Multiple mutagenesis of P450 isoflavonoid synthase reveals a key active-site residue

被引:26
|
作者
Sawada, Y [1 ]
Ayabe, SI [1 ]
机构
[1] Nihon Univ, Dept Appl Biol Sci, Fujisawa, Kanagawa 2528510, Japan
来源
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS | 2005年 / 330卷 / 03期
基金
日本学术振兴会;
关键词
cytochrome P450; site-directed inutagenesis; homology modeling; isoflavonoid biosynthesis; leguminosae; thermal stability; molecular evolution;
D O I
10.1016/j.bbrc.2005.03.053
中图分类号
Q5 [生物化学]; Q7 [分子生物学];
学科分类号
071010 ; 081704 ;
摘要
The leguminous isollavonoid skeleton is constructed by P450 2-hydroxyisoflavanone synthase (CYP93C). Two active-site residues of CYP93C2, Ser 310 and Lys 375, are critical for unusual aryl migration of the flavanone substrate. Leu 371 is located near the substrate in a homology model, and mutant proteins regarding this residue were expressed in recombinant yeast microsomes. The single mutant, L371V, yielded only inactive P420, but multiple mutants incorporating K375T restored the P450 fold: the S310T-L371V-K375T triple mutant showed four times higher P450 level than the wild type. L371V-K375T and S310T-L371V-K375T produced a mixture of major 3 beta-hydroxyflavanone and minor flavone, and 100% flavone, respectively, from a flavanone. Thus, Len 371 appeared to control the substrate accommodation in favor of hydrogen abstraction from C-3 of the flavanone molecule and contribute to the P450 fold under the presence of Lys 375, the residue responsible for aryl migration. The molecular evolution of CYP93 enzymes is discussed. (c) 2005 Elsevier Inc. All rights reserved.
引用
收藏
页码:907 / 913
页数:7
相关论文
共 50 条
  • [31] STRUCTURAL ASPECTS OF ACTIVE-SITE OF CYTOCHROME P-450CAM
    LIPSCOMB, JD
    GUNSALUS, IC
    DRUG METABOLISM AND DISPOSITION, 1973, 1 (01) : 1 - 5
  • [32] ACTIVE-SITE MODEL OF CYTOCHROME-P-450-LM2
    SCHWARZE, W
    JAEGER, J
    JANIG, GR
    RUCKPAUL, K
    BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS, 1988, 150 (03) : 996 - 1005
  • [33] CYTOCHROMES-P450 - THEIR ACTIVE-SITE STRUCTURE AND MECHANISM OF OXIDATION
    KOYMANS, L
    DENKELDER, GMDO
    TE, JMK
    VERMEULEN, NPE
    DRUG METABOLISM REVIEWS, 1993, 25 (03) : 325 - 387
  • [34] THE SEQUENCE HOMOLOGIES OF CYTOCHROMES-P-450 AND ACTIVE-SITE GEOMETRIES
    LEWIS, DFV
    MOEREELS, H
    JOURNAL OF COMPUTER-AIDED MOLECULAR DESIGN, 1992, 6 (03) : 235 - 252
  • [35] MOLECULAR ORGANIZATION OF ACTIVE-SITE OF MICROSOMAL CYTOCHROME-P-450
    RAIKHMAN, LM
    ANNAEV, B
    BELOVA, VS
    BORUKAEVA, MR
    MOLEKULYARNAYA BIOLOGIYA, 1973, 7 (03): : 399 - 409
  • [36] FLUOROMETRIC STUDIES ON THE ACTIVE-SITE CONFORMATION OF CYTOCHROME-P450
    OMATA, Y
    FRIEDMAN, FK
    BIOPHYSICAL JOURNAL, 1990, 57 (02) : A230 - A230
  • [37] ACTIVE-SITE MAPPING OF VARIOUS CYTOCHROMES-P450 ISOZYMES
    DONNEOPDEN, KGM
    KOYMANS, LMH
    VERMEULEN, NPE
    EUROPEAN JOURNAL OF PHARMACOLOGY, 1990, 183 (02) : 181 - 181
  • [38] ACCESSIBILITY AND DYNAMICS OF THE ACTIVE-SITE IN BACTERIAL CYTOCHROME-P-450
    JUNG, C
    MARLOW, F
    RISTAU, O
    FALSETT, S
    GUNSALUS, IC
    FRAUENFELDER, H
    CYTOCHROME P-450 : BIOCHEMISTRY AND BIOPHYSICS /, 1989, : 280 - 283
  • [39] A RUTHENIUM OCTAETHYLPORPHYRIN ANALOG OF THE CYTOCHROME-P-450 ACTIVE-SITE
    PAULSON, DR
    HWANG, DS
    INORGANICA CHIMICA ACTA-BIOINORGANIC CHEMISTRY, 1983, 80 (05): : L59 - L60
  • [40] ACTIVE-SITE DYNAMICS OF TOLUENE HYDROXYLATION BY CYTOCHROME-P-450
    HANZLIK, RP
    LING, KHJ
    JOURNAL OF ORGANIC CHEMISTRY, 1990, 55 (13): : 3992 - 3997
12345