3bwm Citations

Crystal structures of human 108V and 108M catechol O-methyltransferase.

Rutherford K, Le Trong I, Stenkamp RE, Parson WW
J Mol Biol 380 120-30 (2008)
Cited: 79 times
EuropePMC logo PMID: 18486144

Abstract

Catechol O-methyltransferase (COMT) plays important roles in the metabolism of catecholamine neurotransmitters and catechol estrogens. The development of COMT inhibitors for use in the treatment of Parkinson's disease has been aided by crystallographic structures of the rat enzyme. However, the human and rat proteins have significantly different substrate specificities. Additionally, human COMT contains a common valine-methionine polymorphism at position 108. The methionine protein is less stable than the valine polymorph, resulting in decreased enzyme activity and protein levels in vivo. Here we describe the crystal structures of the 108V and 108M variants of the soluble form of human COMT bound with S-adenosylmethionine (SAM) and a substrate analog, 3,5-dinitrocatechol. The polymorphic residue 108 is located in the alpha5-beta3 loop, buried in a hydrophobic pocket approximately 16 A from the SAM-binding site. The 108V and 108M structures are very similar overall [RMSD of C(alpha) atoms between two structures (C(alpha) RMSD)=0.2 A], and the active-site residues are superposable, in accord with the observation that SAM stabilizes 108M COMT. However, the methionine side chain is packed more tightly within the polymorphic site and, consequently, interacts more closely with residues A22 (alpha2) and R78 (alpha4) than does valine. These interactions of the larger methionine result in a 0.7-A displacement in the backbone structure near residue 108, which propagates along alpha1 and alpha5 toward the SAM-binding site. Although the overall secondary structures of the human and rat proteins are very similar (C(alpha) RMSD=0.4 A), several nonconserved residues are present in the SAM-(I89M, I91M, C95Y) and catechol- (C173V, R201M, E202K) binding sites. The human protein also contains three additional solvent-exposed cysteine residues (C95, C173, C188) that may contribute to intermolecular disulfide bond formation and protein aggregation.

Reviews - 3bwm mentioned but not cited (9)

  1. The structural biology of oestrogen metabolism. Thomas MP, Potter BV. J Steroid Biochem Mol Biol 137 27-49 (2013)
  2. Targeting Metalloenzymes for Therapeutic Intervention. Chen AY, Adamek RN, Dick BL, Credille CV, Morrison CN, Cohen SM. Chem Rev 119 1323-1455 (2019)
  3. Bioinformatics and variability in drug response: a protein structural perspective. Lahti JL, Tang GW, Capriotti E, Liu T, Altman RB. J R Soc Interface 9 1409-1437 (2012)
  4. Structure-based drug design of catechol-O-methyltransferase inhibitors for CNS disorders. Ma Z, Liu H, Wu B. Br J Clin Pharmacol 77 410-420 (2014)
  5. Recent Developments in New Therapeutic Agents against Alzheimer and Parkinson Diseases: In-Silico Approaches. Cruz-Vicente P, Passarinha LA, Silvestre S, Gallardo E. Molecules 26 2193 (2021)
  6. A structural metagenomics pipeline for examining the gut microbiome. Walker ME, Simpson JB, Redinbo MR. Curr Opin Struct Biol 75 102416 (2022)
  7. Analytical methodologies for sensing catechol-O-methyltransferase activity and their applications. Wang FY, Wang P, Zhao DF, Gonzalez FJ, Fan YF, Xia YL, Ge GB, Yang L. J Pharm Anal 11 15-27 (2021)
  8. Insights into S-adenosyl-l-methionine (SAM)-dependent methyltransferase related diseases and genetic polymorphisms. Li J, Sun C, Cai W, Li J, Rosen BP, Chen J. Mutat Res Rev Mutat Res 788 108396 (2021)
  9. Prevention of Deficit in Neuropsychiatric Disorders through Monitoring of Arsenic and Its Derivatives as Well as Through Bioinformatics and Cheminformatics. Avram S, Udrea AM, Negrea A, Ciopec M, Duteanu N, Postolache C, Duda-Seiman C, Duda-Seiman D, Shaposhnikov S. Int J Mol Sci 20 E1804 (2019)

