Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C1332347 (ADH)
2,230 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Human chi-alcohol dehydrogenase (chi-ADH) is a zinc-containing dimeric enzyme responsible for the oxidation of long-chain alcohols and omega-hydroxyfatty acids. Class-III ADHs, of which chi-ADH is the prototype, are widely produced and well conserved during evolution. This suggests that they fulfill important housekeeping roles in cellular metabolism. Recent evidence suggests that class-III ADH and formaldehyde dehydrogenase (FDH) are the same enzyme. We have isolated and characterized two overlapping genomic clones that cover the entire ADH5 (FDH) gene. ADH5 is composed of nine exons and eight introns. Two major transcription start points were identified by primer extension. The 5' nontranslated region is unusual in that it contains two additional upstream ATG codons, which would encode peptides of 20 and 10 amino acids. Neither of the upstream ATGs is in a good context for translation initiation, whereas the ATG initiating &khgr;-ADH is in a favorable context. The 5' region of ADH5 is a CpG island; it is extremely G+C rich and has many CpG doublets. It does not contain either a TATA box or a CAAT box. This is consistent with ubiquitous expression, and contrasts with the promoters of all previously cloned ADH genes, which are expressed in a tissue-specific manner. The 5' region of ADH5 contains consensus binding sites for the transcriptional regulatory proteins, Sp1, AP2, LF-A1, NF-1, NF-A2, and NF-E1. A 1.5-kb upstream fragment from ADH5 was able to drive the transcription of a cat reporter gene at high levels in monkey kidney cells (CV-1). Several processed pseudogenes were also isolated.
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PMID:Cloning and characterization of the ADH5 gene encoding human alcohol dehydrogenase 5, formaldehyde dehydrogenase. 144 28

We have cloned and sequenced a cDNA encoding the mouse class III alcohol dehydrogenase, Adh-B2. Adh-B2 mRNA is detectable in all the mouse tissues tested. Class III ADHs are highly conserved: the deduced amino acid sequence of the mouse Adh-B2 is 91 to 97% identical to the human, horse and rat liver enzymes. The mouse Adh-B2 cDNA is 87% identical in nucleotide sequence to the human chi-ADH cDNA. Previously, a slower rate of evolutionary divergence of the amino acid sequences of class III ADH proteins was detected and ascribed to functional constraints upon the protein. Our analysis of the nucleotide sequences demonstrates that this cannot be the entire explanation, since the rate of silent (synonymous) nucleotide substitutions is also lower in the class III ADHs than in the class I ADHs.
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PMID:Molecular cloning of mouse alcohol dehydrogenase-B2 cDNA: nucleotide sequences of the class III ADH genes evolve slowly even for silent substitutions. 147 9

Human liver class III alcohol dehydrogenase (chi chi-ADH) and glutathione dependent formaldehyde dehydrogenase are the same enzyme. The enzyme, chi chi-ADH, exhibits a kcat of 200 min-1 and a km of 4 microM for the oxidation of formaldehyde, but only in the presence of GSH. In the absence of GSH the enzyme is essentially inactive toward formaldehyde but very active toward long chain alcohols. Thus, as in the rat (Koivusalo, M., Baumann, M., and Uotila, L. (1989) FEBS Letters 257, 105-109), the class III alcohol dehydrogenase and the GSH dependent formaldehyde dehydrogenase are identical enzymes. S-Hydroxymethyl derivatives of 8-thiooctanoate and lipoate are also very active substrates. The activity is specific for class III alcohol dehydrogenase; neither the class I and II nor the horse EE, ES, and SS isozymes oxidize hemithiolacetals. o-Phenanthroline competitively inhibits both activities and the two substrate types compete with each other.
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PMID:Human liver class III alcohol and glutathione dependent formaldehyde dehydrogenase are the same enzyme. 187 53

The three-dimensional structure of rat liver formaldehyde dehydrogenase (FALDH), previously known as class III alcohol dehydrogenase, was constructed using computer graphics and computer programs developed for model building. The construction is based on horse liver alcohol dehydrogenase (EE-ADH), whose structure has been elucidated by X-ray crystallography. The high sequence homology between the two enzymes makes knowledge-based modelling feasible in this case. The model shows a remarkable similarity to horse liver alcohol dehydrogenase especially in the NAD-binding domain. Certain mutations, and the one insertion in FALDH compared to EE-ADH in particular, have cause important changes in the substrate binding site, and thus aliphatic alcohols have been replaced by hemi-thioacetals as favourable substrates.
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PMID:Model for the structure of formaldehyde dehydrogenase based on alcohol dehydrogenase. 188 14

