1hsz Citations

Three-dimensional structures of the three human class I alcohol dehydrogenases.

Niederhut MS, Gibbons BJ, Perez-Miller S, Hurley TD
Protein Sci 10 697-706 (2001)
Related entries: 1hso, 1ht0

Cited: 35 times
EuropePMC logo PMID: 11274460

Abstract

In contrast with other animal species, humans possess three distinct genes for class I alcohol dehydrogenase and show polymorphic variation in the ADH1B and ADH1C genes. The three class I alcohol dehydrogenase isoenzymes share approximately 93% sequence identity but differ in their substrate specificity and their developmental expression. We report here the first three-dimensional structures for the ADH1A and ADH1C*2 gene products at 2.5 and 2.0 A, respectively, and the structure of the ADH1B*1 gene product in a binary complex with cofactor at 2.2 A. Not surprisingly, the overall structure of each isoenzyme is highly similar to the others. However, the substitution of Gly for Arg at position 47 in the ADH1A isoenzyme promotes a greater extent of domain closure in the ADH1A isoenzyme, whereas substitution at position 271 may account for the lower turnover rate for the ADH1C*2 isoenzyme relative to its polymorphic variant, ADH1C*1. The substrate-binding pockets of each isoenzyme possess a unique topology that dictates each isoenzyme's distinct but overlapping substrate preferences. ADH1*B1 has the most restrictive substrate-binding site near the catalytic zinc atom, whereas both ADH1A and ADH1C*2 possess amino acid substitutions that correlate with their better efficiency for the oxidation of secondary alcohols. These structures describe the nature of their individual substrate-binding pockets and will improve our understanding of how the metabolism of beverage ethanol affects the normal metabolic processes performed by these isoenzymes.

Articles - 1hsz mentioned but not cited (6)

  1. Three-dimensional structures of the three human class I alcohol dehydrogenases. Niederhut MS, Gibbons BJ, Perez-Miller S, Hurley TD. Protein Sci 10 697-706 (2001)
  2. Allosteric site variants of Haemophilus influenzae beta-carbonic anhydrase. Rowlett RS, Tu C, Lee J, Herman AG, Chapnick DA, Shah SH, Gareiss PC. Biochemistry 48 6146-6156 (2009)
  3. Identified the Synergistic Mechanism of Drynariae Rhizoma for Treating Fracture Based on Network Pharmacology. Lin H, Wang X, Wang L, Dong H, Huang P, Cai Q, Mo Y, Huang F, Jiang Z. Evid Based Complement Alternat Med 2019 7342635 (2019)
  4. Natural variability of minimotifs in 1092 people indicates that minimotifs are targets of evolution. Lyon KF, Strong CL, Schooler SG, Young RJ, Roy N, Ozar B, Bachmeier M, Rajasekaran S, Schiller MR. Nucleic Acids Res 43 6399-6412 (2015)
  5. Relating the shape of protein binding sites to binding affinity profiles: is there an association? Simon Z, Vigh-Smeller M, Peragovics A, Csukly G, Zahoránszky-Kohalmi G, Rauscher AA, Jelinek B, Hári P, Bitter I, Málnási-Csizmadia A, Czobor P. BMC Struct Biol 10 32 (2010)
  6. Binding Direction-Based Two-Dimensional Flattened Contact Area Computing Algorithm for Protein-Protein Interactions. Kang BS, Pugalendhi G, Kim KJ. Molecules 22 E1722 (2017)


Reviews citing this publication (11)

  1. Effect of the allelic variants of aldehyde dehydrogenase ALDH2*2 and alcohol dehydrogenase ADH1B*2 on blood acetaldehyde concentrations. Peng GS, Yin SJ. Hum Genomics 3 121-127 (2009)
  2. Metabolic methanol: molecular pathways and physiological roles. Dorokhov YL, Shindyapina AV, Sheshukova EV, Komarova TV. Physiol Rev 95 603-644 (2015)
  3. Targeting Metalloenzymes for Therapeutic Intervention. Chen AY, Adamek RN, Dick BL, Credille CV, Morrison CN, Cohen SM. Chem Rev 119 1323-1455 (2019)
  4. Polymorphism of ethanol-metabolism genes and alcoholism: correlation of allelic variations with the pharmacokinetic and pharmacodynamic consequences. Chen YC, Peng GS, Wang MF, Tsao TP, Yin SJ. Chem Biol Interact 178 2-7 (2009)
  5. Conformational changes and catalysis by alcohol dehydrogenase. Plapp BV. Arch Biochem Biophys 493 3-12 (2010)
  6. Mammalian alcohol dehydrogenases--a comparative investigation at gene and protein levels. Höög JO, Ostberg LJ. Chem Biol Interact 191 2-7 (2011)
  7. Oral cancer and polymorphism of ethanol metabolising genes. Marichalar-Mendia X, Rodriguez-Tojo MJ, Acha-Sagredo A, Rey-Barja N, Aguirre-Urizar JM. Oral Oncol 46 9-13 (2010)
  8. Genetic modification of the effect of alcohol consumption on CHD. Hines LM. Proc Nutr Soc 63 73-79 (2004)
  9. Current View on the Mechanisms of Alcohol-Mediated Toxicity. Birková A, Hubková B, Čižmárová B, Bolerázska B. Int J Mol Sci 22 9686 (2021)
  10. Enzymes and signal pathways in the pathogenesis of alcoholic cardiomyopathy. Leibing E, Meyer T. Herz 41 478-483 (2016)
  11. The Role of Alcohol Dehydrogenase in Drug Metabolism: Beyond Ethanol Oxidation. Di L, Balesano A, Jordan S, Shi SM. AAPS J 23 20 (2021)