Articles - 3bwm mentioned but not cited (37)

  1. How Large Should the QM Region Be in QM/MM Calculations? The Case of Catechol O-Methyltransferase. Kulik HJ, Zhang J, Klinman JP, Martínez TJ. J Phys Chem B 120 11381-11394 (2016)
  2. Enzymatic methyl transfer: role of an active site residue in generating active site compaction that correlates with catalytic efficiency. Zhang J, Zhang J, Klinman JP. J Am Chem Soc 133 17134-17137 (2011)
  3. An Ancient Fingerprint Indicates the Common Ancestry of Rossmann-Fold Enzymes Utilizing Different Ribose-Based Cofactors. Laurino P, Tóth-Petróczy Á, Meana-Pañeda R, Lin W, Truhlar DG, Tawfik DS. PLoS Biol 14 e1002396 (2016)
  4. Integration of Tmc1/2 into the mechanotransduction complex in zebrafish hair cells is regulated by Transmembrane O-methyltransferase (Tomt). Erickson T, Morgan CP, Olt J, Hardy K, Busch-Nentwich E, Maeda R, Clemens R, Krey JF, Nechiporuk A, Barr-Gillespie PG, Marcotti W, Nicolson T. Elife 6 e28474 (2017)
  5. Mediation of donor-acceptor distance in an enzymatic methyl transfer reaction. Zhang J, Kulik HJ, Martinez TJ, Klinman JP. Proc Natl Acad Sci U S A 112 7954-7959 (2015)
  6. Life beyond the Tanimoto coefficient: similarity measures for interaction fingerprints. Rácz A, Bajusz D, Héberger K. J Cheminform 10 48 (2018)
  7. Structural mechanism of S-adenosyl methionine binding to catechol O-methyltransferase. Tsao D, Diatchenko L, Dokholyan NV. PLoS One 6 e24287 (2011)
  8. COMT gene locus: new functional variants. Meloto CB, Segall SK, Smith S, Parisien M, Shabalina SA, Rizzatti-Barbosa CM, Gauthier J, Tsao D, Convertino M, Piltonen MH, Slade GD, Fillingim RB, Greenspan JD, Ohrbach R, Knott C, Maixner W, Zaykin D, Dokholyan NV, Reenilä I, Männistö PT, Diatchenko L. Pain 156 2072-2083 (2015)
  9. Why does the giant panda eat bamboo? A comparative analysis of appetite-reward-related genes among mammals. Jin K, Xue C, Wu X, Qian J, Zhu Y, Yang Z, Yonezawa T, Crabbe MJ, Cao Y, Hasegawa M, Zhong Y, Zheng Y. PLoS One 6 e22602 (2011)
  10. A hotspot of inactivation: The A22S and V108M polymorphisms individually destabilize the active site structure of catechol O-methyltransferase. Rutherford K, Daggett V. Biochemistry 48 6450-6460 (2009)
  11. Serotonin-induced hypersensitivity via inhibition of catechol O-methyltransferase activity. Tsao D, Wieskopf JS, Rashid N, Sorge RE, Redler RL, Segall SK, Mogil JS, Maixner W, Dokholyan NV, Diatchenko L. Mol Pain 8 25 (2012)
  12. Hydrogen deuterium exchange defines catalytically linked regions of protein flexibility in the catechol O-methyltransferase reaction. Zhang J, Balsbaugh JL, Gao S, Ahn NG, Klinman JP. Proc Natl Acad Sci U S A 117 10797-10805 (2020)
