Linkage disequilibrium at the ADH2 and ADH3 loci and risk of alcoholism

Two of the three class I alcohol dehydrogenase (ADH) genes (ADH2 and ADH3) encode known functional variants that act on alcohol with different efficiencies. Variants at both these genes have been implicated in alcoholism in some populations because allele frequencies differ between alcoholics and controls. Specifically, controls have higher frequencies of the variants with higher Vmax (ADH2*2 and ADH3*1). In samples both of alcoholics and of controls from three Taiwanese populations (Chinese, Ami, and Atayal) we found significant pairwise disequilibrium for all comparisons of the two functional polymorphisms and a third, presumably neutral, intronic polymorphism in ADH2. The class I ADH genes all lie within 80 kb on chromosome 4; thus, variants are not inherited independently, and haplotypes must be analyzed when evaluating the risk of alcoholism. In the Taiwanese Chinese we found that, only among those chromosomes containing the ADH3*1 variant (high Vmax), the proportions of chromosomes with ADH2*1 (low Vmax) and those with ADH2*2 (high Vmax) are significantly different between alcoholics and controls (P<10-5). The proportions of chromosomes with ADH3*1 and those with ADH3*2 are not significantly different between alcoholics and controls, on a constant ADH2 background (with ADH2*1, P=.83; with ADH2*2, P=.53). Thus, the observed differences in the frequency of the functional polymorphism at ADH3, between alcoholics and controls, can be accounted for by the disequilibrium with ADH2 in this population.     

A global perspective on genetic variation at the ADH genes reveals unusual patterns of linkage disequilibrium and diversity

Variants of different Class I alcohol dehydrogenase (ADH) genes have been shown to be associated with an effect that is protective against alcoholism. Previous work from our laboratory has shown that the two sites showing the association are in linkage disequilibrium and has identified the ADH1B Arg47His site as causative, with the ADH1C Ile349Val site showing association only because of the disequilibrium. Here, we describe an initial study of the nature of linkage disequilibrium and genetic variation, in population samples from different regions of the world, in a larger segment of the ADH cluster (including the three Class I ADH genes and ADH7). Linkage disequilibrium across approximately 40 kb of the Class I ADH cluster is moderate to strong in all population samples that we studied. We observed nominally significant pairwise linkage disequilibrium, in some populations, between the ADH7 site and some Class I ADH sites, at moderate values and at a molecular distance as great as 100 kb. Our data indicate (1) that most ADH-alcoholism association studies have failed to consider many sites in the ADH cluster that may harbor etiologically significant alleles and (2) that the relevance of the various ADH sites will be population dependent. Some individual sites in the Class I ADH cluster show Fst values that are among the highest seen among several dozen unlinked sites that were studied in the same subset of populations. The high Fst values can be attributed to the discrepant frequencies of specific alleles in eastern Asia relative to those in other regions of the world. These alleles are part of a single haplotype that exists at high (>65%) frequency only in the eastern-Asian samples. It seems unlikely that this haplotype, which is rare or unobserved in other populations, reached such high frequency because of random genetic drift alone.     

The Activity of Class I, II, III and IV of Alcohol Dehydrogenase (ADH) Isoenzymes and Aldehyde Dehydrogenase (ALDH) in Brain Cancer

The brain being highly sensitive to the action of alcohol is potentially susceptible to its carcinogenic effects. Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are the main enzymes involved in ethanol metabolism, which leads to the generation of carcinogenic acetaldehyde. Human brain tissue contains various ADH isoenzymes and possess also ALDH activity. The purpose of this study was to compare the capacity for ethanol metabolism measured by ADH isoenzymes and ALDH activity in cancer tissues and healthy brain cells. The samples were taken from 62 brain cancer patients (36 glioblastoma, 26 meningioma). For the measurement of the activity of class I and II ADH isoenzymes and ALDH activity, the fluorometric methods were used. The total ADH activity and activity of class III and IV isoenzymes were measured by the photometric method. The total activity of ADH, and activity of class I ADH were significantly higher in cancer cells than in healthy tissues. The other tested classes of ADH and ALDH did not show statistically significant differences of activity in cancer and in normal cells. Analysis of the enzymes activity did not show significant differences depending on the location of the tumor. The differences in the activity of total alcohol dehydrogenase, and class I isoenzyme between cancer tissues and healthy brain cells might be a factor for metabolic changes and disturbances in low mature cancer cells and additionally might be a reason for higher level of acetaldehyde which can intensify the carcinogenesis.     

