Piezo1 incorporates mechanical force signals into the genetic program that governs lymphatic valve development and maintenance
Dongwon Choi, … , Il-Taeg Cho, Young-Kwon Hong
Dongwon Choi, … , Il-Taeg Cho, Young-Kwon Hong
Published January 24, 2019
Citation Information: JCI Insight. 2019;4(5):e125068. https://doi.org/10.1172/jci.insight.125068.
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Research Article Vascular biology

Piezo1 incorporates mechanical force signals into the genetic program that governs lymphatic valve development and maintenance

Abstract

The lymphatic system plays crucial roles in tissue homeostasis, lipid absorption, and immune cell trafficking. Although lymphatic valves ensure unidirectional lymph flows, the flow itself controls lymphatic valve formation. Here, we demonstrate that a mechanically activated ion channel Piezo1 senses oscillating shear stress (OSS) and incorporates the signal into the genetic program controlling lymphatic valve development and maintenance. Time-controlled deletion of Piezo1 using a pan-endothelial Cre driver (Cdh5[PAC]-CreERT2) or lymphatic-specific Cre driver (Prox1-CreERT2) equally inhibited lymphatic valve formation in newborn mice. Furthermore, Piezo1 deletion in adult lymphatics caused substantial lymphatic valve degeneration. Piezo1 knockdown in cultured lymphatic endothelial cells (LECs) largely abrogated the OSS-induced upregulation of the lymphatic valve signature genes. Conversely, ectopic Piezo1 overexpression upregulated the lymphatic valve genes in the absence of OSS. Remarkably, activation of Piezo1 using chemical agonist Yoda1 not only accelerated lymphatic valve formation in animals, but also triggered upregulation of some lymphatic valve genes in cultured LECs without exposure to OSS. In summary, our studies together demonstrate that Piezo1 is the force sensor in the mechanotransduction pathway controlling lymphatic valve development and maintenance, and Piezo1 activation is a potentially novel therapeutic strategy for congenital and surgery-associated lymphedema.

Authors

Dongwon Choi, Eunkyung Park, Eunson Jung, Boksik Cha, Somin Lee, James Yu, Paul M. Kim, Sunju Lee, Yeo Jin Hong, Chester J. Koh, Chang-Won Cho, Yifan Wu, Noo Li Jeon, Alex K. Wong, Laura Shin, S. Ram Kumar, Ivan Bermejo-Moreno, R. Sathish Srinivasan, Il-Taeg Cho, Young-Kwon Hong

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Figure 4

Piezo1 is required for the OSS-induced upregulation of lymphatic valve genes.

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Piezo1 is required for the OSS-induced upregulation of lymphatic valve g...
(A and B) Primary human LECs exposed to OSS for 24 hours became cuboidal shapes. (A) Immunofluorescence staining for F-actin and (B) a box-and-whisker plot showing the ratio of length/width of the cells. (C and D) OSS upregulated FOXC2, GATA2, CX37, LAMA5, and ITGA9 in LECs, based on (C) Western blot analyses and (D) quantitative PCR (qPCR). The box plots depict the minimum and maximum values (whiskers), the upper and lower quartiles, and the median. The length of the box represents the interquartile range. (E and F) Piezo1 knockdown prevented the OSS-mediated upregulation of lymphatic valve genes. Piezo1 expression in primary LECs was inhibited by Piezo1 siRNA (siPiezo1), or not inhibited by control siRNA (siCTR), for 24 hours. Cells were then exposed to OSS for (E) 4 hours or (F) 24 hours before (E) qPCR data assay or (F) Western blot analysis, respectively. OSS with approximately at 6 dyne/cm2 maximum was applied directly onto the cells by reversing the flow at 0.5 Hz (peak). **P < 0.01; ***P < 0.001; unpaired, 2-tailed t test compared with the static culture.