期刊
NATURE COMMUNICATIONS
卷 12, 期 1, 页码 -出版社
NATURE RESEARCH
DOI: 10.1038/s41467-021-22602-5
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资金
- National Institutes of Health [R01 EB024322, R01 CA254342, R01 CA247562, R21 EB028491]
- National Science Foundation Graduate Research Fellowship [DGE-1148903]
- NSF Science and Technology Center for Engineering Mechanobiology
The coupling of traction force and FAK signaling coordinates cell migration and tissue-scale forces to promote microtissue repair. This process relies on actomyosin contractility, talin-FAK binding, and vinculin to convert forces into FAK signaling events regulating cell migration and tissue repair.
How adhesive forces are transduced and integrated into biochemical signals at focal adhesions (FAs) is poorly understood. Using cells adhering to deformable micropillar arrays, we demonstrate that traction force and FAK localization as well as traction force and Y397-FAK phosphorylation are linearly coupled at individual FAs on stiff, but not soft, substrates. Similarly, FAK phosphorylation increases linearly with external forces applied to FAs using magnetic beads. This mechanosignaling coupling requires actomyosin contractility, talin-FAK binding, and full-length vinculin that binds talin and actin. Using an in vitro 3D biomimetic wound healing model, we show that force-FAK signaling coupling coordinates cell migration and tissue-scale forces to promote microtissue repair. A simple kinetic binding model of talin-FAK interactions under force can recapitulate the experimental observations. This study provides insights on how talin and vinculin convert forces into FAK signaling events regulating cell migration and tissue repair. How adhesive forces are transduced and integrated into biochemical signals at focal adhesions (FAs) is poorly understood. Here authors show that force- FAK signaling coupling coordinates cell migration and tissue-scale forces to promote microtissue repair.
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