Expression of the enzyme-encoding genes under the influence of colchicine and triton X-100 in nongerminating seeds of sugarbeet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.)

The expression of the enzyme-coding genes, controlling glucose-phosphate isomerase (GPI), malate dehydrogenase (MDH), and alcohol dehydrogenase (ADH), was examined in nongerminating seeds of sugarbeet after Triton X-100 (TX-100) and colchicine treatment. Two types of changes revealed included modification of the enzymatic loci expression (change of the isozyme electrophoretic mobility) and inactivation of standard profiles. In the MDH and GPI systems, these processes were found to be associated. Complete isozyme modification was accompanied with the disappearance of standard profiles. In the ADH system, the treatment with TX-100 and colchicine gave rise to two independent processes, including silencing of the Adh1 locus and the appearance of the ADH isozymes with abnormal electrophoretic mobility, which were probably the products of the Adh2 locus. It was suggested that the effect of TX-100 and colchicine on the expression of the enzyme-encoding genes examined depended on the intracellular localization of the encoded enzymes.     

Isozyme analysis in a genetic collection of amaranths (Amaranthus L)

In various populations of the cultivated and weedy amaranth species, the electrophoretic patterns of alcohol dehydrogenase (ADH), glutamate dehydrogenase (GDH), malate dehydrogenase (MDH), isocitrate dehydrogenase (IDH) and malic enzyme (Me) were studied. In total, 52 populations and two varieties (Cherginskii and Valentina) have been examined. Allozyme variation of this material was low. Irrespective of species affiliation, 26 populations and two varieties were monomorphic for five enzymes; a slight polymorphism of three, two, and one enzymes was revealed in three, nine, and fourteen populations, respectively. A single amaranth locus, Adh, with two alleles, Adh F and Adh S, controls amaranth ADH. Two alleles, common Gdh S and rare Gdh F, control GDH; no heterozygotes at this locus were found. The MDH pattern has two, the fast- and slow-migrating, zones of activity (I and II, respectively). Under the given electrophoresis conditions, the fast zone is diffuse, whereas slow zone is controlled by two nonallelic genes, monomorphic Mdh 1 and polymorphic Mdh 2 that includes three alleles: Mdh 2-F, Mdh 2-N, and Mdh 2-S. Low polymorphism of IDH and Me was also found, though their genetic control remains unknown.     

Isozyme Analysis in a Genetic Collection of Amaranths (<Emphasis Type="Italic">Amaranthus</Emphasis> L.)

In various populations of the cultivated and weedy amaranth species, the electrophoretic patterns of alcohol dehydrogenase (ADH), glutamate dehydrogenase (GDH), malate dehydrogenase (MDH), isocitrate dehydrogenase (IDH) and malic enzyme (Me) were studied. In total, 52 populations and two varieties (Cherginskii and Valentina) have been examined. Allozyme variation of this material was low. Irrespective of species affiliation, 26 populations and two varieties were monomorphic for five enzymes; a slight polymorphism of three, two, and one enzymes was revealed in three, nine, and fourteen populations, respectively. A single amaranth locus, Adh, with two alleles, Adh F and Adh S, controls amaranth ADH. Two alleles, common Gdh S and rare Gdh F, control GDH; no heterozygotes at this locus were found. The MDH pattern has two, the fast- and slow-migrating, zones of activity (I and II, respectively). Under the given electrophoresis conditions, the fast zone is diffuse, whereas slow zone is controlled by two nonallelic genes, monomorphic Mdh 1 and polymorphic Mdh 2 that includes three alleles: Mdh 2-F, Mdh 2-N, and Mdh 2-S. Low polymorphism of IDH and Me was also found, though their genetic control remains unknown.     

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.     

