Molecular structure of the human alcohol dehydrogenase 1 gene

Conservative evolution in duplicated genes of the primate Class I ADH cluster

Humans have seven alcohol dehydrogenase genes (ADH) falling into five classes. Three out of the seven genes (ADH1A, ADH1B and ADH1C) belonging to Class I are expressed primarily in liver and code the main enzymes catalyzing ethanol oxidization. The three genes are tandemly arrayed within the ADH cluster on chromosome 4 and have very high nucleotide similarity to each other (exons: >90%; introns: >70%), suggesting the genes have been generated by duplication event(s). One explanation for maintaining similarity of such clustered genes is homogenization via gene conversion(s). Alternatively, recency of the duplications or some other functional constraints might explain the high similarities among the genes. To test for gene conversion, we sequenced introns 2, 3, and 8 of all three Class I genes (total>15.0 kb) for five non-human primates--four great apes and one Old World Monkey (OWM)--and compared them with those of humans. The phylogenetic analysis shows each intron sequence clusters strongly within each gene, giving no evidence for gene conversion(s). Several lines of evidence indicate that the first split was between ADH1C and the gene that gave rise to ADH1A and ADH1B. We also analyzed cDNA sequences of the three genes that have been previously reported in mouse and Catarrhines (OWMs, chimpanzee, and humans) and found that the synonymous and non-synonymous substitution (dN/dS) ratios in all pairs are less than 1 representing purifying selection. This suggests that purifying selection is more important than gene conversion(s) in maintaining the overall sequence similarity among the Class I genes. We speculate that the highly conserved sequences on the three duplicated genes in primates have been achieved essentially by maintaining stability of the hetero-dimer formation that might have been related to dietary adaptation in primate evolution.

Genome scans and gene expression microarrays converge to identify gene regulatory loci relevant in schizophrenia

Multiple linkage regions have been reported in schizophrenia, and some appear to harbor susceptibility genes that are differentially expressed in postmortem brain tissue derived from unrelated individuals. We combined traditional genome-wide linkage analysis in a multiplex family with lymphocytic genome-wide expression analysis. A genome scan suggested linkage to a chromosome 4q marker (D4S1530, LOD 2.17, theta = 0) using a dominant model. Haplotype analysis using flanking microsatellite markers delineated a 14 Mb region that cosegregated with all those affected. Subsequent genome-wide scan with SNP genotypes supported the evidence of linkage to 4q33-35.1 (LOD = 2.39) using a dominant model. Genome-wide microarray analysis of five affected and five unaffected family members identified two differentially expressed genes within the haplotype AGA and GALNT7 (aspartylglucosaminidase and UDP-N-acetyl-alpha-D-galactosamine: polypeptide N-acetylgalactosaminyltransferase 7) with nominal significance; however, these genes did not remain significant following analysis of covariance. We carried out genome-wide linkage analyses between the quantitative expression phenotype and genetic markers. AGA expression levels showed suggestive linkage to multiple markers in the haplotype (maximum LOD = 2.37) but to no other genomic region. GALNT7 expression levels showed linkage to regulatory loci at 4q28.1 (maximum LOD = 3.15) and in the haplotype region at 4q33-35.1 (maximum LOD = 2.37). ADH1B (alcohol dehydrogenase IB) was linked to loci at 4q21-q23 (maximum LOD = 3.08) and haplotype region at 4q33-35.1 (maximum LOD = 2.27). Seven differentially expressed genes were validated with RT-PCR. Three genes in the 4q33-35.1 haplotype region were also differentially expressed in schizophrenia in postmortem dorsolateral prefrontal cortex: AGA, HMGB2, and SCRG1. These results indicate that combining differential gene expression with linkage analysis may help in identifying candidate genes and potential regulatory sites. Moreover, they also replicate recent findings of complex trans- and cis- regulation of genes.

