Polymorphism at the ADH2 and ADH3 loci of alcohol dehydrogenase (ADH) has been shown to have an effect on the predisposition to alcoholism in Asian individuals. However, the results are not conclusive for white individuals. We have analyzed the ADH genotype of 876 white individuals from Spain (n ؍ 251), France (n ؍ 160), Germany (n ؍ 184), Sweden (n ؍ 88), and Poland (n ؍ 193). Peripheral blood samples from healthy controls and groups of patients with viral cirrhosis and alcohol-induced cirrhosis, as well as alcoholics with no liver disease, were collected on filter paper. Genotyping of the ADH2 and ADH3 loci was performed using polymerase chain reactionrestriction fragment length polymorphism methods on white cell DNA. In healthy controls, ADH2*2 frequencies ranged from 0% (France) to 5.4% (Spain), whereas ADH3*1 frequencies ranged from 47.6% (Germany) to 62.5% (Sweden). Statistically significant differences were not found, however, between controls from different countries, nor between patients with alcoholism and/or liver disease. When all individuals were grouped in nonalcoholics (n ؍ 451) and alcoholics (n ؍ 425), ADH2*2 frequency was higher in nonalcoholics (3.8%) than in alcoholics (1.3%) (P ؍ .0016), whereas the ADH3 alleles did not show differences. Linkage disequilibrium was found between ADH2 and ADH3, resulting in an association of the alleles ADH2*2 and ADH3*1, both coding for the most active enzymatic forms. In conclusion, the ADH2*2 allele decreases the risk for alcoholism, whereas the ADH2*2 and ADH3*1 alleles are found to be associated in the European population. (HEPATOLOGY 2000;31:984-989.)Ingested alcohol is mostly metabolized in the liver by the successive action of alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH). Both enzymes exhibit genetic polymorphisms that influence the rate of conversion of ethanol to acetaldehyde, and of acetaldehyde to acetate. It has been consistently reported that ALDH2 is the most important alcohol-metabolizing gene affecting predisposition to alcoholism in Asian populations. The prevalence of the ALDH2*2 allele, which codes for a physiologically inactive mitochondrial ALDH form, is lower in alcoholics than in nonalcoholics. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] However, this allele has not been found in white individuals. 21 Regarding ADH, polymorphism is detected at the ADH2 and ADH3 loci. Alleles of ADH2 found in whites and Asians are ADH2*1 and ADH2*2, which encode for the low activity (1) and high activity (2) subunits, respectively. The kcat values for the resulting dimeric isozymes are very different: 9.2 min Ϫ1 for 11 and 400 min Ϫ1 for 22. 22 The ADH2*2 frequency is much higher in Asians (60%-80%) than in whites (0%-10%). 21 ADH3 alleles are ADH3*1 and ADH3*2, which produce the ␥1 and ␥2 subunits. The ␥1␥1 isozyme (kcat ϭ 87 min Ϫ1 ) is moderately more active than the ␥2␥2 isozyme (kcat ϭ 35 min Ϫ1 ). 22 ADH3*1 frequency is about 50% to 60% in whites and higher than 90% in Asians. 3,23 ...
Plaque brachytherapy is an effective eye and vision-sparing method to treat patients with intraocular tumors. Practitioners are encouraged to use ABS-OOTF guidelines to enhance their practice.
The three-dimensional structure of betaine aldehyde dehydrogenase, the most abundant aldehyde dehydrogenase (ALDH) of cod liver, has been determined at 2.1 A resolution by the X-ray crystallographic method of molecular replacement.This enzyme represents a novel structure of the highly multiple ALDH, with at least 12 distinct classes in humans. This betaine ALDH of class 9 is different from the two recently determined ALDH structures (classes 2 and 3). Like these, the betaine ALDH structure has three domains, one coenzyme binding domain, one catalytic domain. and one oligomerization domain. Crystals grown in the presence or absence of NAD' have very similar structures and no significant conformational change occurs upon coenzyme binding. This is probably due to the tight interactions between domains within the subunit and between subunits in the tetramer. The oligomerization domains link the catalytic domains together into two 20-stranded pleated sheet structures. The overall structure is similar to that of the tetrameric bovine class 2 and dimeric rat class 3 ALDH, but the coenzyme binding with the nicotinamide in anti conformation, resembles that of class 2 rather than of class 3.
Two types of alcohol dehydrogenase in separate protein families are the "medium-chain" zinc enzymes (including the classical liver and yeast forms) and the "shortchain" enzymes (including the insect form). Although the medium-chain family has been characterized in prokaryotes and many eukaryotes (fungi, plants, cephalopods, and verte-brates), insects have seemed to possess only the short-chain enzyme. We have now also characterized a medium-chain alcohol dehydrogenase in Drosophila. The developmental stages of the fly, compatible with the constitutive nature of the vertebrate enzyme. Taken together, the results bridge a previously apparent gap in the distribution of medium-chain alcohol dehydrogenases and establish a strictly conserved class m enzyme, consistent with an important role for this enzyme in cellular metabolism.The "classical" alcohol dehydrogenase is part of a widespread system of zinc-containing enzymes (1). In mammalian tissues, at least six classes of this enzyme occur. They differ considerably and represent stages between separate enzymes and ordinary isozymes. Class I is the well-known liver enzyme with ethanol dehydrogenase activity (2), class III is identical with glutathione-dependent formaldehyde dehydrogenase (3), class IV is a form preferentially expressed in stomach (4, 5), while classes II, V, and VI, although little studied, are known also to exhibit distinct properties (6, 7, 44). The class origins have been traced to gene duplications early in vertebrate evolution [the I/III duplication (8)] or during that evolution [the IV/I duplication (5)], with emerging activities toward ethanol (9); class III corresponds to an ancestral form. These properties and the different evolutionary patterns, with class III being "constant" and class I "variable" (10), result in a consistent picture of the enzyme system and place the classes of medium-chain alcohol dehydrogenases as separate enzymes in the cellular metabolism.Similarly, another protein family, short-chain dehydrogenases, has also evolved into a family comprising many different enzyme activities, including an alcohol dehydrogenase (11). This form operates by means of a completely different catalytic mechanism and is related to mammalian prostaglandin dehydrogenases/carbonyl reductase (12). Thus far, this alcohol dehydrogenase has been found in insects, the Drosophila enzyme being recognized early to differ from the zinc-containing alcohol dehydrogenases (13,14). Its properties in various Drosophila species are well established (15).These two alcohol dehydrogenase types demonstrate that ethanol dehydrogenase activity has evolved in different manners, with many organisms now employing a medium-chain enzyme, while others depend on a short-chain enzyme. The medium-chain family has not been identified in insects, although it is of ancient origin and has been characterized in other eukaryotes and in prokaryotes. We now show that the family is indeed present also in insects and that its major representative is the typical class III t...
Background: Annotations of completely sequenced genomes reveal that nearly half of the genes identified are of unknown function, and that some belong to uncharacterized gene families. To help resolve such issues, information can be obtained from the comparative analysis of homologous genes in model organisms.
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