The activity of yeast ADH I and ADH II with long-chain alcohols and diols

The activities of yeast ADH I and ADH II towards long chain alcohols and diols were studied using rather unusual conditions (1.0 M Tris pH 8.75, approximately 0.3 mg/ml enzyme and [S]相似文献   

The activity of yeast ADH I and ADH II with long-chain alcohols and diols

The activities of yeast ADH I and ADH II towards long chain alcohols and diols were studied using rather unusual conditions (1.0 M Tris pH 8.75, approximately 0.3 mg/ml enzyme and [S]< < <K_m ) where the alcohols are oxidised quantitatively in a first-order manner. Plots of the apparent first-order rate constant versus primary alcohol chain length show double peaks with similar values for ethanol and 1-decanol and relatively low values for 1-butanol through to 1-octanol. With the α,ω diols only one peak of activity was observed with 1,14-tetradecanediol, the preferred substrate, being oxidised about the same rate as ethanol. Both enzymes were essentially inactive with short-chain diols (C₂–C₈). For all of these assays normalised rates with ADH II were about threefold faster than with ADH I.     

Opossum alcohol dehydrogenases: Sequences, structures, phylogeny and evolution: evidence for the tandem location of ADH genes on opossum chromosome 5

BLAT (BLAST-Like Alignment Tool) analyses and interrogations of the recently published opossum genome were undertaken using previously reported rat ADH amino acid sequences. Evidence is presented for six opossum ADH genes localized on chromosome 5 and organized in a comparable ADH gene cluster to that reported for human and rat ADH genes. The predicted amino acid sequences and secondary structures for the opossum ADH subunits and the intron-exon boundaries for opossum ADH genes showed a high degree of similarity with other mammalian ADHs, and four opossum ADH classes were identified, namely ADH1, ADH3, ADH6 and ADH4 (for which three genes were observed: ADH4A, ADH4B and ADH4C). Previous biochemical analyses of opossum ADHs have reported the tissue distribution and properties for these enzymes: ADH1, the major liver enzyme; ADH3, widely distributed in opossum tissues with similar kinetic properties to mammalian class 3 ADHs; and ADH4, for which several forms were localized in extrahepatic tissues, especially in the digestive system and in the eye. These ADHs are likely to perform similar functions to those reported for other mammalian ADHs in the metabolism of ingested and endogenous alcohols and aldehydes. Phylogenetic analyses examined opossum, human, rat, chicken and cod ADHs, and supported the proposed designation of opossum ADHs as class I (ADH1), class III (ADH3), class IV (ADH4A, ADH4B and ADH4C) and class VI (ADH6). Percentage substitution rates were examined for ADHs during vertebrate evolution which indicated that ADH3 is evolving at a much slower rate to that of the other ADH classes.     

Evidence of positive selection on a class I ADH locus

The alcohol dehydrogenase (ADH) family of enzymes catalyzes the reversible oxidation of alcohol to acetaldehyde. Seven ADH genes exist in a segment of ~370 kb on 4q21. Products of the three class I ADH genes that share 95% sequence identity are believed to play the major role in the first step of ethanol metabolism. Because the common belief that selection has operated at the ADH1B*47His allele in East Asian populations lacks direct biological or statistical evidence, we used genomic data to test the hypothesis. Data consisted of 54 single-nucleotide polymorphisms (SNPs) across the ADH clusters in a global sampling of 42 populations. Both the F(st) statistic and the long-range haplotype (LRH) test provided positive evidence of selection in several East Asian populations. The ADH1B Arg47His functional polymorphism has the highest F(st) of the 54 SNPs in the ADH cluster, and it is significantly above the mean F(st) of 382 presumably neutral sites tested on the same 42 population samples. The LRH test that uses cores including that site and extending on both sides also gives significant evidence of positive selection in some East Asian populations for a specific haplotype carrying the ADH1B*47His allele. Interestingly, this haplotype is present at a high frequency in only some East Asian populations, whereas the specific allele also exists in other East Asian populations and in the Near East and Europe but does not show evidence of selection with use of the LRH test. Although the ADH1B*47His allele conveys a well-confirmed protection against alcoholism, that modern phenotypic manifestation does not easily translate into a positive selective force, and the nature of that selective force, in the past and/or currently, remains speculative.     

