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 ...
Heteromeric amino acid transporters (HATs) are the unique example, known in all kingdoms of life, of solute transporters composed of two subunits linked by a conserved disulfide bridge. In metazoans, the heavy subunit is responsible for the trafficking of the heterodimer to the plasma membrane, and the light subunit is the transporter. HATs are involved in human pathologies such as amino acidurias, tumor growth and invasion, viral infection and cocaine addiction. However structural information about interactions between the heavy and light subunits of HATs is scarce. In this work, transmission electron microscopy and single-particle analysis of purified human 4F2hc/L-type amino acid transporter 2 (LAT2) heterodimers overexpressed in the yeast Pichia pastoris, together with docking analysis and crosslinking experiments, reveal that the extracellular domain of 4F2hc interacts with LAT2, almost completely covering the extracellular face of the transporter. 4F2hc increases the stability of the light subunit LAT2 in detergent-solubilized Pichia membranes, allowing functional reconstitution of the heterodimer into proteoliposomes. Moreover, the extracellular domain of 4F2hc suffices to stabilize solubilized LAT2. The interaction of 4F2hc with LAT2 gives insights into the structural bases for light subunit recognition and the stabilizing role of the ancillary protein in HATs.CD98hc | 4F2hc ectodomain H eteromeric amino acid transporters (HATs) are composed of two subunits, a heavy (SLC3 family) and a light subunit [SLC7 or L-type amino acid transporter (LAT) family] linked by a conserved disulfide bridge (1). HATs are amino acid exchangers (1), and this transport activity resides in the light subunit (2). The heavy subunit (either 4F2hc or rBAT) is essential for trafficking of the holotransporter to the plasma membrane (3, 4). In mammals, six transporters heterodimerize with 4F2hc, and only one heterodimerizes with rBAT. The rBAT/b 0,+ AT complex is a dimer of heterodimers in which the light subunit is required for proper rBAT folding and stability (5, 6). In contrast, 4F2hc-associated transporters are simple heterodimers (6), and possible stabilizing roles of the two subunits in the biogenesis of the heterodimer have not been described.HATs have major impacts on human health and are involved directly in amino acidurias (cystinuria and lysinuric protein intolerance), tumor cell growth, glioma invasion, Kaposi's sarcomaassociated herpesvirus infection, and cocaine relapse (1). In addition to the role of HATs in amino acid transport, 4F2hc heterodimers mediate β1-and β3-integrin signaling (7).Structural information about HATs is scarce (1). The heavy subunits are type II membrane N-glycoproteins with a single transmembrane domain (TMD), an intracellular N terminus, and a large extracellular C terminus with sequence homology with bacterial α-amylases. Indeed, the atomic structure of the extracellular domain (ED) of human 4F2hc (4F2hc-ED) is similar to that of bacterial glucosidases [i.e., a triose phosphate isomerase barr...
Human heteromeric amino acid transporters (HATs) are membrane protein complexes that facilitate the transport of specific amino acids across cell membranes. Loss of function or overexpression of these transporters is implicated in several human diseases such as renal aminoacidurias and cancer. HATs are composed of two subunits, a heavy and a light subunit, that are covalently connected by a disulphide bridge. Light subunits catalyse amino acid transport and consist of twelve transmembrane α-helix domains. Heavy subunits are type II membrane N-glycoproteins with a large extracellular domain and are involved in the trafficking of the complex to the plasma membrane. Structural information on HATs is scarce because of the difficulty in heterologous overexpression. Recently, we had a major breakthrough with the overexpression of a recombinant HAT, 4F2hc-LAT2, in the methylotrophic yeast Pichia pastoris. Microgram amounts of purified protein made possible the reconstruction of the first 3D map of a human HAT by negative-stain transmission electron microscopy. Here we report the important stabilization of purified human 4F2hc-LAT2 using a combination of two detergents, i.e., n-dodecyl-β-D-maltopyranoside and lauryl maltose neopentyl glycol, and cholesteryl hemisuccinate. The superior quality and stability of purified 4F2hc-LAT2 allowed the measurement of substrate binding by scintillation proximity assay. In addition, an improved 3D map of this HAT could be obtained. The detergent-induced stabilization of the purified human 4F2hc-LAT2 complex presented here paves the way towards its crystallization and structure determination at high-resolution, and thus the elucidation of the working mechanism of this important protein complex at the molecular level.
