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.     

Adh Nucleotide Variation in Drosophila willistoni: High Replacement Polymorphism in an Electrophoretically Monomorphic Protein

Drosophila willistoni was the subject of intensive allozyme studies and the locus coding for alcohol dehydrogenase (Adh) was found to be virtually monomorphic. DNA sequence analysis of 18 alleles throughout the distribution of the species has revealed six replacement polymorphisms. The ratio of replacement to silent polymorphisms is higher in D. willistoni than in any other Drosophila species studied for Adh nucleotide variation. Also in contrast to other species, the variation in introns and noncoding DNA is about the same as in the coding region. We speculate that both these differences indicate D. willistoni has historically had a small population size possibly related to Pleistocene refugia in the Neotropics. Received: 5 August 1996 / Accepted: 12 April 1997     

Evolutionary implications of allozyme and RAPD variation in diploid populations of dioecious buffalograss Buchloë dactyloides

Buffalograss, Buchloë dactyloides, is widely distributed throughout the Great Plains of North America, where it is an important species for rangeland forage and soil conservation. The species consists of two widespread polyploid races, with narrowly endemic diploid populations known from two regions: central Mexico and Gulf Coast Texas. We describe and compare the patterns of allozyme and RAPD variation in the two diploid races, using a set of 48 individuals from Texas and Mexico (four population samples of 12 individuals each). Twelve of 22 allozyme loci were polymorphic, exhibiting 35 alleles, while seven 10-mer RAPD primers revealed 98 polymorphic bands. Strong regional differences were detected in the extent of allozyme polymorphism: Mexican populations exhibited more internal gene diversity (H_e= 0.20, 0.19) than did the Texan populations (H_e= 0.08, 0.06), although the number of RAPD bands in Texas (n= 62) was only marginally smaller than in Mexico (n= 68). F-statistics for the allozyme data, averaged over loci, revealed strong regional differentiation (mean F_RT=+ 0.30), as well as some differentiation among populations within regions (mean F_PR=+ 0.09). In order to describe and compare the partitioning of genetic variation for multiple allozyme and RAPD loci, we performed an Analysis of Molecular Variance (AMOVA). AMOVA for both allozyme and RAPD data revealed similar qualitative patterns: large regional differences and smaller (but significant) population differences within regions. RAPDs revealed greater variation among regions (58.4% of total variance) than allozymes (45.2%), but less variation among individuals within populations (31.9% for RAPDs vs. 45.2% for allozymes); the proportion of genetic variance among populations within regions was similar (9.7% for RAPDs vs. 9.6% for allozymes). Despite this large-scale concordance of allozyme and RAPD variation patterns, multiple correlation Mantel techniques revealed that the correlations were low on an individual by individual basis. Our findings of strong regional differences among the diploid races will facilitate further study of polyploid evolution in buffalograss.     

Isozyme variability in species of the genus Drosophila. VI. Frequency-property-environment relationships of allelic alcohol dehydrogenases in D. melanogaster

Adult Drosophila melanogaster from naturally occurring populations in the Eastern United States were examined by gel electrophoresis for their alcohol dehydrogenase (ADH) phenotype. The ADH enzymes were partially purified and characterized. Frequencies of the controlling alleles, Adh ⁴ and Adh ⁶, were discovered to vary in a clinal pattern. Adh ⁶ reaches a maximum frequency of about 0.90 in the South and minimum of about 0.50 in the North. Partially purified enzymes from the three Adh genotypes varied according to specific activity, substrate specificity, and heat stability. A differential influence of pH was indicated. There was little variation in K _m values for ethanol and DPN⁺ among the enzymes.This work was supported by AEC Contract No. AT-(40-1)-3980 and by PHS Research Grant No. GM 11546.Paper No. 3880 of the Journal Series of the North Carolina Experiment Station, Raleigh, North Carolina. This work incorporates, in part, the thesis research of C. L. Vigue to be submitted in partial fulfillment of the Ph.D. requirements in Genetics.     

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.     

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.     

Isozyme polymorphism and phylogenetic interpretations in the genus Cicer L.

Summary Allozyme variation among 50 accessions representing the cultivated chickpea (Cicer arietinum L.) and eight wild annual Cicer species was scored and used to assess genetic diversity and phylogeny. Sixteen enzyme systems revealed 22 putative and scorable loci of which 21 showed polymorphism. Variation was prevalent between species (D_st = 0.510) but not within species (H_s = 0.050). No variation for isozyme loci was detected in the cultivated chickpea accessions. Cicer reticulatum had the highest proportion of polymorphic loci (0.59) while the loci Adh-2 and Lap were the most polymorphic over all the species accessions. The phylogeny of annual Cicer species, as determined by allozyme data, generally corroborated those based on other characters in previous studies. Cicer arietinum, C. reticulatum and C. echinospermum formed one cluster, while C. pinnatifidum, C. bijugum and C. judaicum formed another cluster. Cicer chorassanicum was grouped with C. yamashitae, whereas C. cuneatum formed an independent group and showed the largest genetic distance from C. arietinum.     

