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CYP158A2 中 Ile87 残基在氧化偶联反应中的作用。

The role of Ile87 of CYP158A2 in oxidative coupling reaction.

机构信息

Department of Biochemistry, Vanderbilt University School of Medicine, Nashville, TN 37232-0146, USA.

出版信息

Arch Biochem Biophys. 2012 Feb 15;518(2):127-32. doi: 10.1016/j.abb.2011.12.007. Epub 2011 Dec 19.

DOI:10.1016/j.abb.2011.12.007
PMID:22203090
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3274592/
Abstract

Both CYP158A1 and CYP158A2 are able to catalyze an oxidative C-C coupling reaction producing biflaviolin or triflaviolin in Streptomyces coelicolor A3(2). The substrate-bound crystal structures of CYP158A2 and CYP158A1 reveal that the side chain of Ile87 in CYP158A2 points to the active site contacting the distal flaviolin molecule, however, the bulkier side chain of Lys90 in CYP158A1 (corresponding to Ile87 in CYP158A2) is toward the distal surface of the protein. These results suggest that these residues could be important in determining product regiospecificity. In order to explore the role of the two residues in catalysis, the reciprocal mutants, Ile87Lys and Lys90Ile, of CYP158A2 and CYP158A1, respectively, were generated and characterized. The mutant Ile87Lys enzyme forms two isomers of biflaviolin instead of three isomers of biflaviolin in wild-type CYP158A2. CYP158A1 containing the substitution of lysine with isoleucine has the same catalytic activity compared with the wild-type CYP158A1. The crystal structure of Ile87Lys showed that the BC loop in the mutant is in a very different orientation compared with the BC loop in both CYP158A1/A2 structures. These results shed light on the mechanism of the oxidative coupling reaction catalyzed by cytochrome P450.

摘要

CYP158A1 和 CYP158A2 均可催化氧化 C-C 偶联反应,在变铅青链霉菌 A3(2)中产生双黄酮醇或三黄酮醇。CYP158A2 和 CYP158A1 的底物结合晶体结构表明,CYP158A2 中 Ile87 的侧链指向与远端黄酮醇分子接触的活性位点,然而 CYP158A1 中较大侧链的 Lys90(对应于 CYP158A2 中的 Ile87)朝向蛋白质的远端表面。这些结果表明这些残基可能在决定产物区域特异性方面很重要。为了探索这两个残基在催化中的作用,分别生成并表征了 CYP158A2 和 CYP158A1 的相应突变体 Ile87Lys 和 Lys90Ile。突变体 Ile87Lys 酶形成两种双黄酮醇异构体而不是野生型 CYP158A2 中的三种双黄酮醇异构体。与野生型 CYP158A1 相比,含有赖氨酸取代为异亮氨酸的 CYP158A1 具有相同的催化活性。Ile87Lys 的晶体结构表明,突变体中的 BC 环与 CYP158A1/A2 结构中的 BC 环相比处于非常不同的取向。这些结果阐明了细胞色素 P450 催化的氧化偶联反应的机制。

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