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Three alcohol dehydrogenase (ADH) genes have recently been characterized in the yeast Kluyveromyces lactis. We report on a fourth ADH in K. lactis (KADH II: KADH2* gene) which is highly similar to other ADHs in K. lactis and Saccharomyces cerevisiae. KADH II appears to be a cytoplasmic enzyme, and after expression of KADH2 in S. cerevisiae enzyme activity comigrated with a K. lactis ADH present in cells grown in glucose or in ethanol. KADH I was also expressed in S. cerevisiae and it comigrated with a major ADH species expressed under glucose growth conditions in K. lactis. The substrate specificities for KADH I and KADH II were shown to be more similar to that of SADH II than to SADH I. SADH I cannot efficiently utilize long chain alcohols, in contrast to other cytoplasmic yeast ADHs, presumably because of the presence of a methionine (residue 271) in its substrate binding cleft. A comparison of the DNA sequences of ADHs among K. lactis, S. cerevisiae and Schizosaccharomyces pombe suggests that the ancestral yeast species contained one cytoplasmic ADH. After divergence from S. pombe, the ADH in the ancestor to K. lactis and S. cerevisiae was duplicated, and one ADH became localized to the mitochondrion, presumably for the oxidative use of ethanol. Following the speciation of S. cerevisiae and K. lactis, the gene encoding the cytoplasmic ADH in S. cerevisiae duplicated, which resulted in the development of the SADH II protein as the primary oxidative enzyme in place of SADH III. In contrast, the K. lactis mitochondrial ADH duplicated to give rise to the highly expressed KADH3 and KADH4 genes, both of which may still play primary roles in oxidative metabolism. These data suggest that K. lactis and S. cerevisiae use different compartments for their metabolism of ethanol. Our results also indicate that the complex regulatory circuits controlling the glucose-repressible SADH2 in S. cerevisiae are a recent acquisition from regulatory networks used for the control of genes other than SADH2.
Mol Gen Genet 1992 Apr
PMID:Evolution of the alcohol dehydrogenase (ADH) genes in yeast: characterization of a fourth ADH in Kluyveromyces lactis. 158 17

Sequences of 47 members of the Zn-containing alcohol dehydrogenase (ADH) family were aligned progressively, and an evolutionary tree with detailed branch order and branch lengths was produced. The alignment shows that only 9 amino acid residues (of 374 in the horse liver ADH sequence) are conserved in this family; these include eight Gly and one Val with structural roles. Three residues that bind the catalytic Zn and modulate its electrostatic environment are conserved in 45 members. Asp 223, which determines specificity for NAD, is found in all but the two NADP-dependent enzymes, which have Gly or Ala. Ser or Thr 48, which makes a hydrogen bond to the substrate, is present in 46 members. The four Cys ligands for the structural zinc are conserved except in zeta-crystallin, the sorbitol dehydrogenases, and two bacterial enzymes. Analysis of the evolutionary tree gives estimates of the times of divergence for different animal ADHs. The human class II (pi) and class III (chi) ADHs probably diverged about 630 million years ago, and the newly identified human ADH6 appeared about 520 million years ago, implying that these classes of enzymes may exist or have existed in all vertebrates. The human class I ADH isoenzymes (alpha, beta, and gamma) diverged about 80 million years ago, suggesting that these isoenzymes may exist or have existed in all primates. Analysis of branch lengths shows that these plant ADHs are more conserved than the animal ones and that class III ADHs are more conserved than class I ADHs. The rate of acceptance of point mutations (PAM units) shows that selection pressure has existed for ADHs, implying that these enzymes play definite metabolic roles.
J Mol Evol 1992 Jun
PMID:Progressive sequence alignment and molecular evolution of the Zn-containing alcohol dehydrogenase family. 159 44