The fate of several migrant genes in isolated populations of Drosophila melanogaster

Sepia-eyed flies carrying the slow electrophoretic variant of either Est-6 or Adh were introduced in low numbers and at infrequent intervals into populations of wildtype flies (+ ^se /+ ^se ) that were also homozygous for the fast moving variant of either Est-6 (50 populations) or Adh (50 populations). After 24 generations, the frequency of the sepia alleles was approximately 25%, although there was considerable variation from population to population. The fate of the Est-6 slow allele corresponded closely to that of sepia (which is located ten map units distant), although one population retained the slow allozyme variant but rejected sepia. The Adh slow allele was also retained by many populations. A number of them retained Adh-S but not sepia, and vice versa; these loci are on different chromosomes. The advantage of sepia heterozygotes was estimated to be about twice that of wildtype homozygotes. The data suggest that the selective advantage resides not with the sepia locus itself, but with a nearby chromosomal region.Financial support for work reported here was supplied under grant number GM24850, National Institutes of Health.     

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.     

Chromosomal location of alcohol dehydrogenase gene(s) in rye,using wheat-rye addition lines

Following disc electrophoresis on standard gels, rye seed extracts showed two bands (ADH-3 and 5) for alcohol dehydrogenase. The ADH-3 band was homologous to the ADH band observed in other diploid species of the Triticinae, and with the ADH-3 band of 4 × and 6 × wheat. It is proposed that the rye isoenzymes ADH-3 and 5 are governed respectively, by the genes Adh _R1 and Adh _R2. Using bread wheat (Holdfast) lines with disomic addition of individual rye (King II) chromosomes, we found that the ADH-5 band was associated with the addition of rye chromosome IV (after Riley), indicating thereby that Adh _R2 gene is located on this chromosome. The products of Adh _R1 and Adh _R2 do not form active heterodimers, among themselves, but do form active dimers with wheat ADH monomers. It is suggested that the use of chromosomal addition lines may provide a method for locating genes for those enzymes, where the rye and wheat isoenzymes are electrophoretically distinct.     

Genetic relationships between the multiple alcohol dehydrogenases of maize

There are three electrophoretically separable sets of alcohol dehydrogenase isozymes in maize. Previous work has shown that two of these isozymes (Sets I and II) share a subunit in common, since mutations in one of the Adh genes, Adh ₁, alter both isozymes. A mutation in the second Adh gene, Adh ₂, has now been induced and recovered. This mutant allele also alters two of the three isozymes—Sets III and II. Adh ₁ and Adh ₂ appear to segregate independently. Gel filtration data show that all ADH isozymes are indistinguishable in size. These findings support the hypothesis that the two Adh genes specify promoters which homo- and heterodimerize, yielding three types of ADH isozymes.This research was supported by National Science Foundation Grant GB 25594. M.F. is a recipient of Public Health Service Genetics Training Grant GM 82-12.     

MOLECULAR ANALYSIS OF THE ALLELES OF ALCOHOL DEHYDROGENASE ALONG A CLINE IN DROSOPHILA MELANOGASTER. I. MAINE,NORTH CAROLINA,AND FLORIDA

Clinal variation in natural populations is often assumed to be due to the operation of natural selection. However, for many clines there exist plausible neutralist explanations which suggest that aspects of population structure maintain differences among subpopulations for particular traits. We used a restriction-mapping technique to investigate the contributions of population subdivision and selection to the maintenance of the allozyme polymorphism at the alcohol dehydrogenase (Adh) locus of Drosophila melanogaster. Digestions of genomic DNAs from 270 lines of flies by seven enzymes reveal 15–20% of all possible nucleotide substitutions and virtually all of the insertion/deletion variation in a 2.7-kilobase region containing the Adh structural locus. Analysis of large samples from each of three populations along the east coast of the United States provides evidence of founder effects in the most northerly population. Although there are signs of population differentiation among the samples, similarities between two of the populations indicate that migration among populations is extensive and strengthen the argument that natural selection plays a role in maintaining the cline.     

