化学
线粒体
谷胱甘肽
活性氧
细胞生物学
平衡
生物化学
催化作用
基因沉默
氧化还原
调解人
癌症研究
谷胱甘肽代谢
胞浆
氧化磷酸化
小RNA
酶
生物物理学
癌症
新陈代谢
癌细胞
生物
信号转导
自噬
作者
Y. Zhang,Shuangshuang Yang,Qin Xiang,Jinkun Huang,Yongfeng Tan,Xiang Peng,Youming Feng,Ran Chang,Jinze Li,Yaru Cheng,Xuan Wang,Zhuangqiang Gao,Haifeng Dong
标识
DOI:10.1002/anie.202520859
摘要
Although nanozyme-mediated disruption of mitochondrial homeostasis holds significant therapeutic potential, precise spatiotemporal regulation using single-function catalysts remains a major challenge. To overcome this limitation, we developed a triphenylphosphine-functionalized Pd@PtIr nanozyme by epitaxially depositing a Pt-Ir (1:1) alloy shell onto Pd nanocube cores with atomic-level precision. This rationally engineered metal-center architecture generates a synergistic catalytic interface that not only enhances peroxidase-like activity-validated by density functional theory (DFT)-but also endows the nanozyme with intrinsic NADH oxidase and glutathione peroxidase-like functionalities within a single platform. Upon 808 nm near-infrared (NIR) irradiation, the nanozyme triggers a cascade of enzyme-mimetic redox reactions that jointly deplete mitochondrial glutathione (GSH) and elevate reactive oxygen species (ROS) levels, while NADH oxidation concurrently disrupts ATP biosynthesis. These concerted effects synergistically impair mitochondrial redox homeostasis and energy metabolism in tumor cells. To further potentiate therapeutic efficacy, we combined the nanozyme with antisense oligonucleotide-mediated silencing of ASncmtRNA, resulting in a pronounced 89.1% tumor regression in an orthotopic breast cancer model. This integrated approach-combining atomic-precision catalyst design, multifunctional enzymatic activity, and gene-silencing therapy-presents a transformative paradigm for organelle-targeted precision nanotherapeutics in oncology.
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