拉明
衰老
DNA损伤
早衰
氧化应激
细胞生物学
早熟
表型
生物
肌萎缩
细胞
核板
细胞周期
细胞衰老
心肌肥大
自噬
老化
DNA修复
癌症研究
端粒
心肌细胞
肌肉肥大
细胞周期检查点
化学
细胞老化
氧化损伤
突变
成纤维细胞
机制(生物学)
疾病
作者
Stephanie E. Schneider,Adrienne K. Scott,Katie M. Gallagher,Emily Y. Miller,Soham Ghosh,Corey P. Neu
标识
DOI:10.1002/advs.202513314
摘要
The cardiovascular system functions under continuous cyclic mechanical stretch, with disruptions in mechanical and biochemical signals contributing to disease progression. In cardiovascular disorders, these disruptions activate cardiac fibroblasts (CFs) and promote cellular senescence, yet it remains unclear whether mechanical stimuli alone can initiate this phenotype. Here, primary murine CFs are exposed to uniaxial stretch, and systematically varied mechanical parameters assessed their role in senescence induction. Loss of stretch magnitude and increase in frequency, mimicking a pathologic hypertrophy and fibrosis, led to a senescence phenotype, identified through cell cycle arrest, decreased lamin B expression, and DNA damage. Mechanically-induced CF senescence depends on p53/p21, whereas senescence triggered by oxidative stress or lamin A/C mutation proceeded via p16. Notably, mechanically-induced premature senescence is accompanied by reduced levels of the nuclear envelope protein emerin. These findings demonstrate that altered mechanical signals are sufficient to trigger premature senescence and implicate compromised nuclear integrity in the underlying mechanism.
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