Articles citing this publication (18)

  1. Structure of a specific alcohol-binding site defined by the odorant binding protein LUSH from Drosophila melanogaster. Kruse SW, Zhao R, Smith DP, Jones DN. Nat Struct Biol 10 694-700 (2003)
  2. 4-Hydroxynonenal regulates 26S proteasomal degradation of alcohol dehydrogenase. Carbone DL, Doorn JA, Petersen DR. Free Radic Biol Med 37 1430-1439 (2004)
  3. The structure of an alcohol dehydrogenase from the hyperthermophilic archaeon Aeropyrum pernix. Guy JE, Isupov MN, Littlechild JA. J Mol Biol 331 1041-1051 (2003)
  4. Hominids adapted to metabolize ethanol long before human-directed fermentation. Carrigan MA, Uryasev O, Frye CB, Eckman BL, Myers CR, Hurley TD, Benner SA. Proc Natl Acad Sci U S A 112 458-463 (2015)
  5. The ternary complex of Pseudomonas aeruginosa alcohol dehydrogenase with NADH and ethylene glycol. Levin I, Meiri G, Peretz M, Burstein Y, Frolow F. Protein Sci 13 1547-1556 (2004)
  6. The crystal structure of the allosteric non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase from the hyperthermophilic archaeum Thermoproteus tenax. Pohl E, Brunner N, Wilmanns M, Hensel R. J Biol Chem 277 19938-19945 (2002)
  7. Oxidation of methanol, ethylene glycol, and isopropanol with human alcohol dehydrogenases and the inhibition by ethanol and 4-methylpyrazole. Lee SL, Shih HT, Chi YC, Li YP, Yin SJ. Chem Biol Interact 191 26-31 (2011)
  8. Crystal structure of the vertebrate NADP(H)-dependent alcohol dehydrogenase (ADH8). Rosell A, Valencia E, Parés X, Fita I, Farrés J, Ochoa WF. J Mol Biol 330 75-85 (2003)
  9. Tetrameric NAD-dependent alcohol dehydrogenase. Karlsson A, El-Ahmad M, Johansson K, Shafqat J, Jörnvall H, Eklund H, Ramaswamy S. Chem Biol Interact 143-144 239-245 (2003)
  10. Human Glycerol 3-Phosphate Dehydrogenase: X-ray Crystal Structures That Guide the Interpretation of Mutagenesis Studies. Mydy LS, Cristobal JR, Katigbak RD, Bauer P, Reyes AC, Kamerlin SCL, Richard JP, Gulick AM. Biochemistry 58 1061-1073 (2019)
  11. The natural history of class I primate alcohol dehydrogenases includes gene duplication, gene loss, and gene conversion. Carrigan MA, Uryasev O, Davis RP, Zhai L, Hurley TD, Benner SA. PLoS One 7 e41175 (2012)
  12. Structural insight into the conformational change of alcohol dehydrogenase from Arabidopsis thaliana L. during coenzyme binding. Chen F, Wang P, An Y, Huang J, Xu Y. Biochimie 108 33-39 (2015)
  13. Inversion of substrate stereoselectivity of horse liver alcohol dehydrogenase by substitutions of Ser-48 and Phe-93. Kim K, Plapp BV. Chem Biol Interact 276 77-87 (2017)
  14. The effect of metal ions on the binding of ethanol to human alcohol dehydrogenase beta2beta2. Liu HL, Ho Y, Hsu CM. J Biomed Sci 10 302-312 (2003)
  15. Opossum alcohol dehydrogenases: Sequences, structures, phylogeny and evolution: evidence for the tandem location of ADH genes on opossum chromosome 5. Holmes RS. Chem Biol Interact 178 8-15 (2009)
  16. Specificity of human alcohol dehydrogenase 1C*2 (gamma2gamma2) for steroids and simulation of the uncompetitive inhibition of ethanol metabolism. Plapp BV, Berst KB. Chem Biol Interact 143-144 183-193 (2003)
  17. ADH1B, ADH1B/C and CYP2E1 Gene Polymorphism and the Risk of Fetal Alcohol Spectrum Disorder. Kukowka A, Brzuchalski B, Kurzawski M, Malinowski D, Białecka MA. Genes (Basel) 14 1392 (2023)
  18. Enhanced active-site electric field accelerates enzyme catalysis. Zheng C, Ji Z, Mathews II, Boxer SG. Nat Chem (2023)


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