1ggh Citations

Substrate flow in catalases deduced from the crystal structures of active site variants of HPII from Escherichia coli.

Melik-Adamyan W, Bravo J, Carpena X, Switala J, Maté MJ, Fita I, Loewen PC
Proteins 44 270-81 (2001)
Related entries: 1gg9, 1gge, 1ggf, 1ggj, 1ggk

Cited: 27 times
EuropePMC logo PMID: 11455600

Abstract

The active site of heme catalases is buried deep inside a structurally highly conserved homotetramer. Channels leading to the active site have been identified as potential routes for substrate flow and product release, although evidence in support of this model is limited. To investigate further the role of protein structure and molecular channels in catalysis, the crystal structures of four active site variants of catalase HPII from Escherichia coli (His128Ala, His128Asn, Asn201Ala, and Asn201His) have been determined at approximately 2.0-A resolution. The solvent organization shows major rearrangements with respect to native HPII, not only in the vicinity of the replaced residues but also in the main molecular channel leading to the heme distal pocket. In the two inactive His128 variants, continuous chains of hydrogen bonded water molecules extend from the molecular surface to the heme distal pocket filling the main channel. The differences in continuity of solvent molecules between the native and variant structures illustrate how sensitive the solvent matrix is to subtle changes in structure. It is hypothesized that the slightly larger H(2)O(2) passing through the channel of the native enzyme will promote the formation of a continuous chain of solvent and peroxide. The structure of the His128Asn variant complexed with hydrogen peroxide has also been determined at 2.3-A resolution, revealing the existence of hydrogen peroxide binding sites both in the heme distal pocket and in the main channel. Unexpectedly, the largest changes in protein structure resulting from peroxide binding are clustered on the heme proximal side and mainly involve residues in only two subunits, leading to a departure from the 222-point group symmetry of the native enzyme. An active role for channels in the selective flow of substrates through the catalase molecule is proposed as an integral feature of the catalytic mechanism. The Asn201His variant of HPII was found to contain unoxidized heme b in combination with the proximal side His-Tyr bond suggesting that the mechanistic pathways of the two reactions can be uncoupled.

Articles - 1ggh mentioned but not cited (1)

  1. An NMR study on the interaction of Escherichia coli DinI with RecA-ssDNA complexes. Yoshimasu M, Aihara H, Ito Y, Rajesh S, Ishibe S, Mikawa T, Yokoyama S, Shibata T. Nucleic Acids Res 31 1735-1743 (2003)


Reviews citing this publication (3)

  1. Thirty years of heme catalases structural biology. Díaz A, Loewen PC, Fita I, Carpena X. Arch Biochem Biophys 525 102-110 (2012)
  2. Enzyme Tunnels and Gates As Relevant Targets in Drug Design. Marques SM, Daniel L, Buryska T, Prokop Z, Brezovsky J, Damborsky J. Med Res Rev 37 1095-1139 (2017)
  3. Monofunctional Heme-Catalases. Hansberg W. Antioxidants (Basel) 11 2173 (2022)

