Molecular basis of P450 inhibition and activation: implications for drug development and drug therapy.

Three-dimensional homology models of cytochromes P450 (P450) 2B1 and P450 3A4 have been utilized along with site-directed mutagenesis to elucidate the molecular determinants of substrate specificity. Most of the key residues identified in 2B enzymes fall within five substrate recognition sites (SRSs) and have counterparts in bacterial P450 residues that regulate substrate binding or access. Docking of inhibitors into 2B models has provided a plausible explanation for changes in susceptibility to mechanism-based inactivation that accompany particular amino acid side-chain replacements. These studies provide a basis for predicting drug interactions due to P450 inhibition and for rational inhibitor design. In addition, the location of P450 3A4 residues capable of influencing homotropic stimulation by substrates and heterotropic stimulation by flavonoids has been identified. Steroid hydroxylation by the wild-type enzyme exhibits sigmoidal kinetics, indicative of positive cooperativity. Based on the 3A4 model and single-site mutants, a double mutant in SRS-2 has been constructed that exhibits normal Michaelis-Menten kinetics. Results of modeling and mutagenesis studies suggest that the substrate and effector bind at adjacent sites within a single large cavity in P450 3A4. A thorough understanding of the location and structural requirements of the substrate-binding and effector sites in cytochrome P450 3A4 should prove valuable in rationalizing and predicting interactions among the multitude of drugs and other compounds that bind to the enzyme.

[1]  J. Halpert,et al.  Analysis of human cytochrome P450 3A4 cooperativity: construction and characterization of a site-directed mutant that displays hyperbolic steroid hydroxylation kinetics. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[2]  J. Halpert,et al.  Probing the active site of cytochrome P450 2B1: metabolism of 7-alkoxycoumarins by the wild type and five site-directed mutants. , 1998, Biochemistry.

[3]  J. Liu,et al.  Analysis of four residues within substrate recognition site 4 of human cytochrome P450 3A4: role in steroid hydroxylase activity and alpha-naphthoflavone stimulation. , 1998, Archives of biochemistry and biophysics.

[4]  J. Halpert,et al.  Use of homology modeling in conjunction with site-directed mutagenesis for analysis of structure-function relationships of mammalian cytochromes P450. , 1997, Life sciences.

[5]  J. Halpert,et al.  Stoichiometry of 7‐ethoxycoumarin metabolism by cytochrome P450 2B1 wild‐type and five active‐site mutants , 1997, FEBS letters.

[6]  J. Halpert,et al.  Significance of glycine 478 in the metabolism of N-benzyl-1-aminobenzotriazole to reactive intermediates by cytochrome P450 2B1. , 1997, Biochemistry.

[7]  J. Halpert,et al.  Identification of three key residues in substrate recognition site 5 of human cytochrome P450 3A4 by cassette and site-directed mutagenesis. , 1997, Biochemistry.

[8]  Grazyna D. Szklarz,et al.  Molecular modeling of cytochrome P450 3A4 , 1997, J. Comput. Aided Mol. Des..

[9]  James R. Halpert,et al.  Alanine-scanning Mutagenesis of a Putative Substrate Recognition Site in Human Cytochrome P450 3A4 , 1997, The Journal of Biological Chemistry.

[10]  R. Ornstein,et al.  Binding free energy calculations for P450cam-substrate complexes. , 1996, Protein engineering.

[11]  D W Nebert,et al.  P450 superfamily: update on new sequences, gene mapping, accession numbers and nomenclature. , 1996, Pharmacogenetics.

[12]  R. Ornstein,et al.  Using molecular modeling and molecular dynamics simulation to predict P450 oxidation products. , 1996, Methods in enzymology.

[13]  J. Halpert,et al.  Site-directed mutagenesis as a tool for molecular modeling of cytochrome P450 2B1. , 1995, Biochemistry.

[14]  T. Poulos,et al.  Structure of cytochrome P450eryF involved in erythromycin biosynthesis , 1995, Nature Structural Biology.

[15]  Eric F. Johnson,et al.  Structures of Eukaryotic Cytochrome P450 Enzymes , 1995 .

[16]  R. Ornstein,et al.  Application of 3-dimensional homology modeling of cytochrome P450 2B1 for interpretation of site-directed mutagenesis results. , 1994, Journal of biomolecular structure & dynamics.

[17]  J Deisenhofer,et al.  Crystal structure and refinement of cytochrome P450terp at 2.3 A resolution. , 1994, Journal of molecular biology.

[18]  J Deisenhofer,et al.  Crystal structure of hemoprotein domain of P450BM-3, a prototype for microsomal P450's. , 1993, Science.

[19]  R. Ornstein,et al.  Controlling the regiospecificity and coupling of cytochrome P450cam: T185F mutant increases coupling and abolishes 3‐hydroxynorcamphor product , 1993, Protein science : a publication of the Protein Society.

[20]  Mark D. Paulsen,et al.  Predicting the product specificity and coupling of cytochrome P450cam , 1992, J. Comput. Aided Mol. Des..

[21]  O. Gotoh,et al.  Substrate recognition sites in cytochrome P450 family 2 (CYP2) proteins inferred from comparative analyses of amino acid and coding nucleotide sequences. , 1992, The Journal of biological chemistry.

[22]  S. Wrighton,et al.  The human hepatic cytochromes P450 involved in drug metabolism. , 1992, Critical reviews in toxicology.

[23]  R. Ornstein,et al.  A 175‐psec molecular dynamics simulation of camphor‐bound cytochrome P‐450cam , 1991, Proteins.

[24]  T. Poulos,et al.  High-resolution crystal structure of cytochrome P450cam. , 1987, Journal of molecular biology.

[25]  B C Finzel,et al.  The 2.6-A crystal structure of Pseudomonas putida cytochrome P-450. , 1985, The Journal of biological chemistry.