机械转化
光学镊子
钙
氧化还原
化学
生物物理学
信号蛋白
钙信号传导
纳米技术
材料科学
信号转导
细胞生物学
生物化学
物理
生物
光学
无机化学
有机化学
作者
Yuyao Li,Haodong Li,Yawen Zheng,Dadi Xu,Liu Liu,Ao Liu,Tianning Li,Dai‐Wen Pang,Hong‐Wu Tang
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-04-15
卷期号:19 (16): 16084-16095
被引量:2
标识
DOI:10.1021/acsnano.5c03122
摘要
Endothelial cells (ECs) regulate vascular function by converting mechanical forces into biochemical signals; however, the molecular mechanisms of pN-scale mechanotransduction remain elusive. Here, we develop an optical tweezer-integrated confocal microscopy system that allows precise, noninvasive manipulation of the cell membrane localization with mechanical stimuli within the 0–100 pN range while monitoring Ca2+-mediated NO/ROS redox signaling in situ in single ECs under varying force parameters. We show that pN-scale mechanical stimulation regulates extracellular Ca2+ influx, triggering downstream production of NO and ROS, which subsequently affects intracellular redox homeostasis. Key mechanosensitive ion channels (e.g., Piezo1 and TRPV4) and cytoskeletal components (e.g., F-actin) facilitate force-induced redox signaling. We further delineate the roles of membrane tension-dominant versus hybrid tension-tether models in mechanotransduction, revealing their differential engagement in force transmission pathways. This mechanistic framework establishes direct connections between pN-scale mechanical input characteristics and redox-regulated vascular homeostasis.
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