311 related articles for article (PubMed ID: 20211593)
1. Redox properties of heme peroxidases.
Battistuzzi G; Bellei M; Bortolotti CA; Sola M
Arch Biochem Biophys; 2010 Aug; 500(1):21-36. PubMed ID: 20211593
[TBL] [Abstract][Full Text] [Related]
2. The dynamic role of distal side residues in heme hydroperoxidase catalysis. Interplay between X-ray crystallography and ab initio MD simulations.
Vidossich P; Alfonso-Prieto M; Carpena X; Fita I; Loewen PC; Rovira C
Arch Biochem Biophys; 2010 Aug; 500(1):37-44. PubMed ID: 20447375
[TBL] [Abstract][Full Text] [Related]
3. A catalytic approach to estimate the redox potential of heme-peroxidases.
Ayala M; Roman R; Vazquez-Duhalt R
Biochem Biophys Res Commun; 2007 Jun; 357(3):804-8. PubMed ID: 17442271
[TBL] [Abstract][Full Text] [Related]
4. Protein-based radicals in the catalase-peroxidase of synechocystis PCC6803: a multifrequency EPR investigation of wild-type and variants on the environment of the heme active site.
Ivancich A; Jakopitsch C; Auer M; Un S; Obinger C
J Am Chem Soc; 2003 Nov; 125(46):14093-102. PubMed ID: 14611246
[TBL] [Abstract][Full Text] [Related]
5. Versatile peroxidase oxidation of high redox potential aromatic compounds: site-directed mutagenesis, spectroscopic and crystallographic investigation of three long-range electron transfer pathways.
Pérez-Boada M; Ruiz-Dueñas FJ; Pogni R; Basosi R; Choinowski T; Martínez MJ; Piontek K; Martínez AT
J Mol Biol; 2005 Nov; 354(2):385-402. PubMed ID: 16246366
[TBL] [Abstract][Full Text] [Related]
6. Redox thermodynamics of the ferric-ferrous couple of wild-type synechocystis KatG and KatG(Y249F).
Bellei M; Jakopitsch C; Battistuzzi G; Sola M; Obinger C
Biochemistry; 2006 Apr; 45(15):4768-74. PubMed ID: 16605245
[TBL] [Abstract][Full Text] [Related]
7. Two alternative substrate paths for compound I formation and reduction in catalase-peroxidase KatG from Burkholderia pseudomallei.
Deemagarn T; Wiseman B; Carpena X; Ivancich A; Fita I; Loewen PC
Proteins; 2007 Jan; 66(1):219-28. PubMed ID: 17063492
[TBL] [Abstract][Full Text] [Related]
8. Improving the oxidative stability of a high redox potential fungal peroxidase by rational design.
Sáez-Jiménez V; Acebes S; Guallar V; Martínez AT; Ruiz-Dueñas FJ
PLoS One; 2015; 10(4):e0124750. PubMed ID: 25923713
[TBL] [Abstract][Full Text] [Related]
9. EPR and ENDOR studies of cryoreduced compounds II of peroxidases and myoglobin. Proton-coupled electron transfer and protonation status of ferryl hemes.
Davydov R; Osborne RL; Kim SH; Dawson JH; Hoffman BM
Biochemistry; 2008 May; 47(18):5147-55. PubMed ID: 18407661
[TBL] [Abstract][Full Text] [Related]
10. Redox thermodynamics of lactoperoxidase and eosinophil peroxidase.
Battistuzzi G; Bellei M; Vlasits J; Banerjee S; Furtmüller PG; Sola M; Obinger C
Arch Biochem Biophys; 2010 Feb; 494(1):72-7. PubMed ID: 19944669
[TBL] [Abstract][Full Text] [Related]
11. New and classic families of secreted fungal heme peroxidases.
Hofrichter M; Ullrich R; Pecyna MJ; Liers C; Lundell T
Appl Microbiol Biotechnol; 2010 Jul; 87(3):871-97. PubMed ID: 20495915
[TBL] [Abstract][Full Text] [Related]
12. Disruption of the H-bond network in the main access channel of catalase-peroxidase modulates enthalpy and entropy of Fe(III) reduction.
Vlasits J; Bellei M; Jakopitsch C; De Rienzo F; Furtmüller PG; Zamocky M; Sola M; Battistuzzi G; Obinger C
J Inorg Biochem; 2010 Jun; 104(6):648-56. PubMed ID: 20347488
[TBL] [Abstract][Full Text] [Related]
13. Comparison of the binding and reactivity of plant and mammalian peroxidases to indole derivatives by computational docking.
Hallingbäck HR; Gabdoulline RR; Wade RC
Biochemistry; 2006 Mar; 45(9):2940-50. PubMed ID: 16503648
[TBL] [Abstract][Full Text] [Related]
14. Distal site aspartate is essential in the catalase activity of catalase-peroxidases.
Jakopitsch C; Auer M; Regelsberger G; Jantschko W; Furtmüller PG; Rüker F; Obinger C
Biochemistry; 2003 May; 42(18):5292-300. PubMed ID: 12731870
[TBL] [Abstract][Full Text] [Related]
15. Oxygen activation and electron transfer in flavocytochrome P450 BM3.
Ost TW; Clark J; Mowat CG; Miles CS; Walkinshaw MD; Reid GA; Chapman SK; Daff S
J Am Chem Soc; 2003 Dec; 125(49):15010-20. PubMed ID: 14653735
[TBL] [Abstract][Full Text] [Related]
16. Structure and action mechanism of ligninolytic enzymes.
Wong DW
Appl Biochem Biotechnol; 2009 May; 157(2):174-209. PubMed ID: 18581264
[TBL] [Abstract][Full Text] [Related]
17. Compound ES of dehaloperoxidase decays via two alternative pathways depending on the conformation of the distal histidine.
Thompson MK; Franzen S; Ghiladi RA; Reeder BJ; Svistunenko DA
J Am Chem Soc; 2010 Dec; 132(49):17501-10. PubMed ID: 21090708
[TBL] [Abstract][Full Text] [Related]
18. Role of Tyr residues on the protein surface of cationic cell-wall-peroxidase (CWPO-C) from poplar: potential oxidation sites for oxidative polymerization of lignin.
Sasaki S; Nonaka D; Wariishi H; Tsutsumi Y; Kondo R
Phytochemistry; 2008 Jan; 69(2):348-55. PubMed ID: 17910963
[TBL] [Abstract][Full Text] [Related]
19. The reaction mechanism of plant peroxidases.
Longu S; Medda R; Padiglia A; Pedersen JZ; Floris G
Ital J Biochem; 2004 Mar; 53(1):41-5. PubMed ID: 15356961
[TBL] [Abstract][Full Text] [Related]
20. The redox properties of ascorbate peroxidase.
Efimov I; Papadopoulou ND; McLean KJ; Badyal SK; Macdonald IK; Munro AW; Moody PC; Raven EL
Biochemistry; 2007 Jul; 46(27):8017-23. PubMed ID: 17580972
[TBL] [Abstract][Full Text] [Related]
[Next] [New Search]
