化学
辅因子
单加氧酶
催化作用
蛋白质工程
氧化还原酶
立体化学
组合化学
酶
细胞色素P450
生物化学
作者
Xiangquan Qin,Yiping Jiang,Fuquan Yao,Jie Chen,Fanhui Kong,Panxia Zhao,Long Yi Jin,Zhiqi Cong
标识
DOI:10.1002/anie.202311259
摘要
Abstract A recent novel strategy for constructing artificial metalloenzymes (ArMs) that target new‐to‐nature functions uses dual‐functional small molecules (DFSMs) with catalytic and anchoring groups for converting P450BM3 monooxygenase into a peroxygenase. However, this process requires excess DFSMs (1000 equivalent of P450) owing to their low binding affinity for P450, thus severely limiting its practical application. Herein, structural optimization of the DFSM‐anchoring group considerably enhanced their binding affinity by three orders of magnitude ( K d ≈10 −8 M), thus approximating native cofactors, such as FMN or FAD in flavoenzymes. An artificial cofactor‐driven peroxygenase was thus constructed. The co‐crystal structure of P450BM3 bound to a DFSM clearly revealed a precatalytic state in which the DFSM participates in H 2 O 2 activation, thus facilitating peroxygenase activity. Moreover, the increased binding affinity substantially decreases the DFSM load to as low as 2 equivalents of P450, while maintaining increased activity. Furthermore, replacement of catalytic groups showed disparate selectivity and activity for various substrates. This study provides an unprecedented approach for assembling ArMs by binding editable organic cofactors as a co‐catalytic center, thereby increasing the catalytic promiscuity of P450 enzymes.
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