Myosin-II mediated traction forces evoke localized Piezo1-dependent Ca2+ flickers

Ellefsen, Kyle L.; Holt, Jesse R.; Chang, Alice C.; Nourse, Jamie P.; Arulmoli, Janahan; Mekhdjian, Armen H.; Abuwarda, Hamid; Tombola, Francesco; Flanagan, Lisa A.; Dunn, Alexander R.; Parker, Ian; Pathak, Madhu A.

doi:10.1038/s42003-019-0514-3

Cited by 165 publications

(242 citation statements)

References 77 publications

(112 reference statements)

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“…Biophysical studies have shown that membrane bilayer tension changes can directly activate Piezo1 ion channels and the regulation of Piezo1's function has been attributed to the regulation of localized lipid bilayer tension changes 12,13 . This is supported by biophysical studies that Piezo1 is sensitive to specific lipid types 14 and the observations that Piezo1 is diffusively localized in plasma membranes of many cell lines with very few interaction partners identified 4,13,15,16 . However, an open question In the regulation of Piezo1 is the intimate involvement of the integrin-linked actin cytoskeleton in Piezo1's functions 17 .…”

Section: Introductionmentioning

confidence: 60%

“…Since the discovery of Piezo1's role as a mechanosensitive ion channel in eukaryotic cells, the regulation mechanism of Piezo1's function in the various physiological activities of cells has been under heavy investigation 8,9 . The current model of Piezo1's physiological function assumes that it is diffusive in the plasma membrane and is activated locally through membrane bilayer tension or curvature changes that occur through cytoskeletal-dependent mechanical events 13,15,17,40,42 . In these studies, we find that the involvement of Piezo1 in cell spreading on fibronectin is lost with cell transformation and also with spreading on collagen.…”

Section: Discussionmentioning

confidence: 99%

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Force-dependent recruitment of Piezo1 drives adhesion maturation and calcium entry in normal but not tumor cells

Yao

Tijore

Cox

et al. 2020

Preprint

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Piezo1 is a mechanosensitive Ca 2+ -permeable channel that has been implicated in a number of mechanosensing processes. It is diffusive on plasma membranes and activated by local membrane tension changes yet recent data suggest that Piezo1 activity is tightly coupled to the integrin-mediated actin cytoskeleton through a poorly understood mechanism. In our studies, we found that Piezo1 stably localizes to RGD matrix adhesions in normal but not in transformed cells. Piezo1 binding requires contractility and triggers local Ca 2+ entry during adhesion formation and turnover. In transformed cells, Piezo1 level does not affect adhesion morphology; and there is no detectable Ca 2+ influx around adhesions. Based upon these findings, we suggest that Piezo1 is a novel component of integrin-based adhesions in non-transformed cells and contributes to the distinct mechanosensing and Ca 2+ signaling in normal vs transformed cells.Concentration of Piezo1 at adhesions is a key factor underlying Piezo1's physiological functions.

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Section: Introductionmentioning

confidence: 60%

Section: Discussionmentioning

confidence: 99%

Force-dependent recruitment of Piezo1 drives adhesion maturation and calcium entry in normal but not tumor cells

Yao

Tijore

Cox

et al. 2020

Preprint

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“…Thus, the activity of the downstream signaling pathways that govern the microgravity-induced cytoskeletal changes are significantly impaired and are at least in part due to the microgravitytriggered inhibition of FAK and/or RhoA signaling (Higashibata et al, 2006;Li et al, 2009;Tan et al, 2018). Furthermore, recent data suggest that changes to the cytoskeleton may also impact signaling via mechanically activated ion channels and contacts in response to both cell-generated (Nourse and Pathak, 2017;Ellefsen et al, 2019) and externally applied mechanical inputs (Bavi et al, 2019). Thus, downstream signaling of the numerous mechanotransduction pathways depend on the concerted interaction of the cytoskeleton, cell adhesion molecules, and force sensing proteins, including mechanically activated ion channels.…”

Section: The Impact Of Microgravity Of Cell Cytoskeletonmentioning

confidence: 99%

Modeling the Impact of Microgravity at the Cellular Level: Implications for Human Disease

Bradbury

Choi

et al. 2020

Front. Cell Dev. Biol.

