Artificial metalloenzyme assembly in cellular compartments for enhanced catalysis

IF 12.9 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Nature chemical biology Pub Date : 2025-01-08 DOI:10.1038/s41589-024-01819-7

Tong Wu, Xianhui Chen, Yating Fei, Guopu Huang, Yingjiao Deng, Yingjie Wang, Anming Yang, Zhiyong Chen, N. Gabriel Lemcoff, Xinxin Feng, Yugang Bai

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Abstract

Artificial metalloenzymes (ArMs) integrated within whole cells have emerged as promising catalysts; however, their sensitivity to metal centers remains a systematic challenge, resulting in diminished activity and turnover. Here we address this issue by inducing in cellulo liquid–liquid phase separation through a self-labeling fusion protein, HaloTag–SNAPTag. This strategy creates membraneless, isolated liquid condensates within Escherichia coli as protective compartments for the assembly of ArMs using the same fusion protein. The approach allows for high ArM loading and stabilization by localizing the ArMs within the phase-separated regions. Consequently, the performance of ArM-based whole-cell catalysts is improved, with a demonstrated turnover per cell of up to 7.1 × 10⁹ for the olefin metathesis reaction. Furthermore, we apply this to an engineered E. coli system in live mice, where host bacterial cells confine the metal catalytic species, and in a mouse colorectal cancer model, where ArM-containing whole-cell catalysts mediate concurrent reactions to activate prodrugs.

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用于增强催化作用的细胞室人工金属酶组装

整合在全细胞内的人工金属酶（arm）已成为一种很有前景的催化剂；然而，它们对金属中心的敏感性仍然是一个系统性的挑战，导致活动和周转减少。在这里，我们通过一种自标记融合蛋白HaloTag-SNAPTag在纤维素液-液相分离中诱导解决了这个问题。这种策略在大肠杆菌中产生无膜、分离的液体冷凝物，作为使用相同融合蛋白组装ArMs的保护隔室。该方法通过将ArM定位在相分离区域内，实现了高ArM负载和稳定性。因此，基于arm的全细胞催化剂的性能得到了改善，每个细胞的周转率高达7.1 × 109，用于烯烃转化反应。此外，我们将其应用于活小鼠的工程大肠杆菌系统，其中宿主细菌细胞限制金属催化物种，以及小鼠结肠直肠癌模型，其中含有arm的全细胞催化剂介导同步反应以激活前药。

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来源期刊

Nature chemical biology 生物-生化与分子生物学

CiteScore

23.90

自引率

1.40%

发文量

238

审稿时长

12 months

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