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.     

Genotyping of human alcohol dehydrogenases at the ADH2 and ADH3 loci following DNA sequence amplification

Humans are polymorphic at two of the alcohol dehydrogenase (ADH) loci important in ethanol metabolism, ADH2 and ADH3. Although the coding regions of these genes are 94% identical, they produce subunits that differ greatly in kinetic properties in vitro. These differences are likely to be reflected in the pharmacokinetics of alcohol metabolism, but studies have been hampered by the need to use liver biopsy specimens to determine the ADH phenotype. This problem has now been overcome by determining the genotype at these loci using DNA that has been amplified in vitro by the polymerase chain reaction. We report here the identification of all three of the ADH2 alleles and both of the ADH3 alleles. Any pair of ADH2 or ADH3 alleles can be distinguished using allele-specific oligonucleotide probes directed at their single base pair difference. In addition, ADH2(2) can be distinguished from ADH2(1) and ADH2(3) by detecting a new MaeIII site created in the third exon by the single base pair alteration in ADH2(2).     

Alcohol dehydrogenase (ADH) in yeasts. II. NAD+-and NADP+-dependent alcohol dehydrogenases in Saccharomycopsis lipolytica.

In Sm. lipolytica one NAD+-dependent and three NADP+-dependent alcohol dehydrogenases are detectable by polyacrylamide gelelectrophoresis. The NAD+-dependent ADH (ADH I), with a molecular weight of 240,000 daltons, reacts more intensively with long-chain alcohols (octanol) than with short-chain alcohols (methanol, ethanol). The ADH I is not or only minimally subject to glucose repression. Besides the ADH I band no additional inducible NAD+-dependent ADH band is gel-electrophoretically detectable during growth of yeast cells in medium containing ethanol or paraffin. The ADH I band is very probably formed by two ADH enzymes with the same electrophoretic mobility. The NADP+-dependent alcohol dehydrogenases (ADH II--IV) react with methanol, ethanol and octanol with different intensity. In polyacrylamide gradients two bands of NADP+-dependent ADH are detectable: one with a molecular weight of 70,000 daltons and the other with 120,000 daltons. The occurrence of the three NADP+-dependent alcohol dehydrogenases is regulated by the carbon source of the medium. Sm. lipolytica shows a high tolerance against allylalcohol. Resistant mutants can be isolated only at concentrations of 1 M allylalcohol in the medium. All isolates of allylalcohol-resistant mutants show identical growth in medium containing ethanol as the wild type strain.     

Mammalian alcohol dehydrogenase of higher classes: analyses of human ADH5 and rat ADH6

Alcohol dehydrogenases (ADH) of classes V and VI, ADH5 and ADH6, have been defined in man and rodents, respectively. Sequence data have been obtained at cDNA and genomic levels, but limited data are available for functionality and substrate repertoire. The low positional identity (65%) between the two ADHs, place them into separate classes. We have shown that the ADH5 gene yields two differently processed mRNAs and harbors a gene organization identical to other mammalian ADHs. This is probably due to an alternative splicing in the eighth intron that results in a shorter message missing the ninth exon or a normal message with the expected number of codons. The isolated rat ADH6 cDNA was found to be fused to ADH2 at the 5′-end. The resulting main open reading frame translates into an N-terminally extended polypeptide. In vitro translation results in a polypeptide of about 42 kDa and further, protein was possible to express in COS cells as a fusion product with Green Fluorescent Protein. Both ADH5 and ADH6 show genes and gene products that are processed comparably to other mammalian ADHs and the deduced amino acid sequences indicate a lack of ethanol dehydrogenase activity that probably explains why no corresponding proteins have been isolated. The functionality of these ADHs is therefore still an enigma.     