Regulation of the mammalian alcohol dehydrogenase genes

This review focuses on the regulation of the mammalian medium-chain alcohol dehydrogenase (ADH) genes. This family of genes encodes enzymes involved in the reversible oxidation of alcohols to aldehydes. Interest in these enzymes is increased because of their role in the metabolism of beverage alcohol as well as retinol, and their influence on the risk for alcoholism. There are six known classes ADH genes that evolved from a common ancestor. ADH genes differ in their patterns of expression: most are expressed in overlapping tissue-specific patterns, but class III ADH genes are expressed ubiquitously. All have proximal promoters with multiple cis-acting elements. These elements, and the transcription factors that can interact with them, are being defined. Subtle differences in sequence can affect affinity for these factors, and thereby influence the expression of the genes. This provides an interesting system in which to examine the evolution of tissue specificity. Among transcription factors that are important in multiple members of this gene family are the C/EBPs, Sp1,USF, and AP1, HNF-1, CTF/NF-1, glucocorticoid, and retinoic acid receptors, and several as-yet unidentified negative elements, are important in at least one of the genes. There is evidence that cis-acting elements located far from the proximal promoter are necessary for proper expression. Three of the genes have upstream AUGs in the 5' nontranslated regions of their mRNA, unusual for mammalian genes. The upstream AUGs have been shown to significantly affect expression of the human ADH5 gene.

BWMK1, a novel MAP kinase induced by fungal infection and mechanical wounding in rice

The activation of the mitogen-activated protein (MAP) kinases by different environmental stresses has been previously observed in several dicot plant species. Here, we report the isolation of a novel MAP kinase in rice that is induced during infection by the blast fungus Magnaporthe grisea or upon mechanical wounding. The gene is designated as BWMK1 for blast- and wound-induced MAP kinase. The cDNA of BWMK1 was isolated from rice leaves challenged by the blast pathogen. Transcripts of the corresponding gene accumulated in rice leaves 4 h after blast inoculation and 30 min after mechanical wounding. This gene encodes a 506 amino acid protein that contains a new dual-phosphorylation activation motif TDY and about 150 unique amino acids on its C terminus. In-gel kinase activity and immunoprecipitation assays confirmed that BWMK1 is a functional MAP kinase. These results show that BWMK1 is a new member of the plant MAP kinase family and may mediate both defense and wound signaling in rice.

Genomic structure and expression of the ADH7 gene encoding human class IV alcohol dehydrogenase, the form most efficient for retinol metabolism in vitro

Human alcohol dehydrogenase (ADH) consists of a family of five evolutionarily related classes of enzymes that collectively function in the metabolism of a wide variety of alcohols including ethanol and retinol. Class IV ADH has been found to be the most active as a retinol dehydrogenase, thus it may participate in retinoic acid synthesis. The gene encoding class IV ADH (ADH7) has now been cloned and subjected to molecular examination. Southern blot analysis indicated that class IV ADH is encoded by a single unique gene and has no related pseudogenes. The class IV ADH gene is divided into nine exons, consistent with the highly conserved intron/exon structure of other mammalian ADH genes. The predicted amino acid sequence of the exon coding regions indicates that a protein of 373 amino acids, excluding the amino-terminal methionine, would be translated, sharing greater sequence identity with class I ADH (69%) than with classes II, III or V (59-61%). Expression of class IV ADH mRNA was detected in human stomach but not liver. This correlates with previous protein studies, which have indicated that class IV ADH is the major stomach ADH but unlike other ADHs is absent from liver. Primer extension studies using human stomach RNA were performed to identify the transcription initiation site lying 100 base pairs upstream of the ATG translation start codon. Nucleotide sequence analysis of the promoter region indicated the absence of a TATA box sequence often located about 25 base pairs upstream of the start site as well as the absence of GC boxes, which are quite often seen in promoters lacking a TATA box. The class IV ADH promoter thus differs from the other ADH promoters, which contain either a TATA box (classes I and II) or GC-boxes (class III), suggesting a fundamentally different form of transcriptional regulation.

