Citations to this article
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
Total citations by year
Citations to this article in year 2024 (17)
| Title and authors | Publication | Year |
|---|---|---|
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Piezo1 agonist restores meningeal lymphatic vessels, drainage, and brain-CSF perfusion in craniosynostosis and aged mice
Matt Matrongolo, Phillip Ang, Junbing Wu, Aditya Jain, Josh Thackray, Akash Reddy, Young-Kwon Hong, Max Tischfield |
Journal of Clinical Investigation | 2024 |
|
The mechanosensory channel PIEZO1 functions upstream of Angiopoietin-TIE-FOXO1 signaling in lymphatic development
Jing Du, Pan Liu, Yalu Zhou, Phoebe Leeaw, Sol Misener, Benjamin Thomson, Jing Jin, Susan Quaggin |
Journal of Clinical Investigation | 2024 |
|
Yoda1 opens the lymphatic path for craniosynostosis therapy
Kari Alitalo |
Journal of Clinical Investigation | 2024 |
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The role of mechanically sensitive ion channel Piezo1 in bone remodeling.
Du Y, Xu B, Li Q, Peng C, Yang K |
Frontiers in Bioengineering and Biotechnology | 2024 |
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Developmental progression of lymphatic valve morphology and function.
Davis MJ, Zawieja SD, Yang Y |
Frontiers in Cell and Developmental Biology | 2024 |
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Piezo1 regulates meningeal lymphatic vessel drainage and alleviates excessive CSF accumulation.
Choi D, Park E, Choi J, Lu R, Yu JS, Kim C, Zhao L, Yu J, Nakashima B, Lee S, Singhal D, Scallan JP, Zhou B, Koh CJ, Lee E, Hong YK |
Nature Neuroscience | 2024 |
|
The Role of Inflammation in Lymphedema: A Narrative Review of Pathogenesis and Opportunities for Therapeutic Intervention.
Bowman C, Rockson SG |
International journal of molecular sciences | 2024 |
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Fluid-dynamic modeling of flow in embryonic tissue indicates that lymphatic valve location is not consistently determined by the local fluid shear or its gradient
Bertram CD, Macaskill C |
Microcirculation (New York, N.Y. : 1994) | 2024 |
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PIEZO1 targeting in macrophages boosts phagocytic activity and foam cell apoptosis in atherosclerosis.
Pourteymour S, Fan J, Majhi RK, Guo S, Sun X, Huang Z, Liu Y, Winter H, Bäcklund A, Skenteris NT, Chernogubova E, Werngren O, Li Z, Skogsberg J, Li Y, Matic L, Hedin U, Maegdefessel L, Ehrenborg E, Tian Y, Jin H |
Cellular and molecular life sciences : CMLS | 2024 |
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Lymphatic System Development and Function.
Janardhan HP, Wachter BT, Trivedi CM |
Current cardiology reports | 2024 |
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Alteration of Piezo1 signaling in type 2 diabetic mice: focus on endothelium and BK(Ca) channel.
Haam CE, Choi S, Byeon S, Oh EY, Choi SK, Lee YH |
Pflugers Archiv : European journal of physiology | 2024 |
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Mechanisms of mechanotransduction and physiological roles of PIEZO channels.
Xiao B |
Nature reviews. Molecular cell biology | 2024 |
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The mechanism and potential therapeutic target of piezo channels in pain
Xu Y, Wang Y, Mei S, Hu J, Wu L, Xu L, Bao L, Fang X |
Frontiers in Pain Research | 2024 |
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EPHB4-RASA1 Inhibition of PIEZO1 Ras Activation Drives Lymphatic Valvulogenesis.
Chen D, Tang Y, Lapinski PE, Wiggins D, Sevick EM, Davis MJ, King PD |
Circulation research | 2024 |
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Deformability of Heterogeneous Red Blood Cells in Aging and Related Pathologies.
Prudinnik DS, Kussanova A, Vorobjev IA, Tikhonov A, Ataullakhanov FI, Barteneva NS |
Aging and disease | 2024 |
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Blended Phenotypes From a SERPINA 11 Pathogenic Variant Over Underlying Immune Fetal Hydrops: A Rare Case Report and Literature Review
Beck MM, Luke ND, Anand RS, Navaneethan P, Athiyarath R, Danda S |
Maternal-Fetal Medicine | 2024 |
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Endothelial cell Piezo1 promotes vascular smooth muscle cell differentiation on large arteries
Abello J, Yin Y, Zhao Y, Maurer J, Lee J, Bodell C, Richee J, Clevenger AJ, Burton Z, Goeckel ME, Lin M, Grainger S, Halabi CM, Raghavan SA, Sah R, Stratman AN |
European journal of cell biology | 2024 |
