异柠檬酸脱氢酶
癌症研究
生物
细胞生物学
IDH1
线粒体
突变
生物化学
基因
酶
作者
Duo Wang,Xiaoqi Zhu,Xiaobo Wang,Qin Wang,Kangning Yan,Guichun Zeng,Guanhua Qiu,Rong Jiao,Xia Lin,Jie Chen,Qiaoling Yang,Wen Qin,Junjie Liu,Kun Zhang,Yan Liu
标识
DOI:10.1002/adfm.202303869
摘要
Abstract Tumor adaptation‐originated tumor tolerance that compensatory mechanisms (e.g., isocitrate dehydrogenase (IDH) mutation) jointly shape is the dominant obstacle of ROS therapy. Currently, targeting a single pathway fails to fundamentally reverse the complex milieu and diminish tumor adaptation. Herein, a multichannel sonocatalysis amplifier is engineered via one‐pot gas diffusion method to attenuate IDH1‐mutated cholangiocarcinoma plasticity and tolerance to ROS therapy, wherein triptolide and IR780 are co‐loaded in DSPE‐mPEG‐modified CaCO 3 nanoparticles. Triptolide can blockade Nrf2 to cut off glutathione biosynthesis via blockading proteomic communication, and disrupt redox homeostasis to potentiate IR780‐mediated sonocatalytic ROS production. ROS‐induced mitochondria damages disrupt Ca 2+ homeostasis and in turn aggravate ROS accumulation, which cooperates with sonocatalysis and Nrf2 blockade to reprogram mitochondrial energy and substance metabolism (e.g., adenosine triphosphatase and glutathione), hinder DNA self‐repair, and impair IDH1‐mutation‐asired tolerance. Systematic experiments support that these actions in such multichannel sonocatalysis amplifiers indeed disrupt Ca 2+ /redox homeostasis to disarm robust tumor plasticity and IDH1‐mutation‐induced tolerance to sonocatalysis therapy against IDH1‐mutated cholangiocarcinoma progression. Briefly, the sonocatalysis amplifiers pave a comprehensive avenue to reprogram tumor metabolism, target tumor vulnerability, and attenuate tumor plasticity against genomic instability‐raised treatment adaptation.
科研通智能强力驱动
Strongly Powered by AbleSci AI
寻道图强
shinysparrow
sutharsons
YifanWang
浅尝离白
TrucCSC
随机子
Magali
70
穆紫
樱桃猴子
杳鸢
共享精神
sunny
jyy
大模型
积极慕梅
SciGPT
梁朝伟
misha991
皖公网安备34019202002308
