部分
化学
催化作用
苯乙烯
残留物(化学)
单加氧酶
甲烷单加氧酶
突变
反应机理
立体化学
生物催化
烷基
饱和突变
有机化学
定点突变
活动站点
组合化学
酶
底物特异性
反应条件
机制(生物学)
催化效率
作者
Hui Lin (161703),Shengyuan Fang (17866130),Hang Gao (1457464),Zhangyuan Qin (17866133),Donglin Fan (13136055),Na Li (6550),Zhongliu Wu (17866136),Hongge Chen (306852)
出处
期刊:
[Figshare (United Kingdom)]
日期:2024-01-29
标识
DOI:10.1021/acscatal.3c06328.s001
摘要
Although styrene monooxygenases (SMOs) are widely used in the production of (S)- or (R)-enantiopure epoxides, the underlying enantiocontrol mechanism of SMO-catalyzed epoxidation remains elusive. Herein, we observed that the substrate-binding pose in the catalytic center, which was codetermined by the residues in the catalytic center and size of the alkyl moiety in the substrates, governed the enantioselectivity of the StyA-catalyzed epoxidation. The mutagenesis of the aromatic residue at site 73 into a nonaromatic residue or that of the nonaromatic residue at site 211 into aromatic residues resulted in the inversion of the enantioselectivity. The variants Y73V, V211F, V211Y, Y73V/V211F, and Y73V/V211Y of the (S)-selective StyA exhibited reversible enantioselectivity during the catalyzed epoxidation of 1-phenylcyclohexene derivatives, yielding the corresponding (R)-epoxides with high enantioselectivity (68–85% ee). Moreover, the (R)-selective variants catalyzed the olefins that harbored large hydrophobic groups, such as 1-phenylcyclohexene derivatives, into their corresponding (R)-epoxides with high enantioselectivity (up to >99% ee). However, these (R)-selective variants retained (S)-selectivity for the epoxidation of styrene, trans-β-methylstyrene, and trans-β-ethylstyrene. The elucidation of the enantiocontrolling mechanism of SMOs would thus be valuable for creating efficient styrene monooxygenases with different enantioselectivities.
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