1t86 Citations

Crystal structure of the cytochrome p450cam mutant that exhibits the same spectral perturbations induced by putidaredoxin binding.

Nagano S, Tosha T, Ishimori K, Morishima I, Poulos TL
J Biol Chem 279 42844-9 (2004)
Related entries: 1t85, 1t87, 1t88

Cited: 34 times
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Abstract

The cytochrome P450cam active site is known to be perturbed by binding to its redox partner, putidaredoxin (Pdx). Pdx binding also enhances the camphor monooxygenation reaction (Nagano, S., Shimada, H., Tarumi, A., Hishiki, T., Kimata-Ariga, Y., Egawa, T., Suematsu, M., Park, S.-Y., Adachi, S., Shiro, Y., and Ishimura, Y. (2003) Biochemistry 42, 14507-14514). These effects are unique to Pdx because nonphysiological electron donors are unable to support camphor monooxygenation. The accompanying 1H NMR paper (Tosha, T., Yoshioka, S., Ishimori, K., and Morishima, I. (2004) J. Biol. Chem. 279, 42836-42843) shows that the conformation of active site residues, Thr-252 and Cys-357, and the substrate in the ferrous (Fe(II)) CO complex of the L358P mutant mimics that of the wild-type enzyme complexed to Pdx. To explore how these changes are transmitted from the Pdx-binding site to the active site, we have solved the crystal structures of the ferrous and ferrous-CO complex of wild-type and the L358P mutant. Comparison of these structures shows that the L358P mutation results in the movement of Arg-112, a residue known to be important for putidaredoxin binding, toward the heme. This change could optimize the Pdx-binding site leading to a higher affinity for Pdx. The mutation also pushes the heme toward the substrate and ligand binding pocket, which relocates the substrate to a position favorable for regio-selective hydroxylation. The camphor is held more firmly in place as indicated by a lower average temperature factor. Residues involved in the catalytically important proton shuttle system in the I helix are also altered by the mutation. Such conformational alterations and the enhanced reactivity of the mutant oxy complex with non-physiological electron donors suggest that Pdx binding optimizes the distal pocket for monooxygenation of camphor.

Reviews - 1t86 mentioned but not cited (1)

  1. Updating the Paradigm: Redox Partner Binding and Conformational Dynamics in Cytochromes P450. Poulos TL, Follmer AH. Acc Chem Res 55 373-380 (2022)

Articles - 1t86 mentioned but not cited (1)

  1. Species Identification of Bovine, Ovine and Porcine Type 1 Collagen; Comparing Peptide Mass Fingerprinting and LC-Based Proteomics Methods. Buckley M. Int J Mol Sci 17 445 (2016)


Reviews citing this publication (10)

  1. Heme enzyme structure and function. Poulos TL. Chem Rev 114 3919-3962 (2014)
  2. Conformational plasticity and structure/function relationships in cytochromes P450. Pochapsky TC, Kazanis S, Dang M. Antioxid Redox Signal 13 1273-1296 (2010)
  3. Navigating the Unnatural Reaction Space: Directed Evolution of Heme Proteins for Selective Carbene and Nitrene Transfer. Yang Y, Arnold FH. Acc Chem Res 54 1209-1225 (2021)
  4. Modeling kinetics of subcellular disposition of chemicals. Balaz S. Chem Rev 109 1793-1899 (2009)
  5. A novel type of allosteric regulation: functional cooperativity in monomeric proteins. Denisov IG, Sligar SG. Arch Biochem Biophys 519 91-102 (2012)
  6. Structural biology of heme monooxygenases. Poulos TL. Biochem Biophys Res Commun 338 337-345 (2005)
  7. Structural biology of redox partner interactions in P450cam monooxygenase: a fresh look at an old system. Sevrioukova IF, Poulos TL. Arch Biochem Biophys 507 66-74 (2011)
  8. Structural biology of p450-oxy complexes. Poulos TL. Drug Metab Rev 39 557-566 (2007)
  9. Fourier transform infrared spectroscopy as a tool to study structural properties of cytochromes P450 (CYPs). Jung C. Anal Bioanal Chem 392 1031-1058 (2008)
  10. Oxygen activation and redox partner binding in cytochromes P450. Poulos TL, Madrona Y. Biotechnol Appl Biochem 60 128-133 (2013)

Articles citing this publication (22)

