羟基化
化学
突变
二面角
产量(工程)
突变体
立体化学
合理设计
分子动力学
催化循环
生物物理学
血红素
催化作用
生物化学
蛋白质工程
氧原子
同源重组
氢键
组合化学
突变
蛋白质结构
定向进化
氧气
选择性
作者
Xia Ke,Kai-Rui Wang,Tong Zheng,Y. Jun Xu,Ji-Dong Shen,Junping Zhou,Zhi-Qiang Liu,Yu-Guo Zheng
标识
DOI:10.1021/acs.jafc.5c17087
摘要
Fungal unspecific peroxygenases (UPOs) can directly utilize H2O2 as an oxygen and electron donor for selective C–H bond oxyfunctionalization. However, long-time duration of genetic modification and expression in Pichia pastoris limited its quick evolution. Herein, we propose a novel structure-guided combinatorial evolution strategy(SBPCS) to accelerate the iterative cycle of multipoint mutagenesis for C25 hydroxylation of VD3 by AaeUPO. Through mutational screening of key residues within the substrate-binding pocket, combined with molecular dynamics (MD) simulations, we observed shortened distance and a stabilized dihedral angle between the substrate’s C25 atom and the heme Fe═O center. After two rounds of coevolution, a triple mutant (G195A/V244I/S272A, M3) was successfully obtained, demonstrating a 5.16-fold increase in C25-hydroxylation efficiency, with a increased the yield of 25(OH)VD3 from 45.8 to 354.40 mg/L. Our study elucidate how the geometry of the heme-VD3 complex effect catalytic efficiency during selective hydroxylation and guided a rational design for accelerating AaeUPO coevolution toward VD3 C25-hydroxylation.
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