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Protein kinase C and calcineurin cooperatively mediate cell survival under compressive mechanical stress.


ABSTRACT: Cells experience compressive stress while growing in limited space or migrating through narrow constrictions. To survive such stress, cells reprogram their intracellular organization to acquire appropriate mechanical properties. However, the mechanosensors and downstream signaling networks mediating these changes remain largely unknown. Here, we have established a microfluidic platform to specifically trigger compressive stress, and to quantitatively monitor single-cell responses of budding yeast in situ. We found that yeast senses compressive stress via the cell surface protein Mid2 and the calcium channel proteins Mid1 and Cch1, which then activate the Pkc1/Mpk1 MAP kinase pathway and calcium signaling, respectively. Genetic analysis revealed that these pathways work in parallel to mediate cell survival. Mid2 contains a short intracellular tail and a serine-threonine-rich extracellular domain with spring-like properties, and both domains are required for mechanosignaling. Mid2-dependent spatial activation of the Pkc1/Mpk1 pathway depolarizes the actin cytoskeleton in budding or shmooing cells, thereby antagonizing polarized growth to protect cells under compressive stress conditions. Together, these results identify a conserved signaling network responding to compressive mechanical stress, which, in higher eukaryotes, may ensure cell survival in confined environments.

SUBMITTER: Mishra R 

PROVIDER: S-EPMC5754771 | biostudies-literature | 2017 Dec

REPOSITORIES: biostudies-literature

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Protein kinase C and calcineurin cooperatively mediate cell survival under compressive mechanical stress.

Mishra Ranjan R   van Drogen Frank F   Dechant Reinhard R   Oh Soojung S   Jeon Noo Li NL   Lee Sung Sik SS   Peter Matthias M  

Proceedings of the National Academy of Sciences of the United States of America 20171201 51


Cells experience compressive stress while growing in limited space or migrating through narrow constrictions. To survive such stress, cells reprogram their intracellular organization to acquire appropriate mechanical properties. However, the mechanosensors and downstream signaling networks mediating these changes remain largely unknown. Here, we have established a microfluidic platform to specifically trigger compressive stress, and to quantitatively monitor single-cell responses of budding yeas  ...[more]

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