1wl5 Citations

High resolution crystal structures of human cytosolic thiolase (CT): a comparison of the active sites of human CT, bacterial thiolase, and bacterial KAS I.

Kursula P, Sikkilä H, Fukao T, Kondo N, Wierenga RK
J Mol Biol 347 189-201 (2005)
Cited: 30 times
EuropePMC logo PMID: 15733928

Abstract

Thiolases belong to a superfamily of condensing enzymes that includes also beta-ketoacyl acyl carrier protein synthases (KAS enzymes), involved in fatty acid synthesis. Here, we describe the high resolution structure of human cytosolic acetoacetyl-CoA thiolase (CT), both unliganded (at 2.3 angstroms resolution) and in complex with CoA (at 1.6 angstroms resolution). CT catalyses the condensation of two molecules of acetyl-CoA to acetoacetyl-CoA, which is the first reaction of the metabolic pathway leading to the synthesis of cholesterol. CT is a homotetramer of exact 222 symmetry. There is an excess of positively charged residues at the interdimer surface leading towards the CoA-binding pocket, possibly important for the efficient capture of substrates. The geometry of the catalytic site, including the three catalytic residues Cys92, His 353, Cys383, and the two oxyanion holes, is highly conserved between the human and bacterial Zoogloea ramigera thiolase. In human CT, the first oxyanion hole is formed by Wat38 (stabilised by Asn321) and NE2(His353), and the second by N(Cys92) and N(Gly385). The active site of this superfamily is constructed on top of four active site loops, near Cys92, Asn321, His353, and Cys383, respectively. These loops were used for the superpositioning of CT on the bacterial thiolase and on the Escherichia coli KAS I. This comparison indicates that the two thiolase oxyanion holes also exist in KAS I at topologically equivalent positions. Interestingly, the hydrogen bonding interactions at the first oxyanion hole are different in thiolase and KAS I. In KAS I, the hydrogen bonding partners are two histidine NE2 atoms, instead of a water and a NE2 side-chain atom in thiolase. The second oxyanion hole is in both structures shaped by corresponding main chain peptide NH-groups. The possible importance of bound water molecules at the catalytic site of thiolase for the reaction mechanism is discussed.

Reviews - 1wl5 mentioned but not cited (1)

  1. A structural view of ligand-dependent activation in thermoTRP channels. Steinberg X, Lespay-Rebolledo C, Brauchi S. Front Physiol 5 171 (2014)

Articles - 1wl5 mentioned but not cited (2)

  1. Genetic profiling of the isoprenoid and sterol biosynthesis pathway genes of Trypanosoma cruzi. Cosentino RO, Agüero F. PLoS One 9 e96762 (2014)
  2. Aspergillus fumigatus Mitochondrial Acetyl Coenzyme A Acetyltransferase as an Antifungal Target. Zhang Y, Wei W, Fan J, Jin C, Lu L, Fang W. Appl Environ Microbiol 86 e02986-19 (2020)


Reviews citing this publication (1)

  1. The thiolase superfamily: condensing enzymes with diverse reaction specificities. Haapalainen AM, Meriläinen G, Wierenga RK. Trends Biochem Sci 31 64-71 (2006)

Articles citing this publication (26)