  13. Large-scale QM/MM free energy simulations of enzyme catalysis reveal the influence of charge transfer. Kulik HJ. Phys Chem Chem Phys 20 20650-20660 (2018)
  14. Equatorial Active Site Compaction and Electrostatic Reorganization in Catechol-O-methyltransferase. Czarnota S, Johannissen LO, Baxter NJ, Rummel F, Wilson AL, Cliff MJ, Levy CW, Scrutton NS, Waltho JP, Hay S. ACS Catal 9 4394-4401 (2019)
  15. Examining the Origin of Catalytic Power of Catechol O-Methyltransferase. Chen X, Schwartz SD. ACS Catal 9 9870-9879 (2019)
  16. Using S-adenosyl-L-homocysteine capture compounds to characterize S-adenosyl-L-methionine and S-adenosyl-L-homocysteine binding proteins. Brown LJ, Baranowski M, Wang Y, Schrey AK, Lenz T, Taverna SD, Cole PA, Sefkow M. Anal Biochem 467 14-21 (2014)
  17. Computational Investigation of the Interplay of Substrate Positioning and Reactivity in Catechol O-Methyltransferase. Patra N, Ioannidis EI, Kulik HJ. PLoS One 11 e0161868 (2016)
  18. Identification of Small Molecule Inhibitors of Human As(III) S-Adenosylmethionine Methyltransferase (AS3MT). Dong H, Madegowda M, Nefzi A, Houghten RA, Giulianotti MA, Rosen BP. Chem Res Toxicol 28 2419-2425 (2015)
  19. Regioselectivity of Catechol O-Methyltransferase Confers Enhancement of Catalytic Activity. Tsao D, Liu S, Dokholyan NV. Chem Phys Lett 506 135-138 (2011)
  20. How metal substitution affects the enzymatic activity of catechol-o-methyltransferase. Sparta M, Alexandrova AN. PLoS One 7 e47172 (2012)
  21. Polymorphisms and disease: hotspots of inactivation in methyltransferases. Rutherford K, Daggett V. Trends Biochem Sci 35 531-538 (2010)
  22. A Multi-scale Computational Platform to Mechanistically Assess the Effect of Genetic Variation on Drug Responses in Human Erythrocyte Metabolism. Mih N, Brunk E, Bordbar A, Palsson BO. PLoS Comput Biol 12 e1005039 (2016)
  23. Neuroprotective and Neurorescue Mode of Action of Bacopa monnieri (L.) Wettst in 1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine-Induced Parkinson's Disease: An In Silico and In Vivo Study. Singh B, Pandey S, Rumman M, Kumar S, Kushwaha PP, Verma R, Mahdi AA. Front Pharmacol 12 616413 (2021)
  24. Correlation between Virtual Screening Performance and Binding Site Descriptors of Protein Targets. Shamsara J. Int J Med Chem 2018 3829307 (2018)
  25. Deciphering the underlying mechanisms of Diesun Miaofang in traumatic injury from a systems pharmacology perspective. Zheng CS, Fu CL, Pan CB, Bao HJ, Chen XQ, Ye HZ, Ye JX, Wu GW, Li XH, Xu HF, Xu XJ, Liu XX. Mol Med Rep 12 1769-1776 (2015)
