1gei Citations

Structural characterization of n-butyl-isocyanide complexes of cytochromes P450nor and P450cam.

Lee DS, Park SY, Yamane K, Obayashi E, Hori H, Shiro Y
Biochemistry 40 2669-77 (2001)
Related entries: 1gej, 1gek, 1gem

Cited: 14 times
EuropePMC logo PMID: 11258878

Abstract

Alkyl-isocyanides are able to bind to both ferric and ferrous iron of the heme in cytochrome P450, and the resulting complexes exhibit characteristic optical absorption spectra. While the ferric complex gives a single Soret band at 430 nm, the ferrous complex shows double Soret bands at 430 and 450 nm. The ratio of intensities of the double Soret bands in the ferrous isocyanide complex of P450 varies, as a function of pH, ionic strength, and the origin of the enzyme. To understand the structural origin of these characteristic spectral features, we examined the crystallographic and spectrophotometric properties of the isocyanide complexes of Pseudomonas putida cytochrome P450cam and Fusarium oxysporum cytochorme P450nor, since ferrous isocyanide complex of P450cam gives a single Soret band at 453 nm, while that of P450nor gives one at 427 nm. Corresponding to the optical spectra, we observed C-N stretching of a ferrous iron-bound isocyanide at 2145 and 2116 cm(-1) for P450nor and P450cam, respectively. The crystal structures of the ferric and ferrous n-butyl isocyanide complexes of P450cam and P450nor were determined. The coordination structure of the fifth Cys thiolate was indistinguishable for the two P450s, but the coordination geometry of the isocyanide was different for the case of P450cam [d(Fe-C) = 1.86 A, angleFe-C-N = 159 degrees ] versus P450nor [d(Fe-C) = 1.85 A, angleFe-C-N = 175 degrees ]. Another difference in the structures was the chemical environment of the heme pocket. In the case of P450cam, the iron-bound isocyanide is surrounded by some hydrophobic side chains, while, for P450nor, it is surrounded by polar groups including several water molecules. On the basis of these observations, we proposed that the steric factors and/or the polarity of the environment surrounding the iron-bound isocyanide significantly effect on the resonance structure of the heme(Fe)-isocyanide moiety and that differences in these two factors are responsible for the spectral characteristics for P450s.

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  1. How does the reductase help to regulate the catalytic cycle of cytochrome P450 3A4 using the conserved water channel? Fishelovitch D, Shaik S, Wolfson HJ, Nussinov R. J Phys Chem B 114 5964-5970 (2010)
  2. Selective steroidogenic cytochrome P450 haem iron ligation by steroid-derived isonitriles. Richard AM, Wong NR, Harris K, Sundar R, Scott EE, Pochapsky TC. Commun Chem 6 183 (2023)


Articles citing this publication (12)

  1. Crystal structures of [Fe]-hydrogenase in complex with inhibitory isocyanides: implications for the H2-activation site. Tamura H, Salomone-Stagni M, Fujishiro T, Warkentin E, Meyer-Klaucke W, Ermler U, Shima S. Angew Chem Int Ed Engl 52 9656-9659 (2013)
  2. Straight-chain alkyl isocyanides open the distal histidine gate in crystal structures of myoglobin . Smith RD, Blouin GC, Johnson KA, Phillips GN, Olson JS. Biochemistry 49 4977-4986 (2010)
  3. n-Butyl isocyanide oxidation at the [NiFe4S4OH(x)] cluster of CO dehydrogenase. Jeoung JH, Dobbek H. J Biol Inorg Chem 17 167-173 (2012)
  4. Cooperativity of cytochrome P450 1A2: interactions of 1,4-phenylene diisocyanide and 1-isopropoxy-4-nitrobenzene. Isin EM, Sohl CD, Eoff RL, Guengerich FP. Arch Biochem Biophys 473 69-75 (2008)
  5. Reactivities of organic phase biosensors: 6. Square-wave and differential pulse studies of genetically engineered cytochrome P450(cam) (CYP101) bioelectrodes in selected solvents. Iwuoha EI, Smyth MR. Biosens Bioelectron 18 237-244 (2003)
  6. The stretching frequencies of bound alkyl isocyanides indicate two distinct ligand orientations within the distal pocket of myoglobin. Blouin GC, Olson JS. Biochemistry 49 4968-4976 (2010)
  7. 13C-Methyl isocyanide as an NMR probe for cytochrome P450 active sites. McCullough CR, Pullela PK, Im SC, Waskell L, Sem DS. J Biomol NMR 43 171-178 (2009)
  8. An isocyanide probe for heme electronic structure: bis(tert-butylisocyanide) complex of diazaporphyrin showing a unique (dxy)2(dxz, dyz)3 ground state. Ohgo Y, Neya S, Uekusa H, Nakamura M. Chem Commun (Camb) 4590-4592 (2006)
  9. Spectroscopic investigation of isonitrile complexes of ferric and ferrous microperoxidase 8. Ricoux R, Lecomte S, Policar C, Boucher JL, Mahy JP. J Inorg Biochem 99 1165-1173 (2005)
  10. Unusual electronic structure of bis-isocyanide complexes of iron(III) porphyrinoids. Ohgo Y, Neya S, Hashizume D, Ozeki T, Nakamura M. Dalton Trans 41 3126-3129 (2012)
  11. Synthesis and crystal structure of bis-(tert-butyl isocyanide-κC)[5,10,15,20-tetra-kis-(4-chloro-phen-yl)porphyrinato-κ4N]iron(II). Nasri S. Acta Crystallogr E Crystallogr Commun 79 931-935 (2023)
  12. The synthesis, characterization, and application of ¹³C-methyl isocyanide as an NMR probe of heme protein active sites. McCullough C, Pullela PK, Im SC, Waskell L, Sem D. Methods Mol Biol 987 51-59 (2013)


Related citations provided by authors (1)

  1. Crystal structure of nitric oxide reductase from denitrifing fungus Fusarium oxysporum. Park S-Y, Shimizu H, Adachi S, Nakagawa A, Tanaka I, Nakahara K, Shoun H, Obayashi E, Nakamura H, Iizuka T, Shiro Y Nat. Struct. Biol. 4 827-832 (1997)

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