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  1. A complexomic study of Escherichia coli using two-dimensional blue native/SDS polyacrylamide gel electrophoresis. Lasserre JP, Beyne E, Pyndiah S, Lapaillerie D, Claverol S, Bonneu M. Electrophoresis 27 3306-3321 (2006)
  2. Letter An engineered enzyme that targets circulating lactate to alleviate intracellular NADH:NAD+ imbalance. Patgiri A, Skinner OS, Miyazaki Y, Schleifer G, Marutani E, Shah H, Sharma R, Goodman RP, To TL, Robert Bao X, Ichinose F, Zapol WM, Mootha VK. Nat Biotechnol 38 309-313 (2020)
  3. Unusual Cys-Tyr covalent bond in a large catalase. Díaz A, Horjales E, Rudiño-Piñera E, Arreola R, Hansberg W. J Mol Biol 342 971-985 (2004)
  4. Structural analysis of urate oxidase in complex with its natural substrate inhibited by cyanide: mechanistic implications. Gabison L, Prangé T, Colloc'h N, El Hajji M, Castro B, Chiadmi M. BMC Struct Biol 8 32 (2008)
  5. The quest for a functional substrate access tunnel in FeFe hydrogenase. Lautier T, Ezanno P, Baffert C, Fourmond V, Cournac L, Fontecilla-Camps JC, Soucaille P, Bertrand P, Meynial-Salles I, Léger C. Faraday Discuss 148 385-407; discussion 421-41 (2011)
  6. Structure-function relationships in fungal large-subunit catalases. Díaz A, Valdés VJ, Rudiño-Piñera E, Horjales E, Hansberg W. J Mol Biol 386 218-232 (2009)
  7. Binding of chrysoidine to catalase: spectroscopy, isothermal titration calorimetry and molecular docking studies. Yang B, Hao F, Li J, Chen D, Liu R. J Photochem Photobiol B 128 35-42 (2013)
  8. Catalase from the white shrimp Penaeus (Litopenaeus) vannamei: molecular cloning and protein detection. Tavares-Sánchez OL, Gómez-Anduro GA, Felipe-Ortega X, Islas-Osuna MA, Sotelo-Mundo RR, Barillas-Mury C, Yepiz-Plascencia G. Comp Biochem Physiol B Biochem Mol Biol 138 331-337 (2004)
  9. Hydrogen peroxide decomposition by a non-heme iron(III) catalase mimic: a DFT study. Sicking W, Korth HG, Jansen G, de Groot H, Sustmann R. Chemistry 13 4230-4245 (2007)
  10. High-resolution structure and biochemical properties of a recombinant Proteus mirabilis catalase depleted in iron. Andreoletti P, Sainz G, Jaquinod M, Gagnon J, Jouve HM. Proteins 50 261-271 (2003)
  11. Crystal structures and calorimetry reveal catalytically relevant binding mode of coproporphyrin and coproheme in coproporphyrin ferrochelatase. Hofbauer S, Helm J, Obinger C, Djinović-Carugo K, Furtmüller PG. FEBS J 287 2779-2796 (2020)
  12. Discovery of catalases in members of the Chlamydiales order. Rusconi B, Greub G. J Bacteriol 195 3543-3551 (2013)
  13. Influence of main channel structure on H(2)O(2) access to the heme cavity of catalase KatE of Escherichia coli. Jha V, Chelikani P, Carpena X, Fita I, Loewen PC. Arch Biochem Biophys 526 54-59 (2012)
  14. Comparison of native and recombinant chlorite dismutase from Ideonella dechloratans. Danielsson Thorell H, Beyer NH, Heegaard NH, Ohman M, Nilsson T. Eur J Biochem 271 3539-3546 (2004)
  15. How catalase recognizes H₂O₂ in a sea of water. Domínguez L, Sosa-Peinado A, Hansberg W. Proteins 82 45-56 (2014)
  16. Structure of the monofunctional heme catalase DR1998 from Deinococcus radiodurans. Borges PT, Frazão C, Miranda CS, Carrondo MA, Romão CV. FEBS J 281 4138-4150 (2014)
  17. Post-transcriptional regulator Hfq binds catalase HPII: crystal structure of the complex. Yonekura K, Watanabe M, Kageyama Y, Hirata K, Yamamoto M, Maki-Yonekura S. PLoS One 8 e78216 (2013)
  18. Structure, recombinant expression and mutagenesis studies of the catalase with oxidase activity from Scytalidium thermophilum. Yuzugullu Y, Trinh CH, Smith MA, Pearson AR, Phillips SE, Sutay Kocabas D, Bakir U, Ogel ZB, McPherson MJ. Acta Crystallogr D Biol Crystallogr 69 398-408 (2013)
  19. Catalase-Based Modified Graphite Electrode for Hydrogen Peroxide Detection in Different Beverages. Fusco G, Bollella P, Mazzei F, Favero G, Antiochia R, Tortolini C. J Anal Methods Chem 2016 8174913 (2016)
  20. Structural features of peroxisomal catalase from the yeast Hansenula polymorpha. Peña-Soler E, Vega MC, Wilmanns M, Williams C. Acta Crystallogr D Biol Crystallogr 67 690-698 (2011)
  21. Mutation of Phe413 to Tyr in catalase KatE from Escherichia coli leads to side chain damage and main chain cleavage. Jha V, Donald LJ, Loewen PC. Arch Biochem Biophys 525 207-214 (2012)
  22. Structural analysis of NADPH depleted bovine liver catalase and its inhibitor complexes. Sugadev R, Ponnuswamy MN, Sekar K. Int J Biochem Mol Biol 2 67-77 (2011)
  23. The oxygenase-peroxidase theory of Bach and Chodat and its modern equivalents: change and permanence in scientific thinking as shown by our understanding of the roles of water, peroxide, and oxygen in the functioning of redox enzymes. Nicholls P. Biochemistry (Mosc) 72 1039-1046 (2007)


Related citations provided by authors (2)

  1. Crystal Structure of Catalase HPII from Escherichia coli. Bravo J, Verdaguer N, Tormo J, Betzel C, Switala J, Loewen PC, Fita I Structure 3 491-502 (1995)
  2. Structure of Catalase Hpii from Escherichia Coli at 1.9 A Resolution. Bravo J, Mate MJ, Schneider T, Switala J, Wilson K, Loewen PC, Fita I Proteins 34 155-166 (1999)

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