THE ASSOCIATION BETWEEN THE POLYMORPHISMS AT THE Adh AND αGpdh LOCI AND THE In(2L)t INVERSION IN DROSOPHILA MELANOGASTER IN RELATION TO TEMPERATURE

Substantial allele-frequency changes were observed at the Adh and αGpdh loci in a seminatural population of Drosophila melanogaster kept in a tropical greenhouse during 1972–1985. Further analysis of the changes at the Adh and αGpdh loci showed that linkage disequilibrium between these loci occurred for a prolonged period due to the presence of In(2L)t, a long inversion on the left arm of the second chromosome. We observed increases in the frequencies of In(2L)t and of short inversions on the left arm of the second chromosome in subpopulations kept at 29.5°C or 33°C. These inversion-frequency increases were accompanied by an increase in Adh^s and a decrease in αGpdh^s frequency. In populations kept at 20°C and 25°C, inversion frequencies decreased, while αGpdh^s allele frequencies decreased at 25°C and increased at 20°C. At 33°C, egg-to-adult survival of individuals possessing In(2L)t, either in the homokaryotypic or the heterokaryotypic state, was higher than that of the other karyotypes of identical allozyme constitution (i.e., Adh^s αGpdh^F). Thus it seems that In(2L)t has a selective advantage at high temperature. We argue that the observed changes in allele frequencies at the Adh and αGpdh loci are, in part, due to genic selection and are not merely the result of selection acting on the chromosome rearrangements and hitchhiking of the allozymes. The results are discussed with respect to the latitudinal clines found for In(2L)t, Adh, and αGpdh.     

Mimicry of isozyme adaptive advantage by gene association I. Relationship between Adh genotypes and body dimension in Drosophila cage populations: A multivariate analysis

Experiments are described that are to prove that the apparent selective responses at the Adh locus in Drosophila melanogaster are not independent from its genetic background and from the variation at the gene pool level brought about by the changes of selection pressure. The dynamics of allozyme frequencies were observed at the Adh locus, of five metric traits and of reproductive fitness in two synthetic populations of Drosophila melanogaster originated from the same cross between Canton and Oregon strains, homozygotes for different Adh alleles and reared at different temperature (25 °C and 28 °C), until all above mentioned characters showed no more variations. The results obtained by univariate and multivariate statistical analyses can be summarized as follows:

- Adh ^s allele frequency keeps high and reaches very similar values in spite of the different environmental temperatures, whose selective effects at the Adh locus are therefore unlikely;

- both populations evolve toward the stabilization of Adh frequencies and other characters with a process strictly dependent on the permanence of coadapted blocks of genes which were contributed to the F₂ generation by the parental Canton and which are identified phenotypically by the association of Adh ^s/s with short wing;

- at the stabilization point the flies classified on the basis of their Adh genotype exhibit different shapes, namely their metric phenotypes can be discriminated considering all the respective traits together by means of multivariate analyses.

Owing to the presence in the initial populations of heterosis and epistatic interactions between loci, the observed differences between Adh genotype groups should represent the outcome of selection upon coadapted blocks of genes rather than on individual loci. Therefore, these results are argued as further evidence that each Adh genotype can be associated to different gene arrangements and its adaptive value cannot be isolated from that of its genetic background.     

Heterosis in the flour moth,Ephestia kühniella

Four lines of Ephestia kühniella each homozygous for one of three different allozyme alleles at the Est-2 locus and two alleles at the Adh locus were crossed in order to study the extent of somatic, reproductive and adaptive heterosis in F₁ hybrids in comparison with the mean performance of the simultaneously reared inbred parent lines. With regard to adult weight and wing length (somatic heterosis) hybrids exhibit maximally 20% (males 10%) and 9% heterosis, respectively. As concerns the production of eggs and hatched larvae (reproductive heterosis) hybrids exceed the parental mean by 90% and 200%. Adaptive heterosis is realized by a shorter development period of the hybrids (maximally by 30%) as well as by significant lower variance of all metrical characters studied. In the F₂ the degree of heterosis diminishes. There is neither an excess of heterozygotes among the segregating allozyme genotypes nor superior performance of the heterozygotes concerning any one of the traits studied. Therefore, it is concluded that the pronounced heterosis in F₁ is not a single-gene-heterosis operating at the Est-2 and the Adh-locus.     

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.     