Polymorphisms of Alcohol Dehydrogenase Genes ADH1Band ADH7 in Russian Populations of Siberia

Three Russian populations of Siberia were examined for allele and genotype frequency distributions of two alcohol dehydrogenase genes, ADH1B (exon 3 polymorphism A/G detectable with MslI) and ADH7 (intron 5 polymorphism G/C detectable with StyI). No interpopulation or sex difference in allele frequencies was revealed. Allele ADH1B*G (+ MslI, A2) was rare (3.6–7.5%); the frequency of the mutant ADH7 allele (–StyI, B2) was 46.02% in the total sample (N = 339). The genotype frequencies obeyed the Hardy–Weinberg equilibrium and the alleles were in linkage equilibrium in each population. Frequency of ADH7 allele B2 increased beyond 40 years of age in the total sample (by 11%, P = 0.001) and in the Tomsk population (by 9%, P= 0.017). The ADH1B and ADH7 polymorphisms had no effect on the antioxidant activity (AOA), which was inferred from the ability of serum to reduce the yield of thiobarbituric acid-reactive species in the Fe²⁺–lecithin system. In the Tomsk population, carriers of AHD1B allele A2 showed a significant increase in very low density lipoproteins (by 9.95%, P = 0.045) and a near significant increase in systolic pressure (by 6.8%, P = 0.068) and serum triglycerides (by 6.16%, P = 0.058).     

Ethnic related selection for an ADH Class I variant within East Asia

Background

The alcohol dehydrogenases (ADH) are widely studied enzymes and the evolution of the mammalian gene cluster encoding these enzymes is also well studied. Previous studies have shown that the ADH1B*47His allele at one of the seven genes in humans is associated with a decrease in the risk of alcoholism and the core molecular region with this allele has been selected for in some East Asian populations. As the frequency of ADH1B*47His is highest in East Asia, and very low in most of the rest of the world, we have undertaken more detailed investigation in this geographic region.

Methodology/Principal Findings

Here we report new data on 30 SNPs in the ADH7 and Class I ADH region in samples of 24 populations from China and Laos. These populations cover a wide geographic region and diverse ethnicities. Combined with our previously published East Asian data for these SNPs in 8 populations, we have typed populations from all of the 6 major linguistic phyla (Altaic including Korean-Japanese and inland Altaic, Sino-Tibetan, Hmong-Mien, Austro-Asiatic, Daic, and Austronesian). The ADH1B genotyping data are strongly related to ethnicity. Only some eastern ethnic phyla or subphyla (Korean-Japanese, Han Chinese, Hmong-Mien, Daic, and Austronesian) have a high frequency of ADH1B*47His. ADH1B haplotype data clustered the populations into linguistic subphyla, and divided the subphyla into eastern and western parts. In the Hmong-Mien and Altaic populations, the extended haplotype homozygosity (EHH) and relative EHH (REHH) tests for the ADH1B core were consistent with selection for the haplotype with derived SNP alleles. In the other ethnic phyla, the core showed only a weak signal of selection at best.

Conclusions/Significance

The selection distribution is more significantly correlated with the frequency of the derived ADH1B regulatory region polymorphism than the derived amino-acid altering allele ADH1B*47His. Thus, the real focus of selection may be the regulatory region. The obvious ethnicity-related distributions of ADH1B diversities suggest the existence of some culture-related selective forces that have acted on the ADH1B region.     

Mammalian alcohol dehydrogenase of higher classes: analyses of human ADH5 and rat ADH6

Alcohol dehydrogenases (ADH) of classes V and VI, ADH5 and ADH6, have been defined in man and rodents, respectively. Sequence data have been obtained at cDNA and genomic levels, but limited data are available for functionality and substrate repertoire. The low positional identity (65%) between the two ADHs, place them into separate classes. We have shown that the ADH5 gene yields two differently processed mRNAs and harbors a gene organization identical to other mammalian ADHs. This is probably due to an alternative splicing in the eighth intron that results in a shorter message missing the ninth exon or a normal message with the expected number of codons. The isolated rat ADH6 cDNA was found to be fused to ADH2 at the 5'-end. The resulting main open reading frame translates into an N-terminally extended polypeptide. In vitro translation results in a polypeptide of about 42 kDa and further, protein was possible to express in COS cells as a fusion product with Green Fluorescent Protein. Both ADH5 and ADH6 show genes and gene products that are processed comparably to other mammalian ADHs and the deduced amino acid sequences indicate a lack of ethanol dehydrogenase activity that probably explains why no corresponding proteins have been isolated. The functionality of these ADHs is therefore still an enigma.     

Isolation and DNA sequence of ADH3, a nuclear gene encoding the mitochondrial isozyme of alcohol dehydrogenase in Saccharomyces cerevisiae.