  26. Design, synthesis and evaluation of 3-hydroxypyridin-4-ones as inhibitors of catechol-O-methyltransferase. de Beer J, Petzer JP, Lourens ACU, Petzer A. Mol Divers 25 753-762 (2021)
  27. 1H, 15N, 13C backbone resonance assignments of human soluble catechol O-methyltransferase in complex with S-adenosyl-L-methionine and 3,5-dinitrocatechol. Czarnota S, Baxter NJ, Cliff MJ, Waltho JP, Scrutton NS, Hay S. Biomol NMR Assign 11 57-61 (2017)
  28. CHARMM-GUI LBS Finder & Refiner for Ligand Binding Site Prediction and Refinement. Guterres H, Park SJ, Zhang H, Im W. J Chem Inf Model 61 3744-3751 (2021)
  29. Cheminformatic quantum mechanical enzyme model design: A catechol-O-methyltransferase case study. Summers TJ, Cheng Q, Palma MA, Pham DT, Kelso DK, Webster CE, DeYonker NJ. Biophys J 120 3577-3587 (2021)
  30. Computational analysis of deleterious single nucleotide polymorphisms in catechol O-Methyltransferase conferring risk to post-traumatic stress disorder. Chitrala KN, Nagarkatti P, Nagarkatti M. J Psychiatr Res 138 207-218 (2021)
  31. DeepBindGCN: Integrating Molecular Vector Representation with Graph Convolutional Neural Networks for Protein-Ligand Interaction Prediction. Zhang H, Saravanan KM, Zhang JZH. Molecules 28 4691 (2023)
  32. Factors That Determine the Variation of Equilibrium and Kinetic Properties of QM/MM Enzyme Simulations: QM Region, Conformation, and Boundary Condition. Demapan D, Kussmann J, Ochsenfeld C, Cui Q. J Chem Theory Comput 18 2530-2542 (2022)
  33. In Silico Neuroprotective Effects of Specific Rheum palmatum Metabolites on Parkinson's Disease Targets. Garcia PJB, Huang SK, De Castro-Cruz KA, Leron RB, Tsai PW. Int J Mol Sci 24 13929 (2023)
  34. In silico discovery and evaluation of phytochemicals binding mechanism against human catechol-O-methyltransferase as a putative bioenhancer of L-DOPA therapy in Parkinson disease. Rath SN, Jena L, Bhuyan R, Mahanandia NC, Patri M. Genomics Inform 19 e7 (2021)
  35. Inhibition of catechol-O-methyltransferase by natural pentacyclic triterpenes: structure-activity relationships and kinetic mechanism. Wang FY, Wei GL, Fan YF, Zhao DF, Wang P, Zou LW, Yang L. J Enzyme Inhib Med Chem 36 1079-1087 (2021)
  36. research-article Integrated multiplexed assays of variant effect reveal cis -regulatory determinants of catechol- O -methyltransferase gene expression. Hoskins I, Rao S, Tante C, Cenik C. bioRxiv 2023.08.02.551517 (2023)
  37. Nordihydroguaiaretic Acid as a Novel Substrate and Inhibitor of Catechol O-Methyltransferase Modulates 4-Hydroxyestradiol-Induced Cyto- and Genotoxicity in MCF-7 Cells. Kim JH, Lee J, Jeong H, Bang MS, Jeong JH, Chang M. Molecules 26 2060 (2021)


