表观遗传学
化学
SIRT2
孟德尔随机化
H3K4me3
锡尔图因
药理学
转录组
生物信息学
生物
候选基因
清脆的
组蛋白
基因表达
细胞生物学
医学
西妥因1
癌症研究
体内
炎症
生物信息学
HEK 293细胞
白藜芦醇
DNA甲基化
基因
基因表达谱
表观遗传学
异源表达
计算生物学
作者
Xingling Chen,Qianqiang Zhao,Linhuang Chen,Shengrong Lin,Bin Mai,Xingling He,Xiaojiao Zhang,Jiahui Chen,Sijing Li,Ziru Li,Hua Zhang,Yuehui Zhou,Xiaofang Li,Huili Liao,Taochun Ye,Shuning Sun,Zhongqi Yang,Shihao Ni,Lu Lu
标识
DOI:10.1016/j.apsb.2026.02.006
摘要
TET2-mediated clonal hematopoiesis of indeterminate potential (CHIP) is a known cardiovascular risk factor, but its role in cardiac aging and potential for pharmacological intervention remain unclear. Herein, mendelian randomization using large-scale genome-wide association studies (GWAS) data assessed CHIP’s causal impact on aging and cardiovascular disease that revealed significant causal associations between TET2 -CHIP, CVD, and aging biomarkers. Transcriptome-guided screening identified oridonin as a candidate compound reversing CHIP- and aging-associated gene signatures. Multi-tiered target prediction combining chemical structure-based algorithms and transcriptomic correlation identified KDM5C as a key target, validated by enzymatic inhibition and surface plasmon resonance assays. In vivo and in vitro administration of oridonin significantly ameliorated cardiac dysfunction and pathological remodeling in the CHIP model. Epigenetic regulation was profiled via ChIP-seq and RNA-seq, focusing on H3K4me3-mediated transcription. Tet2 +/– -BMT mice exhibited age-progressive myocardial fibrosis, inflammation, senescence, and functional decline. Mechanistically, oridonin inhibited KDM5C histone demethylase, restored H3K4me3 levels, and activated the SIRT2 anti-aging pathway. Rescue experiments using gene overexpression and recombinant protein supplementation confirmed the functional role of the KDM5C–H3K4me3–SIRT2–S100A8 axis in mediating oridonin’s effects. Overall, TET2 -driven CHIP promotes cardiac aging, as evidenced by human genetic analyses and long-term BMT models. Oridonin, by inhibiting KDM5C and restoring H3K4me3-dependent SIRT2 signaling, mitigates CHIP–induced myocardial aging. Oridonin mitigates clonal hematopoiesis-driven cardiac aging by inhibiting KDM5C, restoring H3K4me3, and suppressing SASP signaling, highlighting a novel epigenetic therapeutic strategy
科研通智能强力驱动
Strongly Powered by AbleSci AI