The human class I alcohol dehydrogenase (ADH) gene family consists of ADH1, ADH2, and ADH3, which are sequentially activated in early fetal, late fetal, and postnatal liver, respectively. Analysis of ADH promoters revealed differential activation by several factors previously shown to control liver transcription. In cotransfection assays, the ADH1 promoter, but not the ADH2 or ADH3 promoter, was shown to respond to hepatocyte nuclear factor 1 (HNF-1), which has previously been shown to regulate transcription in early liver development. The ADH2 promoter, but not the ADH1 or ADH3 promoter, was shown to respond to CCAAT/enhancer-binding protein alpha (C/EBP alpha), a transcription factor particularly active during late fetal liver and early postnatal liver development. The ADH1, ADH2, and ADH3 promoters all responded to the liver transcription factors liver activator protein (LAP) and D-element-binding protein (DBP), which are most active in postnatal liver. For all three promoters, the activation by LAP or DBP was higher than that seen by HNF-1 or C/EBP alpha, and a significant synergism between C/EBP alpha and LAP was noticed for the ADH2 and ADH3 promoters when both factors were simultaneously cotransfected. A hierarchy of ADH promoter responsiveness to C/EBP alpha and LAP homo- and heterodimers is suggested. In all three ADH genes, LAP bound to the same four sites previously reported for C/EBP alpha (i.e., -160, -120, -40, and -20 bp), but DBP bound strongly only to the site located at -40 bp relative to the transcriptional start. Mutational analysis of ADH2 indicated that the -40 bp element accounts for most of the promoter regulation by the bZIP factors analyzed. These studies suggest that HNF-1 and C/EBP alpha help establish ADH gene family transcription in fetal liver and that LAP and DBP help maintain high-level ADH gene family transcription in postnatal liver.
Mol Cell Biol 1992 Jul
PMID:Temporal expression of the human alcohol dehydrogenase gene family during liver development correlates with differential promoter activation by hepatocyte nuclear factor 1, CCAAT/enhancer-binding protein alpha, liver activator protein, and D-element-binding protein. 162 Jan 13

The alcohol dehydrogenase (Adh) gene of Arabidopsis is expressed constitutively in immature seedlings and cells in suspension, and may be induced by hypoxic stress only in roots of mature plants. Deletions and G-box mutations of the Adh promoter were assayed in Arabidopsis protoplasts by PEG-mediated transient expression. Sequence domains necessary for full gene activity are confined to the 384 bp immediately 5' to the transcription start site, and deletion to -177 results in greater than 90% reduction in promoter activity. Site-specific mutations of G-box bases result in greater than 60% reduction in activity and disrupt G-box factor binding in vitro.
Plant Mol Biol 1992 Aug
PMID:Functional elements of the Arabidopsis Adh promoter include the G-box. 164 86

The alcohol dehydrogenase gene (Adh gene) of Drosophila affinidisjuncta is expressed at a higher level in the larval midgut and Malpighian tubules than the homologous gene from Drosophila hawaiiensis. This study analyzed the cis-acting sequences responsible for these regulatory differences in larval tissues of Drosophila melanogaster transformants. A series of 10 chimeric and deleted Adh genes was introduced into the germ line of D. melanogaster, and tissue-specific expression levels were quantified by gel electrophoresis of tissue extracts. Sequences in the upstream region of the two genes had the strongest influence on enzyme production in the midgut and Malpighian tubules. Other sequence elements also showed effects, some of which were tissue specific. Most gene fragments displayed context-dependent effects, thus supporting the proposed model of polygenic regulation of Adh gene expression.
J Mol Evol 1991 Mar
PMID:Complexity in evolved regulatory variation for alcohol dehydrogenase genes in Hawaiian Drosophila. 164 37

We have isolated a cytochrome c gene from Arabidopsis thaliana (cv. Columbia), which is the first cytochrome c gene to be cloned from a higher plant. Genomic DNA blot analysis indicates that there is only one copy of cytochrome c in Arabidopsis. The gene consists of three exons separated by two introns. Gene features such as regulatory regions, codon usage, and conserved splicing-specific sequences are all present and typical of dicotyledonous plant nuclear genes. We have constructed phenograms and cladograms for cytochrome c amino acid sequences and histone H3, alcohol dehydrogenase, and actin DNA sequences. For both cytochrome c and histone H3, Arabidopsis clusters poorly with other higher plants. Instead, it clusters with Neurospora and/or the yeasts. We suggest that perhaps this observation should be considered when using Arabidopsis as a model system for higher plants.
J Mol Evol 1991 Mar
PMID:Structure and molecular evolutionary analysis of a plant cytochrome c gene: surprising implications for Arabidopsis thaliana. 164 38