Reviews citing this publication (1)

  1. Pharmacogenetics and Pharmacotherapy of Military Personnel Suffering from Post-traumatic Stress Disorder. Naß J, Efferth T, Efferth T. Curr Neuropharmacol 15 831-860 (2017)

Articles citing this publication (32)

  1. Dynameomics: a comprehensive database of protein dynamics. van der Kamp MW, Schaeffer RD, Jonsson AL, Scouras AD, Simms AM, Toofanny RD, Benson NC, Anderson PC, Merkley ED, Rysavy S, Bromley D, Beck DA, Daggett V. Structure 18 423-435 (2010)
  2. Methyltransferases do not work by compression, cratic, or desolvation effects, but by electrostatic preorganization. Lameira J, Bora RP, Chu ZT, Warshel A. Proteins 83 318-330 (2015)
  3. Exploring the Dependence of QM/MM Calculations of Enzyme Catalysis on the Size of the QM Region. Jindal G, Warshel A. J Phys Chem B 120 9913-9921 (2016)
  4. Computation of the binding affinities of catechol-O-methyltransferase inhibitors: multisubstate relative free energy calculations. Palma PN, Bonifácio MJ, Loureiro AI, Soares-da-Silva P. J Comput Chem 33 970-986 (2012)
  5. Detoxication of structurally diverse polycyclic aromatic hydrocarbon (PAH) o-quinones by human recombinant catechol-O-methyltransferase (COMT) via O-methylation of PAH catechols. Zhang L, Jin Y, Chen M, Huang M, Harvey RG, Blair IA, Penning TM. J Biol Chem 286 25644-25654 (2011)
  6. Methylation of catechins and procyanidins by rat and human catechol-O-methyltransferase: metabolite profiling and molecular modeling studies. Weinert CH, Wiese S, Rawel HM, Esatbeyoglu T, Winterhalter P, Homann T, Kulling SE. Drug Metab Dispos 40 353-359 (2012)
  7. Catechol-O-methyltransferase in complex with substituted 3'-deoxyribose bisubstrate inhibitors. Ellermann M, Lerner C, Burgy G, Ehler A, Bissantz C, Jakob-Roetne R, Paulini R, Allemann O, Tissot H, Grünstein D, Stihle M, Diederich F, Rudolph MG. Acta Crystallogr D Biol Crystallogr 68 253-260 (2012)
  8. Hybrid dynamics simulation engine for metalloproteins. Sparta M, Shirvanyants D, Ding F, Dokholyan NV, Alexandrova AN. Biophys J 103 767-776 (2012)
  9. A new structural form in the SAM/metal-dependent o‑methyltransferase family: MycE from the mycinamicin biosynthetic pathway. Akey DL, Li S, Konwerski JR, Confer LA, Bernard SM, Anzai Y, Kato F, Sherman DH, Smith JL. J Mol Biol 413 438-450 (2011)
  10. Convergent Mechanistic Features between the Structurally Diverse N- and O-Methyltransferases: Glycine N-Methyltransferase and Catechol O-Methyltransferase. Zhang J, Klinman JP. J Am Chem Soc 138 9158-9165 (2016)
  11. In silico target fishing for the potential targets and molecular mechanisms of baicalein as an antiparkinsonian agent: discovery of the protective effects on NMDA receptor-mediated neurotoxicity. Gao L, Fang JS, Bai XY, Zhou D, Wang YT, Liu AL, Du GH. Chem Biol Drug Des 81 675-687 (2013)
  12. Molecular interaction studies of green tea catechins as multitarget drug candidates for the treatment of Parkinson's disease: computational and structural insights. Azam F, Mohamed N, Alhussen F. Network 26 97-115 (2015)
  13. Identification, characterization, and ontogenic study of a catechol O-methyltransferase from zebrafish. Alazizi A, Liu MY, Williams FE, Kurogi K, Sakakibara Y, Suiko M, Liu MC. Aquat Toxicol 102 18-23 (2011)
  14. Molecular architecture and structural basis of allosteric regulation of eukaryotic phosphofructokinases. Sträter N, Marek S, Kuettner EB, Kloos M, Keim A, Brüser A, Kirchberger J, Schöneberg T. FASEB J 25 89-98 (2011)
  15. Catechol-O-Methyltransferase and UDP-Glucuronosyltransferases in the Metabolism of Baicalein in Different Species. Zhang R, Cui Y, Wang Y, Tian X, Zheng L, Cong H, Wu B, Huo X, Wang C, Zhang B, Wang X, Yu Z. Eur J Drug Metab Pharmacokinet 42 981-992 (2017)
