Natural variants of pearl millet (Pennisetum typhoides) with altered levels of set II alcohol dehydrogenase activity

Two linked genes, Adh1 and Adh2, specify three sets of ADH isozymes in pearl millet. Set I is a homodimer specified by Adh1, Set III is a homodimer specified by Adh2, and Set II is a heterodimer consisting of one ADH1 subunit and one ADH2 subunit. Dry seeds exhibit only Sets I and II. Anaerobic treatment of seeds greatly increases the activity of Sets I and II and causes the Set III isozymes to be expressed. In the investigation reported here, the ADH zymogram phenotypes of 112 inbred pearl millet lines were analyzed. Two kinds of naturally occurring ADH variant strains were observed: in the low-activity variant, Set II activity is low in the dry seed, and no Set III activity is present upon anaerobic treatment. In the high-activity variant, Set II activity is high and Set III isozymes are expressed in the dry seed. The mutation in the high-activity strain appears to affect the product of Adh2 and not the product of Adh1. Dominance tests show that the mutations in both types of variant strains act in cis. These observations and linkage tests indicate that the mutations are closely linked to or at the Adh2 locus.This work was supported by a PHS National Research Service Award Training Grant in Genetics to the Biology Department of the University of Oregon.     

Linkage of the alcohol dehydrogenase structural genes in pearl millet (Pennisetum typhoides)

Pearl millet produces three ADH isozymes, Sets I, II, and III. Naturally occurring ADH electrophoretic variants affecting Sets I and II isozymes but not III have been previously described. Analysis of such variants led to the identification of the Adh1 structural gene. The existence of a second Adh structural gene was inferred from dissociation-reassociation studies of Set II. In the present report, a naturally occurring variant affecting the electrophoretic mobility of Sets III and II but not Set I is described. Analysis of this variant confirms the existence of a second structural gene, Adh2. Crosses utilizing this Adh2 marker reveal a dissimilarity with maize and other plants such as sunflower and narrow-leafed lupins. Adh1 and Adh2 of pearl millet do not segregate independently; indeed, no recombinants have been observed. This is the first major difference encountered in an otherwise remarkably similar genetic and environmental control of the ADH isozymes in maize and millet. The organization of the Adh genes of pearl millet may reflect a more primitive arrangement than that of maize.This work was supported by a PHS National Research Service Award Training Grant in Genetics to the Biology Department of the University of Oregon.     

Alcohol dehydrogenase isozymes in grain sorghum (Sorghum bicolor): Evidence for a gene duplication

Two sets of alcohol dehydrogenase (ADH) bands are regularly observed in grain sorghum (Sorghum bicolor): set I is a permanent triplet; set II is variable, as either two or three bands. A faint set III is detected only when extracts from seeds subjected to anerobiosis are run in neutralpH gels. Dissociation-reassociation experiments reveal that the central band of the set I triplet is a heterodimer of the other two. Full-sib progeny analysis from selfed plants shows that the set II bands are doublets, with heterozygotes having only three apparent bands instead of four because of the similar mobilities of the fast-migrating isozyme specified by the slow allele and the slow isozyme specified by the fast allele. We propose a three-locus model as the best explanation of these patterns. Set I consists of the products of two loci and their intergenic heterodimer. Set III is specified by a third locus. Set II isozymes are the intergenic heterodimers of the two set I loci and the set III locus. This explanation is similar to that of Schwartz and Freeling for maize but suggests that the evolution ofSorghum includes a gene duplication of the homologue of theAdh-1 locus inZea. Supported by USDA Grant 59-2063-01522 to NCE and KWF.     

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.     

Catalytic properties of alcohol dehydrogenase isozymes specified by duplicate genes in the diploid plant Stephanomeria exigua

The alcohol dehydrogenase (ADH) isozymes induced in flooded roots of the diploid plant Stephanomeria exigua are specified by tightly linked genes comprising a complex locus, Adh1. Individuals homozygous for a complex with two active genes which specify electrophoretically different subunits have three ADH-I isozymes, two intragenic homodimers and an intergenic heterodimer. Individual isozymes were partially purified from plants homozygous for several different Adh1 complexes and apparent K _m values for acetaldehyde, ethanol, NAD, and NADH and responses to temperature, pH, and two different alcohols were determined. The two homodimeric enzymes specified by a particular Adh1 complex generally differed in one or more of the properties studied, and in three of four cases, intergenic heterodimers differed significantly from intermediacy, often having lower K _m values than either homodimer. None of the isozymes studied could be considered greatly divergent or defective. Constraints on evolution of duplicate genes which form intergenic heterodimers are considered.     