  1. Structural basis for effector control and redox partner recognition in cytochrome P450. Tripathi S, Li H, Poulos TL. Science 340 1227-1230 (2013)
  2. P450cam visits an open conformation in the absence of substrate. Lee YT, Wilson RF, Rupniewski I, Goodin DB. Biochemistry 49 3412-3419 (2010)
  3. Putidaredoxin-to-cytochrome P450cam electron transfer: differences between the two reductive steps required for catalysis. Kuznetsov VY, Poulos TL, Sevrioukova IF. Biochemistry 45 11934-11944 (2006)
  4. Crystal structure of H2O2-dependent cytochrome P450SPalpha with its bound fatty acid substrate: insight into the regioselective hydroxylation of fatty acids at the alpha position. Fujishiro T, Shoji O, Nagano S, Sugimoto H, Shiro Y, Watanabe Y. J Biol Chem 286 29941-29950 (2011)
  5. L358P mutation on cytochrome P450cam simulates structural changes upon putidaredoxin binding: the structural changes trigger electron transfer to oxy-P450cam from electron donors. Tosha T, Yoshioka S, Ishimori K, Morishima I. J Biol Chem 279 42836-42843 (2004)
  6. Detection of a high-barrier conformational change in the active site of cytochrome P450cam upon binding of putidaredoxin. Wei JY, Pochapsky TC, Pochapsky SS. J Am Chem Soc 127 6974-6976 (2005)
  7. Double electron-electron resonance shows cytochrome P450cam undergoes a conformational change in solution upon binding substrate. Stoll S, Lee YT, Zhang M, Wilson RF, Britt RD, Goodin DB. Proc Natl Acad Sci U S A 109 12888-12893 (2012)
  8. Electron transfer between cytochrome P450cin and its FMN-containing redox partner, cindoxin. Kimmich N, Das A, Sevrioukova I, Meharenna Y, Sligar SG, Poulos TL. J Biol Chem 282 27006-27011 (2007)
  9. Structural and dynamic implications of an effector-induced backbone amide cis-trans isomerization in cytochrome P450cam. Asciutto EK, Madura JD, Pochapsky SS, OuYang B, Pochapsky TC. J Mol Biol 388 801-814 (2009)
  10. The conformation of P450cam in complex with putidaredoxin is dependent on oxidation state. Myers WK, Lee YT, Britt RD, Goodin DB. J Am Chem Soc 135 11732-11735 (2013)
  11. Specific effects of potassium ion binding on wild-type and L358P cytochrome P450cam. OuYang B, Pochapsky SS, Pagani GM, Pochapsky TC. Biochemistry 45 14379-14388 (2006)
  12. Ligand and Redox Partner Binding Generates a New Conformational State in Cytochrome P450cam (CYP101A1). Follmer AH, Tripathi S, Poulos TL. J Am Chem Soc 141 2678-2683 (2019)
  13. Crystal structures and functional characterization of wild-type CYP101D1 and its active site mutants. Batabyal D, Poulos TL. Biochemistry 52 8898-8906 (2013)
  14. Investigation of the low frequency dynamics of heme proteins: native and mutant cytochrome P450(cam) and redox partner complexes. Karunakaran V, Denisov I, Sligar SG, Champion PM. J Phys Chem B 115 5665-5677 (2011)
  15. Low-frequency dynamics of Caldariomyces fumago chloroperoxidase probed by femtosecond coherence spectroscopy. Gruia F, Ionascu D, Kubo M, Ye X, Dawson J, Osborne RL, Sligar SG, Denisov I, Das A, Poulos TL, Terner J, Champion PM. Biochemistry 47 5156-5167 (2008)
  16. Synergistic effects of mutations in cytochrome P450cam designed to mimic CYP101D1. Batabyal D, Li H, Poulos TL. Biochemistry 52 5396-5402 (2013)
  17. Combined QM/MM calculations of active-site vibrations in binding process of P450cam to putidaredoxin. Freindorf M, Shao Y, Kong J, Furlani TR. J Inorg Biochem 102 427-432 (2008)
  18. Conformational Change Induced by Putidaredoxin Binding to Ferrous CO-ligated Cytochrome P450cam Characterized by 2D IR Spectroscopy. Ramos S, Basom EJ, Thielges MC. Front Mol Biosci 5 94 (2018)
  19. Linkage between Proximal and Distal Movements of P450cam Induced by Putidaredoxin. Liou SH, Chuo SW, Qiu Y, Wang LP, Goodin DB. Biochemistry 59 2012-2021 (2020)
  20. An artificial electron donor supported catalytic cycle of Pseudomonas putida cytochrome P450cam. Prasad S, Murugan R, Mitra S. Biochem Biophys Res Commun 335 590-595 (2005)
  21. Active Site Hydrogen Bonding Induced in Cytochrome P450cam by Effector Putidaredoxin. Mammoser CC, Ramos S, Thielges MC. Biochemistry 60 1699-1707 (2021)
  22. Spectral features of the ferrous-CO complex in cytochrome P450: a revisit using TDDFT calculations. Hirao H, Xia S, Liu S. J Biol Inorg Chem 28 57-64 (2023)


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