Polymorphism of PCR profiles and expression of alleles at the locus Adh1 in agamospermous progeny of beet root Beta vulgaris L

A modification of the ISSR amplification method based on using a combination of microsatellite and specific unique primer is proposed and tested. This modification simplifies the detected PCR profiles and allows the examination of DNA regions containing definite genes. Combinations of microsatellite primer Mic2 (5'-gacag-acaga-cagac-a-3') and one of the primers specific to the Adh1 locus, which controls alcohol dehydrogenase (ADH1) in sugar beet, were employed in this work. The microsatellite primer was used in combination with the following specific primers: Adh1f (5'-agagt-gttgg-agagg-gtgtg-ac-3') containing the binding site at the fourth exon of gene Adh1, or Adh1r (5'-act(ct)a-cagca-ag(ct)cc-(ct)ac(ct)g-ctcc-3') that binds to the fifth exon of the same gene. In the agamospermous progeny of individual heterozygous diploid plants of sugar beet with the Adh1-F/Adh1-S genotype, polymorphism of PCR profiles obtained in plants of each of three phenotypic classes (FF, FS, and SS) was detected. Among plants of the progeny from an individual plant that represents the heterozygous phenotypic class FS, differences were revealed not only between the PCR profiles but also in the relative activity of allele isozymes of ADH1.     

Molecular differences in Adh1-F and Adh1-S alleles in the sugar beet Beta vulgaris L

We compared nucleotide sequences of exon 4 and part of exon 5 of alleles F and S of the Adh1 locus controlling alcohol dehydrogenase in sugar beet. The Adh1-F and Adh1-S sequences of the examined fragment were shown to differ by two nucleotides. Adenine (A) and cytosine (C) of Adh1-F were substituted by respectively thymine (T) and adenine (A) in Adh1-S. Consequently, glutamine and asparagine from the F subunit of ADH1 are replaced by valine and lysine, respectively. Because of differences in the amino acid content, the F subunit is by two elementary charges more negatively charged electrically than the S subunit, which correlates with differences in their electrophoretic mobility. Comparison of the examined Adh1 fragment of sugar beet with its counterparts in other plants showed that the sites bearing substitutions in the former species are classed as variable.     

The ADH gene-enzyme system and the fitness of Drosophila melanogaster mutants]

Physico-chemical properties of ADH and some fitness parameters were examined in two mutant (cn and vg) and two wild-type (C-S and D) strains of Drosophila melanogaster. It was shown that, under the experimental conditions, longevity, fecundity and heat resistance did not depend on the activity and the electrophoretic mobility of enzymes. The Adh gene-enzyme system of the mutants was analyzed in relation to the saturation of their genotypes with genes of wild-type flies having different allelic control of the enzyme. ADH activity was shown to be positively correlated with the frequency of F allele of the structural gene (r = 0.84), whereas thermostability of the enzyme was not associated with electrophoretic mobility. Low thermostability of ADH in vg mutants, which was correlated with low heat resistance (r = 0.94), is assumed to be controlled by the thermostable allele Adh Fs.     

Variation between electrophoretically identical alleles at the alcohol dehydrogenase locus in Drosophila melanogaster

A new variant of alcohol dehydrogenase (ADH 7lk) was found in a laboratory stock of Drosophila melanogaster. ADH in this stock had the same electrophoretic mobility as the F variant both on acrylamide and on agar. Activity levels were similar to the levels in F flies at temperature between 15 and 25 C. But while ADH F enzyme is inactivated rapidly at 40 C, ADH 7lk is still active. Also, ADH S is not inactivated at this temperature, but has a far lower activity per fly than ADH 7lk. Genetic analysis showed that the new variant is an allele of the Adh locus.     

Polymorphism of PCR profiles and expression of alleles at the locus <Emphasis Type="Italic">Adh1</Emphasis> in agamospermous progeny of sugar beet <Emphasis Type="Italic">Beta vulgaris</Emphasis> L.

A modification of the ISSR amplification method based on using a combination of microsatellite and specific unique primer is proposed and tested. This modification simplifies the detected PCR profiles and allows the examination of DNA regions containing definite genes. Combinations of microsatellite primer Mic2 (5′-gacag-acaga-cagac-a-3′) and one of the primers specific to the Adh1 locus, which controls alcohol dehydrogenase (ADH1) in sugar beet, were employed in this work. The microsatellite primer was used in combination with the following specific primers: Adh1f (5′-agagt-gttgg-agagg-gtgtg-ac-3′) containing the binding site at the fourth exon of gene Adh1, or Adh1r (5′-act(ct)a-cagca-ag(ct)cc-(ct)ac(ct)g-ctcc-3′) that binds to the fifth exon of the same gene. In the agamospermous progeny of individual heterozygous diploid plants of sugar beet with the Adh1-F/Adh1-S genotype, polymorphism of PCR profiles obtained in plants of each of three phenotypic classes (FF, FS, and SS) was detected. Among plants of the progeny from an individual plant that represents the heterozygous phenotypic class FS, differences were revealed not only between the PCR profiles but also in the relative activity of allele isozymes of ADH1.     