Class III alcohol dehydrogenase (chi chi-ADH) from human liver binds both ethanol and acetaldehyde so poorly that their Km values cannot be determined, even at ethanol concentrations up to 3 M. However, long-chain carboxylates, e.g., pentanoate, octanoate, deoxycholate, and other anions, substantially enhance the binding of ethanol and other substrates and hence the activity of class III ADH up to 30-fold. Thus, in the presence of 1 mM octanoate, ethanol displays Michaelis-Menten kinetics. The degree of activation depends on the size both of the substrate and of the activator; generally, longer, negatively charged activators result in greater activation. At pH 10, the activator binds to the E-NAD+ form of the enzyme to potentiate substrate binding. Pentanoate activates methylcrotyl alcohol oxidation and methylcrotyl aldehyde reduction 14- and 30-fold, respectively. Such enhancements of both oxidation and reduction are specific for class III ADH; neither class I nor class II shows this effect. The implications as to the nature of the physiological substrate(s) of class III ADH are discussed in light of the recent finding that this ADH and glutathione-dependent formaldehyde dehydrogenase are identical. A new rapid purification procedure for chi chi-ADH is presented.
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PMID:Hydrophobic anion activation of human liver chi chi alcohol dehydrogenase. 204 14

Three different dehydrogenases able to oxidize formaldehyde were found in the Gram-positive methylotroph, Nocardia sp. 239: an NAD-dependent aldehyde dehydrogenase (NA-ADH), and NAD- and factor-dependent formaldehyde dehydrogenase (FD-FDH), and a dye-linked aldehyde dehydrogenase (DL-ADH). The ratio of the activities observed for the two NAD-linked enzymes varied with growth conditions: batch-wise grown cells had nearly the same activities for both enzymes; in fed batch-wise grown cells (methanol limitation) only FD-FDH was detected. The latter is clearly involved in formaldehyde oxidation, since the enzyme and the factor were found only in methanol-grown cells and the enzyme is specific for formaldehyde. In contrast, the two aldehyde dehydrogenases may have significance for aldehyde dissimilation in general, since both activities could also be demonstrated in ethanol-grown cells (but not in glucose-grown cells) and higher aldehydes are even better substrates than formaldehyde. NA-ADH was purified to homogeneity. The enzyme seems to be a homotetramer since it showed a relative molecular mass of 200,000 and the denaturated form of 55,000. Other characteristics are as follows: the enzyme showed substrate inhibition for the aldehydes tested; optimal activity was found at pH 9.2; the reverse reaction was not observed; the enzyme was specific for NAD; GSH, K+, or NH4+ addition did not stimulate formaldehyde oxidation; the order of NAD and substrate addition to the enzyme was not important; several compounds able to block SH groups were inhibitory. Comparison with NAD-linked aldehyde dehydrogenases from Gram-negative bacteria showed that the Nocardia enzyme is distinct from the enzyme of Pseudomonas putida (EC 1.2.1.46) and of Hyphomicrobium X.
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PMID:Different types of formaldehyde-oxidizing dehydrogenases in Nocardia species 239: purification and characterization of an NAD-dependent aldehyde dehydrogenase. 224 Nov 49

Modification of class III alcohol dehydrogenase (chi chi-ADH) with phenylglyoxal eliminates fatty acid activation by pentanoate and octanoate and concomitantly increases specific activity toward ethanol and 3-methylcrotyl alcohol 2-3-fold. In contrast, chemical modification decreases activity toward S-(hydroxymethyl)glutathione (FDH activity) and 12-hydroxydodecanoic acid by increasing Km, pointing to a role for arginine in binding anionic substrates. Modification with [7-14C]phenylglyoxal indicates that only one arginine residue per subunit is modified. Sequence analysis of tryptic peptides indicates that Arg-115 is modified. Site-directed mutation of this residue to alanine eliminates both fatty acid activation and FDH activity, thus confirming the identity of the modified residue and its function. These results account in part for the unique specificity of chi chi-ADH relative to other human ADH isozymes.
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PMID:Role of arginine 115 in fatty acid activation and formaldehyde dehydrogenase activity of human class III alcohol dehydrogenase. 849 91