Dimerization of multiple maize ADHs studied in vivo and in vitro

Anaerobically induced primary roots simultaneously express two alcohol dehydrogenase (Adh) genes which specify three types of electrophoretically separable dimers: Set I, II, and III ADH. The S inbred line yields a particular activity ratio among these three sets. By use of an Adh ₁ ^null mutant allele and in vitro chemical dissociation and reassociation of ADH dimers, these studies extrapolate from an ADH activity ratio to the actual ratio of ADH protein. Conclusions are that (1) ADH₁ and ADH₂ promoters dimerize randomly in vivo and in vitro, (2) the heterodimeric isozyme (Set II) is approximately the enzymological sum of its subunits under these assay conditions, and (3) ADH-2 subunits are from 10 to 20% as active as ADH₁ subunits under these assay conditions. These conclusions imply that the unlinked Adh genes are coordinately regulated and reconfirm the two-gene-three-dimer model for the maize ADH isozymes.     

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 in the Diploid Plant STEPHANOMERIA EXIGUA (Compositae): Gene Duplication, Mode of Inheritance and Linkage

Study of the biochemical genetics of alcohol dehydrogenase (ADH) in the annual plant Stephanomeria exigua (Compositae) revealed that the isozymes are specified by a small family of tightly linked structural genes. One set of ADH isozymes (ADH-1) was induced in roots by flooding, and was also expressed in thickened unflooded tap roots, stems, ovaries and seeds. As in other plants, the enzymes are dimeric and form homo- and heterodimers. An electrophoretic survey of ADH-1 phenotypes in two natural populations revealed seven different ADH-1 homodimers in various phenotypes having one to eight enzyme bands. Genetic analysis of segregations from crosses involving 59 plants showed that the ADH-1 isozymes are inherited as a single Mendelian unit, Adh1. Adh1 is polymorphic for forms that specify one, two, or three different ADH-1 subunits (which combine to form homo- and heterodimers), and are expressed co-dominantly in all genotypic combinations. Staining intensity of enzymes extracted from various homozygous and heterozygous plants indicated that the different subunit types specified by Adh1 are produced in approximately equal amounts. These observations suggest that Adh1 is a compound locus consisting of one to several tightly linked (0 recombinants among 579 testcross progeny), coordinately expressed structural genes. The genes in the two triplications also occur in various duplicate complexes and thus could have originated via unequal crossing over. The ADH-2 isozyme found in pollen and seeds is apparently specified by a different gene, Adh2. Adh1 and Adh2 are tightly linked (0 recombinants among 81 testcross progeny).     

Regulated expression of three alcohol dehydrogenase genes in barley aleurone layers

Three genes specify alcohol dehydrogenase (EC 1.1.1.1.; ADH) enzymes in barley (Hordeum vulgare L.) (Adh 1, Adh 2, and Adh 3). Their polypeptide products (ADH 1, ADH 2, ADH 3) dimerize to give a total of six ADH isozymes which can be resolved by native gel electrophoresis and stained for enzyme activity.

Under fully aerobic conditions, aleurone layers of cv Himalaya had a high titer of a single isozyme, the homodimer containing ADH 1 monomers. This isozyme was accumulated by the aleurone tissue during the later part of seed development, and survived seed drying and rehydration. The five other possible ADH isozymes were induced by O₂ deficit. The staining of these five isozymes on electrophoretic gels increased progressively in intensity as O₂ levels were reduced below 5%, and were most intense at 0% O₂.

In vivo³⁵S labeling and specific immunoprecipitation of ADH peptides, followed by isoelectric focusing of the ADH peptides in the presence of 8 molar urea (urea-IEF) demonstrated the following. (a) Aleurone layers incubated in air synthesized ADH 1 and a trace of ADH 2; immature layers from developing seeds behaved similarly. (b) At 5% O₂, synthesis of ADH 2 increased and ADH 3 appeared. (c) At 2% and 0% O₂, the synthesis of all three ADH peptides increased markedly.

Cell-free translation of RNA isolated from aleurone layers, followed by immunoprecipitation and urea-IEF of in vitro synthesized ADH peptides, showed that levels of mRNA for all three ADH peptides rose sharply during 1 day of O₂ deprivation. Northern hybridizations with a maize Adh 2 cDNA clone established that the clone hybridized with barley mRNA comparable in size to maize Adh 2 mRNA, and that the level of this barley mRNA increased 15- to 20-fold after 1 day at 5% or 2% O₂, and about 100-fold after 1 day at 0% O₂.

We conclude that in aleurone layers, expression of the three barley Adh genes is maximal in the absence of O₂, that regulation of mRNA level is likely to be a major controlling factor, and that whereas the ADH system of barley has strong similarities to that of maize, it also has some distinctive features.

