化学
重编程
电子转移
活性氧
氧化磷酸化
线粒体
催化作用
生物物理学
代谢途径
密度泛函理论
生物化学
新陈代谢
细胞生物学
电子传输链
氧化还原
电子结构
代谢工程
铁蛋白
氧化损伤
氧气
作者
W.K. Wu,Houqi Zhou,Muxin Zhang,Xi Zhang,Mengjiao Huang,Siyu Tao,Wei Du,Shuang Wang,Jiayi Zhao,Xiang Zhou,Nanxin Liu,Tao Chen
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-02-27
卷期号:20 (10): 8548-8569
被引量:1
标识
DOI:10.1021/acsnano.5c20192
摘要
In this study, single-cell RNA sequencing (scRNA-seq) analysis revealed that both reactive oxygen species (ROS) and excessive lactate accumulation play critical roles in sustaining the local chronic inflammatory microenvironment. Guided by these insights, we developed a phosphorus-doped single-atom iron nanozyme (Fe@CN-P) designed to overcome the long-standing challenge of achieving lactate oxidation with metal-based nanozymes. Phosphorus, acting as a stronger electron donor, effectively increases the electron density at the iron active center, thereby enhancing its proton-capture capacity. In Fe@CN-P, the downward shift of the Fe d-band center, coupled with the increased density of electronic states near the Fermi level, lowers the energy barrier for proton transfer in the rate-determining step, ultimately enabling the efficient conversion of lactate into pyruvate. Notably, the dual functions of lactate oxidation and ROS scavenging restore mitochondrial activity and establish a "reversal-reutilization" metabolic pathway. Our findings demonstrate that phosphorus-induced electronic redistribution at the iron center enables efficient catalytic lactate "reversal-reutilization," thereby driving metabolic reprogramming and epigenetic remodeling to regulate inflammation. This work illustrates how atomic-level electronic structure engineering can be integrated with biological metabolic processes, providing insights and theoretical foundations for the design of single-atom nanozymes with both precise electronic modulation and therapeutic functionality.
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