This study was undertaken to identify the cytosolic 40-kDa zinc-containing alcohol dehydrogenases that oxidize all-trans-retinol and steroid alcohols in fetal tissues. Degenerate oligonucleotide primers were used to amplify by polymerase chain reaction 500-base pair fragments of alcohol dehydrogenase cDNAs from chick embryo limb buds and heart. cDNA fragments that encode an unknown putative alcohol dehydrogenase as well as the class III alcohol dehydrogenase were identified. The new cDNA hybridized with two messages of approximately 2 and 3 kilobase pairs in the adult chicken liver but not in the adult heart, muscle, testis, or brain. The corresponding complete cDNA clones with a total length of 1390 base pairs were isolated from a chicken liver lambdagt11 cDNA library. The open reading frame encoded a 375-amino acid polypeptide that exhibited 67 and 68% sequence identity with chicken class I and III alcohol dehydrogenases, respectively, and had lower identity with mammalian class II (55-58%) and IV (62%) isozymes. Expression of the new cDNA in Escherichia coli yielded an active alcohol dehydrogenase (ADH-F) with subunit molecular mass of approximately 40 kDa. The specific activity of the recombinant enzyme, calculated from active site titration of NADH binding, was 3.4 min-1 for ethanol at pH 7.4 and 25 degrees C. ADH-F was stereospecific for the 3beta,5alpha- versus 3beta,5beta-hydroxysteroids. The Km value for ethanol at pH 7.4 was 17 mM compared with 56 microM for all-trans-retinol and 31 microM for epiandrosterone. Antiserum against ADH-F recognized corresponding protein in the chicken liver homogenate. We suggest that ADH-F represents a new class of alcohol dehydrogenase, class VII, based on its primary structure and catalytic properties.
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PMID:cDNA sequence and catalytic properties of a chick embryo alcohol dehydrogenase that oxidizes retinol and 3beta,5alpha-hydroxysteroids. 905 52

This article reports the cloning of the genes encoding the Arabidopsis and rice class III ADH enzymes, members of the alcohol dehydrogenase or medium chain reductase/dehydrogenase superfamily of proteins with glutathione-dependent formaldehyde dehydrogenase activity (GSH-FDH). Both genes contain eight introns in exactly the same positions, and these positions are conserved in plant ethanol-active Adh genes (class P). These data provide further evidence that plant class P genes have evolved from class III genes by gene duplication and acquisition of new substrate specificities. The position of introns and similarities in the nucleic acid and amino acid sequences of the different classes of ADH enzymes in plants and humans suggest that plant and animal class III enzymes diverged before they duplicated to give rise to plant and animal ethanol-active ADH enzymes. Plant class P ADH enzymes have gained substrate specificities and evolved promoters with different expression properties, in keeping with their metabolic function as part of the alcohol fermentation pathway.
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PMID:Cloning of the Arabidopsis and rice formaldehyde dehydrogenase genes: implications for the origin of plant ADH enzymes. 921 14

Formaldehyde, a major industrial chemical, is classified as a carcinogen because of its high reactivity with DNA. It is inactivated by oxidative metabolism to formate in humans by glutathione-dependent formaldehyde dehydrogenase. This NAD(+)-dependent enzyme belongs to the family of zinc-dependent alcohol dehydrogenases with 40 kDa subunits and is also called ADH3 or chi-ADH. The first step in the reaction involves the nonenzymatic formation of the S-(hydroxymethyl)glutathione adduct from formaldehyde and glutathione. When formaldehyde concentrations exceed that of glutathione, nonoxidizable adducts can be formed in vitro. The S-(hydroxymethyl)glutathione adduct will be predominant in vivo, since circulating glutathione concentrations are reported to be 50 times that of formaldehyde in humans. Initial velocity, product inhibition, dead-end inhibition, and equilibrium binding studies indicate that the catalytic mechanism for oxidation of S-(hydroxymethyl)glutathione and 12-hydroxydodecanoic acid (12-HDDA) with NAD(+) is random bi-bi. Formation of an E.NADH.12-HDDA abortive complex was evident from equilibrium binding studies, but no substrate inhibition was seen with 12-HDDA. 12-Oxododecanoic acid (12-ODDA) exhibited substrate inhibition, which is consistent with a preferred pathway for substrate addition in the reductive reaction and formation of an abortive E.NAD(+).12-ODDA complex. The random mechanism is consistent with the published three-dimensional structure of the formaldehyde dehydrogenase.NAD(+) complex, which exhibits a unique semi-open coenzyme-catalytic domain conformation where substrates can bind or dissociate in any order.
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PMID:Kinetic mechanism of human glutathione-dependent formaldehyde dehydrogenase. 1097 56


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