     

The expression and anaerobic induction of alcohol dehydrogenase in cotton

The alcohol dehydrogenase (ADH) system in cotton is characterized, with an emphasis on the cultivated allotetraploid speciesGossypium hirsutum cv. Siokra. A high level of ADH activity is present in seed of Siokra but quickly declines during germination. When exposed to anaerobic stress the level of ADH activity can be induced several fold in both roots and shoots of seedlings. Unlike maize andArabidopsis, ADH activity can be anaerobically induced in mature green leaves. Three major ADH isozymes were resolved in Siokra, and it is proposed that two genes,Adh1 andAdh2, are coding for these three isozymes. The genes are differentially expressed. ADH1 is predominant in seed and aerobically grown roots, while ADH2 is prominent in roots only after anaerobic stress. Biochemical analysis demonstrated that the ADH enzyme has a native molecular weight of approximately 81 kD and a subunit molecular weight of approximately 42 kD, thus establishing that ADH in cotton is able to form and is active as dimers. Comparisons of ADH activity levels and isozyme patterns between Siokra and other allotetraploid cottons showed that the ADH system is highly conserved among these varieties. In contrast, the diploid species of cotton all had unique isozyme patterns.This work was generously supported by an Australian Cotton Research Council Postgraduate Studentship.     

Biochemical properties and level of expression of alcohol dehydrogenases in the allotetraploid plant Tragopogon miscellus and its diploid progenitors

This study demonstrates that homoeologous genes in two diploid plant species that specify different amounts of an enzyme maintain the same relative level of expression in an allotetraploid derivative. The three predominant alcohol dehydrogenase (ADH) isozymes (DD, DP, PP) in seeds of the recently evolved allotetraploid plant Tragopogon miscellus (Compositae) are dimers specified by Adh3-D and Adh3-P genes derived from its diploid progenitors T. dubius and T. pratensis. Seeds of T. pratensis contain twice as much ADH activity as those of T. dubius, while T. miscellus is intermediate. The three isozymes were similar in a number of catalytic properties; the densitometric ratio of the isozymes purified from T. miscellus was 1 DD:4DP:4PP for both ADH activity and protein; and dissociation-reassociation of the DP enzyme gave a 1:2:1 ratio of the three isozymes. Therefore, the enzymes were similar in specific activity, but twice as many P as D subunits were present in active enzymes in T. miscellus, precisely the difference in activity between the parents. In T. miscellus, the specific activity of ADH and its activity per mg tissue are intermediate to those of the diploids, because relative expression of the Adh gene in each genome is not influenced by the presence of the other genome.     

Rabbit liver alcohol dehydrogenase: isolation and characterization of class I isozymes

Livers of rabbits contain three classes of alcohol dehydrogenase (ADH) isozymes which are highly analogous to the human classes. Class I ADHs migrate toward cathode on starch gel and are very sensitive to 4-methylpyrazole (4-MePz) inhibition. Class II ADH migrates slowly toward anode and is less sensitive to 4-MePz. Class III ADH migrates rapidly toward anode and is insensitive to 4-MePz. There are one class II, one class III and at least three class I ADH isozymes present in the rabbit liver. The three class I isozymes purified to homogeneity are all dimers with subunit molecular weight of 41700. Two are heterodimers composed of A-, C-chains and B-, C-chains, respectively. The third one is a homodimer, contains only the C-chain. These results indicate that among all the mammals examined, rabbit ADH bears the greatest resemblance to the human enzyme.     

The effect of insertion of the maize transposable elementMutator is dependent on genetic background

A secondary mutant, derived from an allele of maize alcohol dehydrogenase 1 (Adh1) carrying a Mutator transposable element (Mu1) in its first intron, was reported to exhibit a threefold decrease in ADH enzymatic activity and steady-state RNA levels compared to the original mutant. The original mutant,Adh1-S3034 (abbreviatedS3034), was previously characterized at the molecular level. The derivative, abbreviatedS3034b, has now been cloned; at the DNA sequence level the insertion and surroundingAdh1 sequences are indistinguishable fromS3034. Furthermore, in our lines there is no difference in relative ADH activities between products of the two putative alleles. A comparison of gene expression in heterozygotes obtained by crossing to different tester lines reveals a correlation between the measured decrease in levels of ADH polypeptide produced by the mutant allele and the background in which it is measured; this effect is distinct from any background-related variation in the expression of the progenitor allele. It does not appear to be attributable to alternative patterns of DNA modification. It appears to reflect a background-associated difference in the level of normalAdh1-RNA produced. Thus the previously reported distinction betweenS3034 andS3034b may be due to differences in the extent to which the mutant allele and a given genetic background interact to produce functionalAdh1-RNA.This research was supported by United States Public Health Service Grant GM38616 and United States Department of Agriculture Grant 87-CRCR-1-2500 to J.S. D.O. was supported by an NIH predoctoral training grant to the Department of Genetics.     

