生物正交化学
化学
原细胞
生物物理学
细胞生物学
羟基化
光敏剂
表观遗传学
合成生物学
5-羟甲基胞嘧啶
组蛋白
生物化学
哈卡特
线粒体
纳米技术
细胞器
细胞模型
甲基化
HEK 293细胞
过氧化氢
细胞信号
体外
亚细胞定位
作者
Qiaoling Che,Ru He,Yixin Zhang,Haipeng Zhang,Kaixing Zeng,Yiyun Chen
标识
DOI:10.1002/anie.202515137
摘要
Abstract Artificial photoenzymes hold transformative potential for in vitro biocatalysis, but their translation to live‐cell environments demands minimal cellular perturbation and aerobic compatibility. Here, we present miniSOG, a 12 kDa miniature photoenzyme that enables bioorthogonal deboronative hydroxylation via superoxide radical anion (O 2 •− ) generation under blue light irradiation. Leveraging the inherent photochemistry of flavins, miniSOG facilitates the photoactivation of 27 structurally diverse organoboronates—including aryl/alkyl boronates, fluorophores, anticancer agents, and epigenetic modulators—through a unified O 2 •− ‐mediated mechanism. This system achieves spatiotemporally precise photocatalysis in live cells, where miniSOG's compact size and subcellular targeting enable organelle‐specific localization and confined reactivity due to short‐range O 2 •− diffusion (∼0.2 µm). We demonstrate its utility in light‐gated cellular modulation: i) mitochondrial depolarization via localized release of 2,4‐dinitrophenol (DNP) to disrupt energy metabolism, and ii) nuclear m 6 A methylation enhancement to epigenetically upregulate autophagy. By repurposing miniSOG's photochemistry for bioorthogonal deboronative hydroxylation, this work establishes a versatile, genetically encoded platform for manipulating fundamental cellular pathways with minimal off‐target effects.
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