作者
Yuetong Wang,Jian Zhang,Shengxiang Ren,Dan Sun,Hsin‐Yi Huang,Hua Wang,Yujuan Jin,Fuming Li,Chao Zheng,Yang Liu,Lei Deng,Zhenfei Jiang,Tao Jiang,Xiuxin Han,Shenda Hou,Chenchen Guo,Fēi Li,Dong Gao,Jun Qin,Daming Gao,Luonan Chen,Shuhai Lin,Kwok‐Kin Wong,Li Cheng,Liang Hu,Caicun Zhou,Hongbin Ji
摘要
Drug resistance is a significant hindrance to effective cancer treatment. Although resistance mechanisms of epidermal growth factor receptor (EGFR) mutant cancer cells to lethal EGFR tyrosine kinase inhibitors (TKI) treatment have been investigated intensively, how cancer cells orchestrate adaptive response under sublethal drug challenge remains largely unknown. Here, we find that 2-h sublethal TKI treatment elicits a transient drug-tolerant state in EGFR mutant lung cancer cells. Continuous sublethal treatment reinforces this tolerance and eventually establishes long-term TKI resistance. This adaptive process involves H3K9 demethylation-mediated upregulation of branched-chain amino acid aminotransferase 1 (BCAT1) and subsequent metabolic reprogramming, which promotes TKI resistance through attenuating reactive oxygen species (ROS) accumulation. Combination treatment with TKI- and ROS-inducing reagents overcomes this drug resistance in preclinical mouse models. Clinical information analyses support the correlation of BCAT1 expression with the EGFR TKI response. Our findings reveal the importance of BCAT1-engaged metabolism reprogramming in TKI resistance in lung cancer.