The Saccharomyces cerevisiae nuclear gene, ADH3, that encodes the mitochondrial alcohol dehydrogenase isozyme ADH III was cloned by virtue of its nucleotide homology to ADH1 and ADH2. Both chromosomal and plasmid-encoded ADH III isozymes were repressed by glucose and migrated heterogeneously on nondenaturing gels. Nucleotide sequence analysis indicated 73 and 74% identity for ADH3 with ADH1 and ADH2, respectively. The amino acid identity between the predicted ADH III polypeptide and ADH I and ADH II was 79 and 80%, respectively. The open reading frame encoding ADH III has a highly basic 27-amino-acid amino-terminal extension relative to ADH I and ADH II. The nucleotide sequence of the presumed leader peptide has a high degree of identity with the untranslated leader regions of ADH1 and ADH2 mRNAs. A strain containing a null allele of ADH3 did not have a detectably altered phenotype. The cloned gene integrated at the ADH3 locus, indicating that this is the structural gene for ADH III.     

Inactivation of alcohol dehydrogenase (ADH) by ferryl derivatives of human hemoglobin

In this paper, inactivation of alcohol dehydrogenase (ADH) by products of reactions of H2O2 with metHb has been studied. Inactivation of the enzyme was studied in two systems corresponding to two kinetic stages of the reaction. In the first system H2O2 was added to the mixture of metHb and ADH [the (metHb+ADH)+H2O2] system (ADH was present in the system since the moment of addition of H2O2 i. e. since the very beginning of the reaction of metHb with H2O2). In the second system ADH was added to the system 5 min after the initiation of the reaction of H2O2 with metHb [the (metHb+H2O2)5 min+ADH] system. In the first case all the products of reaction of H2O2 with metHb (non-peroxyl and peroxyl radicals and non-radical products, viz. hydroperoxides and *HbFe(IV)=O) could react with the enzyme causing its inactivation. In the second system, enzyme reacted almost exclusively with non-radical products (though a small contribution of reactions with peroxyl radicals cannot be excluded). ADH inactivation was observed in both system. Hydrogen peroxide alone did not inactivate ADH at the concentrations employed evidencing that enzyme inactivation was due exclusively to products of reaction of H2O2 with metHb. The rate and extent of ADH inactivation were much higher in the first than in the second system. The dependence of ADH activity on the time of incubation with ferryl derivatives of Hb can be described by a sum of three exponentials in the first system and two exponentials in the second system. Reactions of appropriate forms of the ferryl derivatives of hemoglobin have been tentatively ascribed to these exponentials. The extent of the enzyme inactivation in the second system was dependent on the proton concentration, being at the highest at pH 7.4 and negligible at pH 6.0. The reaction of H2O2 with metHb resulted in the formation of cross-links of Hb subunits (dimers and trimers). The amount of the dimers formed was much lower in the first system i. e. when the radical forms dominated the reaction of inactivation.     

Alcohol dehydrogenase (ADH). Influence of homo- and heterologous ADH administration on albino rats craving for alcohol and on ADH isozyme activity in the liver.

The effects of homo- and heterologous alcohol dehydrogenase (ADH) administration into albino rats were investigated. It was found that homologous ADH increases and heterologous ADH decreases the craving for ethanol. The latter effect was accompanied by the appearance of anti-ADH-3 antibodies and by a decrease in ADH-3 activity in the liver. Craving for alcohol decreased after both active and passive immunization against ADH.     

Multiple mRNAs for human alcohol dehydrogenase (ADH): developmental and tissue specific differences.

Human class I alcohol dehydrogenase (ADH) genes show developmental and tissue specific differences in expression at the polypeptide level. In these studies ADH expression was investigated at the RNA level. Northern blot analysis of total and poly (A) RNA from adult liver using pADH12 probe demonstrated multiple RNA size classes of 2.6, 2.2, 1.9 and 1.6kb. In contrast, fetal liver, and fetal intestine contained only 2.6 and 1.6kb mRNA while fetal lung showed only 2.6kb mRNA. All of these tissues showed a relative reduction in the amount of ADH mRNA present when compared to adult liver. Immunoprecipitation of in vitro translation products of adult liver RNA by polyclonal ADH antibody revealed a single polypeptide of 40,000 daltons. This result points out the homogeneity of size of class I ADH polypeptides despite mRNA size diversity. Variation in length of the 3' untranslated region probably contributes to the multiple size classes of ADH mRNA observed.