Revisiting protein heterozygosity in plants��nucleotide diversity in allozyme coding genes of conifer Pinus sylvestris

Allozyme variation has been and continues to be a major source of information on the level of genetic variation among plant species. Deciphering the molecular basis of electrophoretic variation is essential for understanding the forces affecting the protein level variation. In this study, the relationship between allozyme heterozygosity and nucleotide diversity in plants is investigated among and within species. Allozyme and nucleotide diversity in 27 plant species was reviewed. At the multilocus level, the two methods are congruent: a clear correlation between the two measures of genetic diversity among plant species was observed, strengthening the view that effective population size is the major determinant of genome-wide diversity. Nucleotide diversity at six allozyme coding genes (6pgdB, aco, gdh, gotC, mdhA, and mdhB) in conifer Pinus sylvestris was investigated jointly with electrophoretic data. Single non-synonymous charge-changing mutations were found together with electrophoretic alleles that consequently were mutationally unique. Synonymous site nucleotide diversity (point estimate of θ _W—0.009 per bp) and silent site divergence from Pinus pinaster at allozyme coding loci were at comparable levels with other loci in the species. Linkage disequilibrium was extensive compared to earlier estimates from P. sylvestris and other trees, spanning several kilobases. Allozyme coding genes had an excess of closely related haplotypes whose frequency has recently increased possibly as a result of partial selective sweeps or balancing selection, but complex demographic effects cannot be excluded.     

Polymorphism of alcohol dehydrogenase in Arabidopsis thaliana (L.) heynh.: Genetical and biochemical characterization

Zymograms of Arabidopsis alcohol dehydrogenase (ADH; EC 1.1.1.1) show a unique anodal migrating band. Three electrophoretic variants were identified among geographical races and designated slow (S), fast (F), and superfast (A), according to their mobility on Tris-citrate starch gels. In plants ADH activity is confined mainly to pollen, seeds, and grains and rapidly declines during the germination process. In callus and suspension cultures, growing on media containing 2,4-D, ADH appeared as one of the major polypeptides. Genetical analysis indicated that the three types of ADH isozymes are under the control of one gene with three alles (Adh ₁ ^s , Adh ₁ ^f , Adh ₁ ^a ), showing codominant expression. Crosses between the electrophoretic types and dissociation-reassociation experiments showed that the Arabidopsis enzyme behaves as a dimer, like ADH from most other species. The molecular weight of the enzyme has been estimated by gel filtration and by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis to be 87,000. The pH optimum for the oxidation of ethanol is 9.0 and two optima for reduction of acetaldehyde have been obtained, 6.0 and 8.5, respectively. The enzyme exhibits a wide substrate specificity for alcohols and is relatively heat resistant.     

Structure,expression, chromosomal location and product of the gene encoding ADH1 inPetunia

A genomic clone for an alcohol dehydrogenase (Adh) gene has been isolated fromPetunia hybrida cv. V30 by screening aPetunia genomic library with a maizeAdh1 probe. A combination of RFLP and allozyme segregation data failed to demonstrate which of twoAdh loci, both of which map to chromosome 4, was the source of the cloned gene. The product of the cloned genes has been identified unequivocally by a transient expression assay inPetunia protoplasts. We have designated this genePetunia Adh1. The expression of this gene is tightly regulated in the developing anther, where its gene product is the predominant ADH isozyme. It is anaerobically inducible in roots, stems and leaves of seedlings. The induction of enzyme activity is correlated with induction ofAdh1 mRNA.     

Exploring the Evolutionary History of the Alcohol Dehydrogenase Gene (<Emphasis Type="Italic">Adh</Emphasis>) Duplication in Species of the Family Tephritidae

In the olive fruit fly Bactrocera oleae and the med fly Ceratitis capitata previous studies have shown the existence of two Adh genes in each species. This observation, in combination with the former finding that various Drosophila species of virilis and repleta group encode two isozymes of ADH which are the result of a gene duplication, challenged us to address a scenario dealing with the evolutionary history of the Adh gene duplication in Tephritidae. In our lab we proceeded to the cloning and sequence analysis of Adh genes from more tephritid species, a prerequisite for further study of this issue. Here we show that phylogenetic trees produced from either the nucleotide or the amino acid sequences of 14 tephritid Adh genes consisted of two main clusters, with Adh sequences of the same type grouping together (i.e., Adh1 sequences form a cluster and Adh2 sequences form a second one), as expected if there was one duplication event before speciation within the family Tephritidae. We used the amount of divergence between the two isozymic forms of Adh of the species carrying both Adh1 and Adh2 genes to obtain an estimate of the age of the duplication event. Interestingly, our data again support the hypothesis that the duplication of an ancestral Adh single gene in the family Tephritidae occurred before the emergence of the genera Bactrocera and Ceratitis, thus suggesting that Adh duplication was based on a prespeciation rather than a postspeciation event that might have involved two independent duplication events, one in each of the two genera.