Molecular analysis of alcohol dehydrogenase electromorphs in wild type and transformed Drosophila melanogaster

The protein expressed by the alcohol dehydrogenase locus (Adh) in D. melanogaster comprises a small group of electromorphs. We are able to study the expression of these electromorphs by electrophoretic separation and subsequent probing of blots of the separated polypeptides with antiserum for alcohol dehydrogenase (ADH). In the present study we have utilized this technique to study and compare the ADH electromorphs in wild type D. melanogaster with D. melanogaster transformants which carry an Adh gene from D. grimshawi, D. hawaiiensis or D. affinidisjuncta and produced functional ADH (10, 19). We have determined that polypeptides are produced by the donor loci in the transformed flies and further show that although the molecular weight of the expressed polypeptides is similar to D. melanogaster electromorphs, the isoelectric points are not similar. Thus this methodology offers the potential to study naturally occurring ADH electromorphs and null alleles independent of enzymatic activity assays.     

Differences in isoenzyme patterns of axenically and monoxenically grown Acanthamoeba and Hartmannella

Axenically and monoxenically grown Acanthamoeba castellanii, Acanthamoeba polyphaga and different isolates of Hartmannella vermiformis strains were examined by polyacrylamide isoelectric focusing in the pH range 3–10. Isoenzyme patterns of acid phosphatase (AP), propionyl esterase (PE), malate dehydrogenase (MDH), alcohol dehydrogenase (ADH), glucose phosphate isomerase (GPI) and phosphoglucomutase (PGM) were compared. Zymograms were used to reveal differences in typical isoenzyme patterns between axenically and monoxenically grown amoebae and to compare axenically grown A. castellanii, A. polyphaga and H. vermiformis. Comparison of zymograms for AP, PE and MDH between axenically grown Acanthamoeba and Hartmannella strains revealed different isoenzyme patterns. Acanthamoeba showed strong bands for ADH and extremely weak bands for GPI and PGM, while Hartmannella lacked ADH but possessed bands for GPI and PGM.\par Comparison of zymograms from axenically and monoxenically grown amoebae revealed a lower intensity and even lack of typical isoenzyme bands in lysates from monoxenic cultures. The observed changes in typical isoenzyme patterns induced by the bacterial substrate can influence the correct isoenzymatic typing of different strains in clinical and phylogenetic studies.     

Molecular Differences between Alleles Adh1-F and Adh1-Sin Sugar Beet Beta vulgaris L.

We compared nucleotide sequences of exon 4 and part of exon 5 of alleles F and S of the Adh1 locus controlling alcohol dehydrogenase in sugar beet. The Adh1-F and Adh1-S sequences of the examined fragment were shown to differ by two nucleotides. Adenine (A) and cytosine (C) of Adh1-F were substituted by respectively thymine (T) and adenine (A) in Adh1-S. Consequently, glutamine and asparagine from the F subunit of ADH1 are replaced by valine and lysine, respectively. Because of differences in the amino acid content, the F subunit is by two elementary charges more negatively charged electrically than the S subunit, which correlates with differences in their electrophoretic mobility. Comparison of the examined Adh1 fragment of sugar beet with its counterparts in other plants showed that the sites bearing substitutions in the former species are classed as variable.     