Heteromeric amino acid transporters (HATs) are relevant targets for structural studies. On the one hand, HATs are involved in inherited and acquired human pathologies. On the other hand, these molecules are the only known examples of solute transporters composed of two subunits (heavy and light) linked by a disulfide bridge. Unfortunately, structural knowledge of HATs is scarce and limited to the atomic structure of the ectodomain of a heavy subunit (human 4F2hc-ED) and distant prokaryotic homologues of the light subunits that share a LeuT-fold. Recent data on human 4F2hc/LAT2 at nanometer resolution revealed 4F2hc-ED positioned on top of the external loops of the light subunit LAT2. Improved resolution of the structure of HATs, combined with conformational studies, is essential to establish the structural bases for light subunit recognition and to evaluate the functional relevance of heavy and light subunit interactions for the amino acid transport cycle.
Gastric tissues from amphibian Rana perezi express the only vertebrate alcohol dehydrogenase (ADH8) that is specific for NADP(H) instead of NAD(H). In the crystallographic ADH8-NADP min؊1 ) similar to those of the wild-type enzyme with NADP(H). The complete reversal of ADH8 coenzyme specificity was therefore attained by the substitution of only three consecutive residues in the phosphate-binding site, an unprecedented achievement within the ADH family.Coenzyme specificity is an important property of NAD(P)-dependent oxidoreductases that is linked to their metabolic function. Thus the type of coenzyme, NAD ϩ or NADP ϩ , often distinguishes between enzymes involved in alternative pathways (e.g. oxidative versus reductive or degradative versus biosynthetic). Because NAD ϩ and NADP ϩ only differ structurally in the phosphate group esterified at the 2Ј position of adenosine ribose, dehydrogenases must possess a limited number of residues to discriminate between the two coenzyme types. Moreover, among dehydrogenases from a given enzyme family, the same protein fold is often used to bind either coenzyme type and even some enzymes show dual activity, meaning that they can use both coenzymes with similar efficiency (1).A rather unique NADP-dependent alcohol dehydrogenase (ADH8) 1 was discovered in the gastric tissues of amphibians (2). ADH8 belongs to the medium chain dehydrogenase/reductase (MDR) superfamily and is phylogenetically related to the NAD-dependent vertebrate ADH family. This enzyme is active with ethanol and functionally may participate in the reduction of retinal to retinol (k cat /K m all-trans-retinal ϭ 33,750 mM Ϫ1 min Ϫ1 ). Recently, the three-dimensional structure of the ADH8-NADP ϩ binary complex was determined at 1. define a binding pocket for the terminal phosphate group of NADP(H).Henceforth residue numbering will correspond to that of horse ADH1 with the Swiss Prot entry P00327. Interestingly, NADPdependent ADHs from distantly related microorganisms (5-7), also have a glycine and two more hydrophilic residues at the positions corresponding to 223, 224, and 225, respectively. In ADHs, residue 223 is located at the C-terminal end of the second -strand of the Rossmann fold (8) and classically is considered as determinant for coenzyme specificity. The substitution D223G, as found in ADH8, would avoid the possible steric and electrostatic hindrances because of the extra phosphate group of NADP(H). In fact, different attempts to switch the coenzyme specificity in medium chain ADHs have been focused on mutations involving residue 223 (9 -12). However, full reversal of coenzyme specificity, in terms of having a mutant enzyme as catalytically efficient as the wild type, has been rarely achieved. This implies that conversion of coenzyme specificity may require multiple substitutions in the coenzymebinding domain. Other residues found in ADH8, such as Thr 224 and His 225 , which are making hydrogen bonds with the oxygen atoms from the terminal phosphate group (3), could also be important in defining co...
Different crystal forms diffracting to high resolution have been obtained for two NADP(H)-dependent alcohol dehydrogenases, members of the medium-chain dehydrogenase/reductase superfamily: ScADHVI from Saccharomyces cerevisiae and ADH8 from Rana perezi. ScADHVI is a broad-speci®city enzyme, with a sequence identity lower than 25% with respect to all other ADHs of known structure. The best crystals of ScADHVI diffracted beyond 2.8 A Ê resolution and belonged to the trigonal space group P3 1 21 (or to its enantiomorph P3 2 21), with unit-cell parameters a = b = 102.2, c = 149.7 A Ê , = 120 . These crystals were produced by the hangingdrop vapour-diffusion method using ammonium sulfate as precipitant. Packing considerations together with the self-rotation function and the native Patterson map seem to indicate the presence of only one subunit per asymmetric unit, with a volume solvent content of about 80%. ADH8 from R. perezi is the only NADP(H)-dependent ADH from vertebrates characterized to date. Crystals of ADH8 obtained both in the absence and in the presence of NADP + using polyethylene glycol and lithium sulfate as precipitants diffracted to 2.2 and 1.8 A Ê , respectively, using synchrotron radiation. These crystals were isomorphous, space group C2, with approximate unitcell parameters a = 122, b = 79, c = 91 A Ê , = 113 and contain one dimer per asymmetric unit, with a volume solvent content of about 50%.
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