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.     

Genetic variation in the carbonic anhydrase isozymes of macaque monkeys. II. Inheritance of red cell carbonic anhydrase levels in different carbonic anhydrase I genotypes of the pig-tailed macaque,Macaca nemestrina

The inheritance of red blood cell levels of carbonic anhydrase isozymes (CA I and CA II) has been studied in different carbonic anhydrase I genotypes of the pig-tailed macaque, Macaca nemestrina. Quantitation of CA I isozymes in a series of animals indicates that the total CA I concentration is the sum of the average effects of each CA I structural allele and that the average effects are independent of the various allelic combinations. The relative average effects were 0.32:0.95:1.0 for the CA I ^a, CA I^b, and CA I ^c structural genes, respectively. It is also demonstrated that the level of CA II is related to the CA I genotypes. Multiple regression analysis demonstrated that each dose of CA I-deficiency gene present decreased the CA II concentration by approximately 30%, with this decrease in CA II level being solely related to the dose of CA I-deficiency gene and not to the level of CA I. The CA I-deficient animals produce CA I products that are similar to the common CA Ia, CA Ib, CA Ic electrophoretic types. Limited mating data indicate that the CA I components in CA I-deficient animals are inherited codominantly.Supported by U.S. Public Health Service Research Grant GM-15419.This report is a portion of a dissertation submitted to the University of Michigan in partial fulfillment of the requirements for the Doctor of Philosophy degree.U.S. Public Health Service Predoctoral Trainee (GM-71-14).     

Interpretation of triose phosphate isomerase isozymes in the cherimoya (Annona cherimola Mill.)

Detailed interpretation of triose phosphate isomerase (TPI) isozymes in seed plants has been restricted to only a few species. Three sets of TPI bands are regularly observed in the cherimoya(Annona cherimola), a primitive angiosperm. The slowest, set I, is expressed as one or three bands; the second-slowest set II, as one or two bands; and the fastest, set IV, as one or three bands. A faint set III, just cathodal to set IV, is detected rarely with overstaining. Set IV bands are expressed in macerated extracted pollen but not in pollen leachate. Dissociation-reassociation experiments reveal that the set II bands are heterodimers involving, in part, the enzymes involved in the set I bands. These data combined with those from full-sib progeny analysis lead us to propose a three-locus model to explain the TPI isozyme banding patterns in cherimoya. Sets I and IV consist of the allelic products of individual, single loci. Sets I and II occur in the cytoplasm. Set IV occurs in organelles. Set II isozymes are the intergenic heterodimers of the locus coding for set I and the locus coding for set III. Our results reported here are contrasted with the TPI isozyme patterns known for other vascular plants and suggest that the locus coding for set III may be a duplication of very ancient origin.This work was supported, in part, by funding from the Elvenia J. Slosson Endowment Fund.     

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.     

Properties of three sets of isoenzymes of alcohol dehydrogenase isolated from barley (Hordeum vulgare)

Three sets of isoenzymes of alcohol dehydrogenase were separated from root and shoot tissue of Hordeum vulgare by DEAE-cellulose chromatography. Set I showed only one band of ADH activity after polyacrylamide gel electrophoresis; Set II—two and Set III—three, making a total of six discernable bands. Only one set (I) was detected in the dry seed and one set (III) in the M9 (Adh-1-null) mutant available in tissue culture. The sets were found to have identical molecular weights (90 000), were all located in the cytoplasm but showed small differences in pH optima and substrate specificity. The affinity for ethanol (K_m value, mM) varied between Set I (27.5), Set II (7.2) and Set III (3.5), whilst the affinity for NADH varied five-fold between the three sets. A dimeric quaternary structure was inferred from the random reassociation of enzyme subunits after dissociation in high ionic strength buffer.     

An intergenic alcohol dehydrogenase isozyme in sunflowers

The isozymes of alcohol dehydrogenase (ADH; E.C. 1.1.1.1) in wild and cultivated sunflower (Helianthus annuus) seeds can be resolved electrophoretically into 12 bands. The slowest- and probably the fastest-migrating sets of three are allozymic products of two genes, Adh ₁ and Adh ₂ , each having two alleles, F (for fast) and S (for slow). Evidence from dissociation-recombination experiments utilizing bands excised from starch gels indicates that an intermediately-migrating isozyme is a dimeric intergenic product consisting of ADH-1F and ADH-2S subunits. The hybrid isozyme was unstable in vitro in that its monomers spontaneously dissociated and recombined to produce ADH-1FF and ADH-2SS isozymes. The molecular weights of the hybrid as well as the parental isozymes were estimated at approximately 98,000.Supported by a Graduate School Research grant of the University of Kansas and by NSF grant GB-35853.