YP2 synthesis.     

Selection at the alcohol dehydrogenase locus of Drosophila melanogaster: Effects of ethanol and temperature

Drosophila melanogaster larvae were subjected to 10 generations of selection on 6% ethanol at 17, 25, and 30°C. For each temperature there was a significant (P<0.01) increase in the frequency of the Adh isoallele. Controls with no ethanol showed no change in the frequency of the Adh ^F isoallele. Larvae subjected to stronger selection on 8% ethanol confirmed the results. When adults of various ages were subjected to 16 and 32°C, the ADH^F isoenzyme retained its twofold advantage in activity over ADH^S regardless of the temperature. The same result was obtained with larvae at 16 and 35°C. Although some effect of temperature was demonstrated, it was concluded that the effect was not strong enough for temperature to be a selective factor under the conditions studied. However, ethanol is a strong selective factor for laboratory populations.     

Regulation of the activity of alcohol dehydrogenase isozymes during the development of the maize kernel

Summary The relative activities of alcohol dehydrogenase isozymes have been studied during the development of the endosperm and scutellum of heterozygous Adh ₁ ^F /Adh ₁ ^S maize kernels. The products of the Adh ₁ ^F allele are found earlier than the products of the Adh ₁ ^S allele in both the scutellum and the endosperm. A second gene (Adh _r )which controlsthe activity level of ADH is active in the scutellum only. The Adh _r ^N allele specifies increase in the relative activity of the Adh ₁ ^S products from 26 to 38 days after pollination. This increase is prevented by the Adh _r ^L allele which is dominant. These results ar discussed on the basis of the limited factor hypothesis proposed recently by Schwartz (1971) for the regulation of the Adh ₁gene in maize.     

The purification and biochemical properties of alcohol dehydrogenase—“Fast (chateau douglas)” from Drosophila melanogaster

Alcohol dehydrogenase has been purified from Drosophila melanogaster lines bearing the Adh ^F, Adh^S, and Adh ^FCh.D. alleles. Biochemical investigations show that the properties of the purified enzymes are very similar to those of crude enzyme extracts except that the pure enzymes are more heat stable. ADH-FCh.D. resembles ADH-S very closely in specific activity, substrate specificity, and a number of kinetic parameters including limiting values for K _m(app.) for ethanol. However, it is considerably more heat stable than either of the two common variants. ADH-F differs from ADH-S and ADH-FCh.D. particularly with regard to the rate of oxidation of secondary alcohols. Atomic absorbtion spectroscopy shows that all three allozymes lack zine or other divalent cations as active-site components. Peptide mapping experiments identify one very active cysteinyl residue; and amide residues in the NAD⁺ binding domain.     

Alcohol dehydrogenase polymorphism in populations of Drosophila melanogaster. II. Relation between ADH activity and adult mortality

Eight Drosophila melanogaster strains, seven homozygous for Adh ^F alleles and one for an Adh-null mutant, were compared for ADH activity in males and adult mortality on ethanol-supplemented food. The strains differed considerably in these qualities. A positive correlation was found between ADH activity and ld ₅₀. The relevance of this finding is discussed in relation to the differential selection acting on Adh genotypes kept on ethanol-supplemented food.     

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.