Molecular analysis of a somaclonal mutant of maize alcohol dehydrogenase

Summary Plants regenerated from tissue cultures of maize were screened for variants of ADH1 and ADH2. Root extracts of 645 primary regenerant plants were tested, and one stable mutant of Adh1 was detected. The mutant gene (Adh1-Usv) produces a functional enzyme with a slower electrophoretic mobility than that of the progenitor Adh1-S allele, and is stably transmitted to progeny. The mutant was not present among four other plants derived from the same immature embryo, and therefore arose as a consequence of the culture procedure. The gene of Adh1-Usv was cloned and sequenced. A single base change in exon 6 was the only alteration found in the gene sequence. This would translate in the polypeptide sequence to a valine residue substituting for a glutamic acid residue, resulting in the loss of a negative charge and the production of a protein with slower electrophoretic mobility.Abbreviations kb kilobase pairs - ADH alcohol dehydrogenase     

Identification of a genetic element that controls the organ-specific expression of adh1 in maize

Allozyme balances serve as markers of quantitative behavior of electrophoretically distinguishable alleles. By the use of ADH Set I allozyme balances, it is demonstrated that all Adh1-S/Adh1-F individuals from more than 20 diverse S/F families exhibit a reciprocal correlation between Adh1 quantitative behavior in two maize organs: the scutellum and primary root. Within an electrophoretic mobility class, the Adh1 allele that is relatively underexpressed in the scutellum is relatively overexpressed in the primary root, and vice versa. Segregation tests prove that this "reciprocal effect" is the property of a cis-acting site that is closely linked to or within the Adh1 structural gene, and it is not affected by diverse genetic backgrounds. Immunological and [(3)H]-leucine incorporation experiments establish that Adh1 quantitative variants differ in ADH1.ADH1 synthetic rates in the anaerobic primary root. The reciprocal-effect phenomenon suggests that the cis-acting loci controlling Adh1 quantitative expression in each respective organ are at least in close proximity, or may share common DNA sequences. We discuss the possibility that the reciprocal-effect locus is a regulatory component of the Adh1 cistron.     

Dynamics of Correlated Genetic Systems. IV. Multilocus Effects of Ethanol Stress Environments

Four replicate populations of Drosophila melanogaster, two reared on medium supplemented with ethanol and two reared on standard medium, were electrophoretically monitored for 28 generations. During the first 12 generations, allelic, genotypic and gametic frequencies were determined for eight polymorphic enzymes: GOT, alpha-GPDH, MDH, ADH, TO, E6, Ec and ODH. Samples from generation 18 and 28 were electrophoretically typed for ADH and alpha-GPDH. In addition, samples from generation 27 were analyzed for the presence of inversion heterozygotes. The experimental results showed rapid gene-frequency divergence between control and treatment populations at the Adh locus in a direction consistent with the activity hierarchy of Adh genotypes. Gene-frequency divergence between control and treatment populations also occurred at the alpha-Gpdh locus, although the agreement among replicates appeared to have broken down by generation 28. No differential gene-frequency change occurred at any of the six remaining marker loci. Furthermore, values of linkage disequilibria among all linked pairs of genes were initially small and remained small throughout the course of the experiment. Taking these facts into account, it is argued that the gene-frequency response observed at ADH is most probably caused by selection at the Adh locus. The gene frequency response at alpha-Gpdh can also be be accounted for in terms of the effect of ethanol on energy metabolism, although other explanations cannot be excluded.     

Molecular Genetic Characterization of a Locus That Contains Duplicate Adh Genes in DROSOPHILA MOJAVENSIS and Related Species

Drosophila mojavensis and other species of the mulleri subgroup contain a duplicate gene encoding the enzyme alcohol dehydrogenase (ADH). Studies on the genetic relationship of the two genes using electrophoretic variants show them to be closely linked. We have cloned a 13.5-kb fragment of D. mojavensis DNA into the lambda vector, Charon 30. This fragment contains both Adh genes separated by approximately 2 kb of DNA. The clone hybridized to a single position on chromosome 3 in D. mojavensis following in situ hybridization. It is likely that the genes are tandemly arranged in the genome. One of the two genes shows a complexity in its structure that suggests the close linkage of a pseudogene or part of a gene. The structure of the Adh locus in five species of the mulleri subgroup have been compared by constructing restriction maps of genomic DNA. Two of these species D. arizonensis and D. mojavensis express Adh-1 in the ovaries; the others do not. In comparing these species it is evident that there has been one or two insertions into the region between the Adh genes. It is possible that one of these structural changes is related to the change in Adh tissue-specific expression that has occurred during the evolution of these species.     