A novel anther-expressed adh-homologous gene in Lycopersicon esculentum

Two novel tandemly-oriented open reading frames (ORFs) with homology to alcohol dehydrogenase (ADH) were isolated from tomato. The predicted amino acid composition for each of the two tandem adh genes indicates the presence of 22 and 21, respectively, of 22 amino acids conserved in ADH proteins from plants and animals. However, comparison to known plant adh genes reveals a significantly lower similarity indicating that they belong to a novel class of ADHs. According to mapping data, the adh-homologous ORFs do not represent either of the previously studied adh1 or adh2 genes of tomato. The tandem genes, termed adh3a and adh3b, mapped to a distal region of the long arm of chromosome 4, unlike adh1, which maps closer to the centromere. Adh3a and adh3b have over 90% similarity to each other at the nucleotide and putative peptide levels. The adh3a gene has ten exons and nine introns with the transcription initiation site 57 bp upstream of the translation start. A putative TATA box and polyadenylation site have been identified. Adh3a is transcribed and, according to cDNA sequence analysis, fully processed in the late stages of anther development. According to transformation analysis, tissue-specific regulatory elements reside within the -448 to +724 region. The termination codon of adh3a is separated from the putative adh3b translation start site by 789 bp of intervening sequence. The 5' untranscribed sequences of each gene contain a stretch of 68 bp with 78% similarity. Within this stretch are sequences which are homologous to sequences found in anaerobically-induced or pollen-expressed genes from various plant species.

Molecular characterization of a class IV human alcohol dehydrogenase gene (ADH7)

Class IV alcohol dehydrogenase (ADH) is a form preferentially expressed in stomach. We report here the isolation and sequence determination of a novel human ADH gene (ADH7). Phylogenetic analysis strongly suggests that ADH7 is a functional class IV ADH gene.

Alcohol dehydrogenase genes: restriction fragment length polymorphisms for ADH4 (pi-ADH) and ADH5 (chi-ADH) and construction of haplotypes among different ADH classes

Of the five human alcohol dehydrogenase (ADH) genes located in the region q21-25 of chromosome 4, genetic markers have been reported previously only for class I enzymes, ADH1-3. Here, new restriction fragment length polymorphisms (RFLPs) are described for the genes of two other classes, ADH4 (pi) and ADH5 (chi or formaldehyde dehydrogenase, FDH). The frequencies and modes of inheritance of these RFLPs were determined with DNA both from unrelated individuals and from families. A polymorphic PstI site is assigned to the fourth intron of the ADH4 gene. Pairwise linkage disequilibrium calculations for these new RFLPs and already known RFLPs at the ADH2 and ADH3 loci establish strong linkage disequilibria between polymorphic MspI and BstXI sites in the ADH5 gene as well as between XbaI and MspI sites in the ADH3 gene. Furthermore, linkage disequilibria were detected between RFLPs of the ADH2 and ADH3 genes as well as between those of the ADH4 and ADH5 genes. The latter disequilibrium implies a hitherto unknown physical proximity of two genes belonging to different ADH classes. The RFLPs were used to construct chromosomal haplotypes that include three ADH classes. Of the 16 possible haplotypes for four RFLP markers used here, 10 were experimentally detected. The potential application of the ADH RFLPs and haplotypes in linkage or association studies of inherited diseases such as familial "alcoholism" is discussed.

Molecular structure of the human alcohol dehydrogenase 3 gene

The structure and nucleotide sequence of an ADH3(1) allele, which encodes the ADH gamma 1 subunit, have been determined. The intron positions of the ADH3 gene are identical to those of the other class I and class II ADH genes. The level of nucleotide variation at the ADH3 locus is somewhat higher than those at the ADH1 and ADH2 loci.