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A lack of gravity experienced during space flight has been shown to have profound effects on human physiology including muscle atrophy, reductions in bone density and immune function, and endocrine disorders. At present, these physiological changes present major obstacles to long-term space missions. What is not clear is which pathophysiological disruptions reflect changes at the cellular level versus changes that occur due to the impact of weightlessness on the entire body. This review focuses on current research investigating the impact of microgravity at the cellular level including cellular morphology, proliferation, and adhesion. As direct research in space is currently cost prohibitive, we describe here the use of microgravity simulators for studies at the cellular level. Such instruments provide valuable tools for cost-effective research to better discern the impact of weightlessness on cellular function. Despite recent advances in understanding the relationship between extracellular forces and cell behavior, very little is understood about cellular biology and mechanotransduction under microgravity conditions. This review will examine recent insights into the impact of simulated microgravity on cell biology and how this technology may provide new insight into advancing our understanding of mechanically driven biology and disease.

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“…Interestingly, Piezo1 channels seem to form clusters when heterologously expressed in mammalian cells and this clustering has been proposed to play a role in concerted gating transitions such as collective loss of inactivation ( 28-30 ). While it is currently unclear whether endogenous Piezo1 form native clusters in vivo, these results together suggest that the gating properties of Piezo channels can be modulated by the local channel density at the plasma membrane.…”

Section: Discussionmentioning

confidence: 99%

A Piezo1 Open State Reveals a Multi-fenestrated Ion Permeation Pathway

Jiang

Rosario

Botello‐Smith

et al. 2020

Preprint

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19Force-sensing Piezo channels are essential to many aspects of vertebrate physiology. Activation 20 of Piezo1 is facilitated by the presence of negative membrane lipids in the inner leaflet, such as 21 phosphatidylinositol-4,5-bisphosphate (PIP2). Here, to study how Piezo1 opens, we performed 22 tension) POPC membrane (11). We also showed that the dome rapidly flattens when membrane 60 tension is gradually increased. Despite flattening of the arms, however, the pore did not open. 61Since the Piezo1 arms are anticipated to act as mechanical levers, the shorter arms in our 62 truncated model may reduce the output force (on the pore) to the input effort (arm motion). 63Another possibility for the absence of opening motions in the pore may have come from the 64 symmetric property of our simulated bilayer: indeed, electrophysiological recordings showed 65 Piezo1 remains fully closed when reconstituted in symmetrical bilayers but spontaneously opens 66 in asymmetric bilayers containing dioleoyl-sn-glycero-3-phosphatidic acid (DOPA) or 67 lysophosphatidic acid (LPA) in the inner leaflet (12, 13). DOPA and LPA differ in the number of 68 fatty acid tails but are both negatively-charged. Interestingly, the presence of negatively-charged 69 PIP2 or phosphatidylserine (PS) lipids in the inner leaflet also promote channel activation (14-16). 70We thus reasoned that adding the missing arm regions and adding negatively charged PIP2 lipids 71 in the inner leaflet will allow us to computationally capture a Piezo1 open state. 72 73 74RESULTS 75 Piezo1 clustering induces flattening of the Piezo arms 76Our previous proof-of-concept AA simulation showed that the membrane curvature, or lipid dome, 77 imposed by the resting conformation of a truncated Piezo1 takes place over 3 μs (11). To reduce 78 computational time, here we first used a 12 μs Coarse-Grained (CG) Martini simulation to enable 79 rapid lipid diffusion and dome formation while the Piezo1 backbone was kept rigid. We performed 80 these CG simulations on both a symmetrical POPC membrane (PC:PC) and an asymmetrical 81 POPC membrane containing 5% PIP2 in the inner leaflet (PC:PC/PIP2) (Figure 1a, systems I and 82 II). The CG systems were then mapped back to an AA system and simulated it for an additional 83 2 μs (Figure 1a, systems III and IV). In all MD simulations with explicit solvent, the periodic 84 boundary conditions (PBC) create an infinite lattice where the simulated system is infinitely 85

show abstract

Myosin-II mediated traction forces evoke localized Piezo1-dependent Ca2+ flickers

Cited by 165 publications

References 77 publications

Force-dependent recruitment of Piezo1 drives adhesion maturation and calcium entry in normal but not tumor cells

Force-dependent recruitment of Piezo1 drives adhesion maturation and calcium entry in normal but not tumor cells

Modeling the Impact of Microgravity at the Cellular Level: Implications for Human Disease

A Piezo1 Open State Reveals a Multi-fenestrated Ion Permeation Pathway

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