Regulatory elements involved in Drosophila Adh gene expression are conserved in divergent species and separate elements mediate expression in different tissues.

Alcohol dehydrogenase (ADH) is expressed in a complex temporal and spatial pattern from tandem promoters (proximal and distal) in Drosophila melanogaster, and from two closely linked genes (Adh-1 and Adh-2) in D. mulleri. The expression patterns of Adh-1 and the proximal promoter, and Adh-2 and the distal promoter are similar, but not identical. We show that the mulleri Adh genes are appropriately expressed when introduced into the melanogaster genome, indicating that the cis- and trans-acting elements which regulate the corresponding promoters are functionally equivalent in the two species. By analyzing the expression of in vitro generated mutants of the mulleri Adh locus, we define at least three regulatory regions of the mulleri Adh genes and show that different control elements mediate the expression of Adh in different tissues.     

Inheritance and expression of gametophyte gene Adh-P causing modification of alcohol dehydrogenase in pollen grains of the beet (Beta vulgaris L.)

An additional alcohol dehydrogenase (ADH) activity zone denoted ADH-P ("pollen") has a slightly lower mobility than the major protein ADH1 (the product of structural locus Adh1). This zone is detected in maturing and mature pollen grains and has not been found in any other tissue. ADH-P is detected by electrophoresis in a neutral medium (at pH 7.0-7.2). In an alkaline medium (pH > 8), protein ADH-P is completely inactivated, whereas protein ADH1 retains its activity. ADH-P is a modified variant of the major protein ADH1. Both alleles of the main structural gene (Adh1-F and Adh1-S) undergo modification. The pollen of an FS heterozygote has two variants of the modified enzyme: ADH-PS and ADH-PF. Analysis of segregation in F2 offsprings and test crosses has confirmed that this character is controlled by the only gene Adh-P with allelic variants Adh-P+ (the presence of the modified ADH protein in the pollen) and Adh-P- (the normal protein). Allele Adh-P+ is transmitted through female gametes at a normal frequency (about 1) and through male gametes at a decreased frequency (0.2-0.6), the mean frequency being about 0.4. The frequency of the transmission of allele Adh-P+ through male gametes depends on the genotype of the female parent and the conditions of pollination. Cytoembryological study of microsporogenesis in the Adh-P+/Adh-P- heterozygotes demonstrated an absence of any disturbances in the formation of microspores and pollen grains. Some differences in the formation of pollen tubes on an artificial medium have been observed. It is assumed that the differences between the Adh-P+ and Adh-P- microgametophytes manifest themselves at the progamic phase of fertilization. The possible mechanisms of the formation of the modified ADH-P protein are discussed in connection with the differential activity of genes in the microgametophytes of angiosperms.     

Three alcohol dehydrogenase genes in wild and cultivated barley: Characterization of the products of variant alleles

Barley (Hordeum vulgare) and its wild progenitor (H. spontaneum) have three loci for alcohol dehydrogenase (EC 1.1.1.1; ADH). The Adh1 locus is constitutively expressed in seed tissues, whereas expression of the loci Adh2 and Adh3 requires anaerobic induction. The Adh3 gene is well expressed in aleurone and embryo tissues kept under N₂ for 2–3 days. Using N₂-treated embryos, a diverse collection of H. spontaneum was screened in starch gels for electrophoretic variants at the Adh3 locus. Four variants were found: two were conventional mobility variants (Adh3 S, Adh3 V); one was a null variant (Adh3 n); and the fourth (Adh3 I) variant lacked active homodimers and showed reduced heterodimer activity. The ³⁵S-labeled monomers induced under N₂ in the lines homozygous for Adh1, Adh2, or Adh3 variants were immunoprecipitated with antiserum raised against maize ADH. Fluorography after separation by SDS-PAGE and by urea-isoelectric focusing indicated that the Adh3 n allele was CRM- and that the Adh3 I gene product was smaller than normal. The Adh1 and Adh3 variants showed independent segregation.