  16. A catalytic triad--Lys-Asn-Asp--Is essential for the catalysis of the methyl transfer in plant cation-dependent O-methyltransferases. Brandt W, Manke K, Vogt T. Phytochemistry 113 130-139 (2015)
  17. Biosynthesis of mycobacterial methylmannose polysaccharides requires a unique 1-O-methyltransferase specific for 3-O-methylated mannosides. Ripoll-Rozada J, Costa M, Manso JA, Maranha A, Miranda V, Sequeira A, Ventura MR, Macedo-Ribeiro S, Pereira PJB, Empadinhas N. Proc Natl Acad Sci U S A 116 835-844 (2019)
  18. In silico analyses of COMT, an important signaling cascade of dopaminergic neurotransmission pathway, for drug development of Parkinson's disease. Chakraborty C, Pal S, Doss CG, Wen ZH, Lin CS. Appl Biochem Biotechnol 167 845-860 (2012)
  19. News Low Barrier Hydrogen Bonds: Getting Close, but Not Sharing... Klinman JP. ACS Cent Sci 1 115-116 (2015)
  20. Structural and biochemical characterization of Rv0187, an O-methyltransferase from Mycobacterium tuberculosis. Lee S, Kang J, Kim J. Sci Rep 9 8059 (2019)
  21. Discovery and characterization of naturally occurring potent inhibitors of catechol-O-methyltransferase from herbal medicines. Zhao DF, Fan YF, Wang FY, Hou FB, Gonzalez FJ, Li SY, Wang P, Xia YL, Ge GB, Yang L. RSC Adv 11 10385-10392 (2021)
  22. Functional and structural characterization of a novel catechol-O-methyltransferase from Schizosaccharomyces pombe. Wang Q, Teng M, Li X. IUBMB Life 71 330-339 (2019)
  23. Multistructural microiteration technique for geometry optimization and reaction path calculation in large systems. Suzuki K, Morokuma K, Maeda S. J Comput Chem 38 2213-2221 (2017)
  24. Salicylate metal-binding isosteres as fragments for metalloenzyme inhibition. Jackl MK, Seo H, Karges J, Kalaj M, Cohen SM. Chem Sci 13 2128-2136 (2022)
  25. Letter The primary structure of COMT gene is not involved in the diet shift of the giant or the red pandas. Tang J, Kong F, Zeng B, Xu H, Yang J, Li Y. Gene 562 244-246 (2015)
  26. Transition-State Vibrational Analysis and Isotope Effects for COMT-Catalyzed Methyl Transfer. Roca M, Williams IH. J Am Chem Soc 142 15548-15559 (2020)
  27. Development of fed-batch profiles for efficient biosynthesis of catechol-O-methyltransferase. Espírito Santo GM, Pedro AQ, Oppolzer D, Bonifácio MJ, Queiroz JA, Silva F, Passarinha LA. Biotechnol Rep (Amst) 3 34-41 (2014)
  28. Enzymatic Fluoromethylation Enabled by the S-Adenosylmethionine Analog Te-Adenosyl-L-(fluoromethyl)homotellurocysteine. Neti SS, Wang B, Iwig DF, Onderko EL, Booker SJ. ACS Cent Sci 9 905-914 (2023)
  29. Ground- and excited-state stability of the conformers of 3,5-dinitrocatechol and its complexes with W(VI) and V(V): combined theoretical and experimental study. Delchev VB, Gavazov KB, Shterev IG. J Mol Model 20 2549 (2014)
  30. Identification and characterization of a catechol-o-methyltransferase cDNA in the catfish Heteropneustes fossilis: Tissue, sex and seasonal variations, and effects of gonadotropin and 2-hydroxyestradiol-17β on mRNA expression. Chaube R, Rawat A, Inbaraj RM, Bobe J, Guiguen Y, Fostier A, Joy KP. Gen Comp Endocrinol 246 129-141 (2017)
  31. Interaction of silver nanoparticles with catechol O-methyltransferase: Spectroscopic and simulation analyses. Usman A, Lobb K, Pletschke BI, Whiteley CG, Wilhelmi BS. Biochem Biophys Rep 26 101013 (2021)
  32. Thermofluor-Based Optimization Strategy for the Stabilization of Recombinant Human Soluble Catechol-O-Methyltransferase. Gonçalves AM, Pedro AQ, Oliveira DM, Oliveira AE, Santos MFA, Correia MAS, Queiroz JA, Gallardo E, Romão MJ, Passarinha LA. Int J Mol Sci 23 12298 (2022)


Quick links