The transposable element mariner occurs widely in the melanogaster species group of Drosophila. However, in drosophilids outside of the melanogaster species group, sequences showing strong DNA hybridization with mariner are found only in the genus Zaprionus. The mariner sequence obtained from Zaprionus tuberculatus is 97% identical with that from Drosophila mauritiana, a member of the melanogaster species subgroup, whereas a mariner sequence isolated from Drosophila tsacasi is only 92% identical with that from D. mauritiana. Because D. tsacasi is much more closely related to D. mauritiana than is Zaprionus, the presence of mariner in Zaprionus may result from horizontal transfer. In order to confirm lack of a close phylogenetic relationship between the genus Zaprionus and the melanogaster species group, we compared the alcohol dehydrogenase (Adh) sequences among these species. The results show that the coding region of Adh is only 82% identical between Z. tuberculatus and D. mauritiana, as compared with 90% identical between D. tsacasi and D. mauritiana. Furthermore, the mariner gene phylogeny obtained by maximum likelihood and maximum parsimony analyses is discordant with the species phylogeny estimated by using the Adh genes. The only inconsistency in the mariner gene phylogeny is in the placement of the Zaprionus mariner sequence, which clusters with mariner from Drosophila teissieri and Drosophila yakuba in the melanogaster species subgroup. These results strongly suggest horizontal transfer.
J Mol Evol 1991 Dec
PMID:Evidence for interspecific transfer of the transposable element mariner between Drosophila and Zaprionus. 166

A genomic clone for an alcohol dehydrogenase (Adh) gene has been isolated from Petunia hybrida cv. V30 by screening a Petunia genomic library with a maize Adh1 probe. A combination of RFLP and allozyme segregation data failed to demonstrate which of two Adh 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 in Petunia protoplasts. We have designated this gene Petunia 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 of Adh1 mRNA.
Plant Mol Biol 1991 Jul
PMID:Structure, expression, chromosomal location and product of the gene encoding ADH1 in Petunia. 167 86

The distal promoter of Adh is differentially expressed in Drosophila tissue culture cell lines. After transfection with an exogenous Adh gene, there was a specific increase in distal alcohol dehydrogenase (ADH) transcripts in ADH-expressing (ADH+) cells above the levels observed in transfected ADH-nonexpressing (ADH-) cells. We used deletion mutations and a comparative transient-expression assay to identify the cis-acting elements responsible for enhanced Adh distal transcription in ADH+ cells. DNA sequences controlling high levels of distal transcription were localized to a 15-base-pair (bp) region nearly 500 bp upstream of the distal RNA start site. In addition, a 61-bp negative cis-acting element was found upstream from and adjacent to the enhancer. When this silencer element was deleted, distal transcription increased only in the ADH+ cell line. These distant upstream elements must interact with the promoter elements, the Adf-1-binding site and the TATA box, as they only influenced transcription when at least one of these two positive distal promoter elements was present. Internal deletions targeted to the Adf-1-binding site or the TATA box reduced transcription in both cell types but did not affect the transcription initiation site. Distal transcription in transfected ADH- cells appears to be controlled primarily through these promoter elements and does not involve the upstream regulatory elements. Evolutionary conservation in distantly related Drosophila species suggests the importance of these upstream elements in correct developmental and tissue-specific expression of ADH.
Mol Cell Biol 1990 Jul
PMID:Conserved enhancer and silencer elements responsible for differential Adh transcription in Drosophila cell lines. 169 13

In a genetic selection for Saccharomyces cerevisiae genes involved in transcription start site specification, two mutant genes which restore alcohol dehydrogenase activity to a functionally defective S. pombe ADH gene were recovered. Examination of S. pombe ADH initiation sites showed that mutations in the SHI gene shift the location of the transcription initiation window closer to TATA. The shi mutant also affected initiation site selection for two S. cerevisiae genes that were tested. For H2B mRNA, initiation occurred in the shi mutant at a series of initiation sites located 43 to 80 bp 3' of the histone H2B TATA sequence and at the usual initiation sites 102 and 103 bp downstream of the TATA sequence. Weakly used initiation sites ranging from 51 to 80 bp downstream of the TATA sequence were observed for the S. cerevisiae ADH1 gene in shi strains, in addition to the normal ADH1 initiation sites 89 and 99 bp from the TATA sequence. Restoration of function to the defective S. pombe ADH gene occurs only when this gene contains a TATA sequence; a single-base-pair TATA-to-TAGA change is sufficient to prevent this restoration of function. Genetic mapping placed the SHI locus on the left arm of chromosome VII, 22.3 centimorgans from cyh2; it does not correspond to any previously mapped gene.
Mol Cell Biol 1991 Aug
PMID:SHI, a new yeast gene affecting the spacing between TATA and transcription initiation sites. 171 2

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