A human alcohol dehydrogenase gene (ADH6) encoding an additional class of isozyme

The human alcohol dehydrogenase (ADH; alcohol:NAD+ oxidoreductase, EC 1.1.1.1) gene family consists of five known loci (ADH1-ADH5), which have been mapped close together on chromosome 4 (4q21-25). ADH isozymes encoded by these genes are grouped in three distinct classes in terms of their enzymological properties. A moderate structural similarity is observed between the members of different classes. We isolated an additional member of the ADH gene family by means of cross-hybridization with the ADH2 (class I) cDNA probe. cDNA clones corresponding to this gene were derived from PCR-amplified libraries as well. The coding sequence of a 368-amino-acid-long open reading frame was interrupted by introns into eight exons and spanned approximately 17 kilobases on the genome. The gene contains a glucocorticoid response element at the 5' region. The transcript was detected in the stomach and liver. The deduced amino acid sequence of the open reading frame showed about 60% positional identity with known human ADHs. This extent of homology is comparable to interclass similarity in the human ADH family. Thus, the newly identified gene, which is designated ADH6, governs the synthesis of an enzyme that belongs to another class of ADHs presumably with a distinct physiological role.

Cloning and characterization of the human ADH4 gene

Human alcohol dehydrogenase (ADH) constitutes a set of isozymes and enzymes with different tissue and substrate specificities. The subunits are coded for by at least five gene loci, ADH1-ADH5. We now report the cloning and analysis of the human ADH4 gene coding for the class-II ADH with pi-subunits. The gene spans a region of 21 kb and is divided into nine exons and eight introns. The arrangement is the same as for all analyzed mammalian class-I genes, but the region covered is 50% larger than that in the human class-I genes. The nucleotide (nt) sequences of the exons, exon/intron boundaries and 5'- and 3'-untranslated regions were determined. The transcription start point (tsp) of the ADH4 gene was defined by primer extension and localized to a position 61 nt upstream from the ATG start codon. A TATA box and a CAAT element were identified by homology to consensus sequences for tsp. No DNA structures homologous to the glucocorticoid-responsive elements (GRE) present in the ADH2 gene were found in the upstream region of the ADH4 gene, but two structures with a 70% identity to the GRE consensus sequence were found at nonhomologous locations. The difference and the overall low degree of identity, 41%, of the upstream regions suggest different regulatory mechanisms for the class-I and class-II genes.

The human class I alcohol dehydrogenase gene cluster: three genes are tandemly organized in an 80-kb-long segment of the genome

The class I alcohol dehydrogenases (ADH; EC 1.1.1.1) play a key role in hepatic alcohol catabolism. Three human class I ADH genes, ADH1, ADH2, and ADH3, which encode the alpha, beta, and gamma subunits respectively, have been isolated and mapped on chromosome 4q21-q23. Genomic cloning using a cosmid vector allowed us to obtain an 88-kb-long genomic segment, which was found to include an entire 80 kb of the class I ADH gene cluster. All three genes lie in the same transcriptional orientation and the order of genes is 5'-ADH3-ADH2-ADH1-3'. It may be of some significance that the order of transcriptional activation in the hepatic development, alpha----beta----gamma, is opposite to the order of gene arrangement. Several members of the AluI family and the KpnI (L1) family of interspersed repetitive sequences were mapped in this region. The divergence of insertional sites suggested that gene multiplication of the class I ADH genes had taken place in the earlier stages of human (or primate) evolution.

cDNA sequence of human class III alcohol dehydrogenase

A human placental cDNA library was screened using oligonucleotide probes based on the peptide sequence of the human class III alcohol dehydrogenase. An incomplete cDNA clone covering most of the coding sequence of class III alcohol dehydrogenase was isolated from a human placental cDNA library. This was subsequently used as a probe to obtain a full-length clone from a human testicular library. The cDNA sequence codes for a protein that is identical to the enzyme purified from human liver. Southern analysis of human genomic DNA suggests that it may contain more than a single copy per haploid genome.