  1. Deciphering genetic factors that determine melon fruit-quality traits using RNA-Seq-based high-resolution QTL and eQTL mapping. Galpaz N, Gonda I, Shem-Tov D, Barad O, Tzuri G, Lev S, Fei Z, Xu Y, Mao L, Jiao C, Harel-Beja R, Doron-Faigenboim A, Tzfadia O, Bar E, Meir A, Sa'ar U, Fait A, Halperin E, Kenigswald M, Fallik E, Lombardi N, Kol G, Ronen G, Burger Y, Gur A, Tadmor Y, Portnoy V, Schaffer AA, Lewinsohn E, Giovannoni JJ, Katzir N. Plant J 94 169-191 (2018)
  2. A comprehensive machine-readable view of the mammalian cholesterol biosynthesis pathway. Mazein A, Watterson S, Hsieh WY, Griffiths WJ, Ghazal P. Biochem Pharmacol 86 56-66 (2013)
  3. Roles of the active site water, histidine 303, and phenylalanine 396 in the catalytic mechanism of the elongation condensing enzyme of Streptococcus pneumoniae. Zhang YM, Hurlbert J, White SW, Rock CO. J Biol Chem 281 17390-17399 (2006)
  4. FadA5 a thiolase from Mycobacterium tuberculosis: a steroid-binding pocket reveals the potential for drug development against tuberculosis. Schaefer CM, Lu R, Nesbitt NM, Schiebel J, Sampson NS, Kisker C. Structure 23 21-33 (2015)
  5. Redox-switch regulatory mechanism of thiolase from Clostridium acetobutylicum. Kim S, Jang YS, Ha SC, Ahn JW, Kim EJ, Lim JH, Cho C, Ryu YS, Lee SK, Lee SY, Kim KJ. Nat Commun 6 8410 (2015)
  6. Engineering Escherichia coli for high-yield geraniol production with biotransformation of geranyl acetate to geraniol under fed-batch culture. Liu W, Xu X, Zhang R, Cheng T, Cao Y, Li X, Guo J, Liu H, Xian M. Biotechnol Biofuels 9 58 (2016)
  7. A novel single-base substitution (c.1124A>G) that activates a 5-base upstream cryptic splice donor site within exon 11 in the human mitochondrial acetoacetyl-CoA thiolase gene. Fukao T, Boneh A, Aoki Y, Kondo N. Mol Genet Metab 94 417-421 (2008)
  8. The crystal structure of human mitochondrial 3-ketoacyl-CoA thiolase (T1): insight into the reaction mechanism of its thiolase and thioesterase activities. Kiema TR, Harijan RK, Strozyk M, Fukao T, Alexson SE, Wierenga RK. Acta Crystallogr D Biol Crystallogr 70 3212-3225 (2014)
  9. Crystal structures of SCP2-thiolases of Trypanosomatidae, human pathogens causing widespread tropical diseases: the importance for catalysis of the cysteine of the unique HDCF loop. Harijan RK, Kiema TR, Karjalainen MP, Janardan N, Murthy MR, Weiss MS, Michels PA, Wierenga RK. Biochem J 455 119-130 (2013)
  10. The crystal structure of a plant 3-ketoacyl-CoA thiolase reveals the potential for redox control of peroxisomal fatty acid beta-oxidation. Sundaramoorthy R, Micossi E, Alphey MS, Germain V, Bryce JH, Smith SM, Leonard GA, Hunter WN. J Mol Biol 359 347-357 (2006)
  11. Cloning, expression and purification of an acetoacetyl CoA thiolase from sunflower cotyledon. Dyer JH, Maina A, Gomez ID, Cadet M, Oeljeklaus S, Schiedel AC. Int J Biol Sci 5 736-744 (2009)
  12. SAHA Capture Compound--a novel tool for the profiling of histone deacetylases and the identification of additional vorinostat binders. Fischer JJ, Michaelis S, Schrey AK, Diehl A, Graebner OY, Ungewiss J, Horzowski S, Glinski M, Kroll F, Dreger M, Koester H. Proteomics 11 4096-4104 (2011)
  13. Kinetic and expression analyses of seven novel mutations in mitochondrial acetoacetyl-CoA thiolase (T2): identification of a Km mutant and an analysis of the mutational sites in the structure. Sakurai S, Fukao T, Haapalainen AM, Zhang G, Yamada K, Lilliu F, Yano S, Robinson P, Gibson MK, Wanders RJ, Mitchell GA, Wierenga RK, Kondo N. Mol Genet Metab 90 370-378 (2007)
  14. Ligand-induced domain rearrangement of fatty acid beta-oxidation multienzyme complex. Tsuchiya D, Shimizu N, Ishikawa M, Suzuki Y, Morikawa K. Structure 14 237-246 (2006)
  15. The SCP2-thiolase-like protein (SLP) of Trypanosoma brucei is an enzyme involved in lipid metabolism. Harijan RK, Mazet M, Kiema TR, Bouyssou G, Alexson SE, Bergmann U, Moreau P, Michels PA, Bringaud F, Wierenga RK. Proteins 84 1075-1096 (2016)
  16. Crystal structure of a monomeric thiolase-like protein type 1 (TLP1) from Mycobacterium smegmatis. Janardan N, Harijan RK, Wierenga RK, Murthy MR. PLoS One 7 e41894 (2012)
  17. Hepatic Acat2 overexpression promotes systemic cholesterol metabolism and adipose lipid metabolism in mice. Ma Z, Huang Z, Zhang C, Liu X, Zhang J, Shu H, Ma Y, Liu Z, Feng Y, Chen X, Kuang S, Zhang Y, Jia Z. Diabetologia 66 390-405 (2023)
  18. Highlighting Human Enzymes Active in Different Metabolic Pathways and Diseases: The Case Study of EC 1.2.3.1 and EC 2.3.1.9. Babbi G, Baldazzi D, Savojardo C, Martelli PL, Casadio R. Biomedicines 8 E250 (2020)
  19. Structural basis for differentiation between two classes of thiolase: Degradative vs biosynthetic thiolase. Bhaskar S, Steer DL, Anand R, Panjikar S. J Struct Biol X 4 100018 (2020)
  20. A Regulatory Cysteine Residue Mediates Reversible Inactivation of NAD+-Dependent Aldehyde Dehydrogenases to Promote Oxidative Stress Response. Zhang Y, Wang M, Lin H. ACS Chem Biol 15 28-32 (2020)
  21. Genome-wide identification and analysis of the thiolase family in insects. Fang SM. PeerJ 8 e10393 (2020)
  22. Structural characterization of a mitochondrial 3-ketoacyl-CoA (T1)-like thiolase from Mycobacterium smegmatis. Janardan N, Harijan RK, Kiema TR, Wierenga RK, Murthy MR. Acta Crystallogr D Biol Crystallogr 71 2479-2493 (2015)
  23. Characterization of primary structure and post-hatching increase in chicken cytosolic acetoacetyl-coA thiolase in the liver. Nakao N, Kaneda H, Tsushima N, Tanaka M. Poult Sci 95 1406-1410 (2016)
  24. Discovery of lipid-mediated protein-protein interactions in living cells using metabolic labeling with photoactivatable clickable probes. Fedoryshchak RO, Gorelik A, Shen M, Shchepinova MM, Pérez-Dorado I, Tate EW. Chem Sci 14 2419-2430 (2023)
  25. Enhanced mapping of small-molecule binding sites in cells. Wozniak JM, Li W, Governa P, Chen LY, Jadhav A, Dongre A, Forli S, Parker CG. Nat Chem Biol (2024)
  26. Transcriptome analysis of the effect of a novel human serine protease inhibitor SPINK13 on gene expression in MHCC97-H cells. Wei L, An T, An Y, He Z, Jia T, Li B, Lun Y. Transl Cancer Res 10 4464-4477 (2021)


Quick links