Mechanosensitive Ca2 Research Articles

Mechanosensing by Piezo1 regulates osteoclast differentiation via PP2A-Akt axis in periodontitis.

The mechanosensitive Ca 2+ channel Piezo1 plays important regulatory roles in a variety of cellular activities. RANKL-mediated OC-genesis requires permissive co-stimulatory signal from ITAM receptors, such as OSCAR and TREM2, to trigger the calcineurin/calmodulin signaling axis via Ca 2+ oscillation, thereby upregulating NFATc1 expression. Activation of Piezo1 remarkably suppressed RANKL-induced NFATc1 activation which, in turn, reduced OC-genesis. Such mechanical activation of Piezo1 expressed on pre-OCs induced intracellular Ca 2+ influx. Nonetheless, PP2A-mediated dephosphorylation of Akt, not the calcineurin/calmodulin pathway, suppressed NFATc1 in RANKL-elicited OC-genesis and resultant bone resorption, both in vitro and in vivo . These results indicate that mechanostress applied to pre-OCs can downregulate pathogenic OC-genesis and that Piezo1, as the mediator, is a novel molecular target for the development of anti-osteolytic therapies.

Heavy mechanical force decelerates orthodontic tooth movement via Piezo1-induced mitochondrial calcium down-regulation

Orthodontic tooth movement (OTM) depends on periodontal ligament cells (PDLCs), which sense biomechanical stimuli and initiate alveolar bone remodeling. Light (optimal) forces accelerate OTM, whereas heavy forces decelerate it. However, the mechanisms by which PDLCs sense biomechanical stimuli and affect osteoclastic activities under different mechanical forces (MFs) remain unclear. This study demonstrates that mechanosensitive ion channel Piezo1-mediated Ca2+ signal conversion is crucial for sensing and delivering biomechanical signals in PDLCs under heavy-force conditions. Heavy MF up-regulated Piezo1 in PDLCs, reducing mitochondrial Ca2+ influx by inhibiting ITPR3 expression in mitochondria-associated membranes. Decreased mitochondrial calcium uptake led to reduced cytoplasmic release of mitochondrial DNA and inhibited the activation of the cGAS‒STING signaling cascade, subsequently inhibiting monocyte-to-osteoclast differentiation. Inhibition of Piezo1 or up-regulation of STING expression under heavy MF conditions significantly increased osteoclast activity and accelerated OTM. These findings suggest that heavy MF-induced Piezo1 expression in PDLCs is closely related to the control of osteoclast activity during OTM and plays an essential role in alveolar bone remodeling. This mechanism may be a potential therapeutic target for accelerating OTM.

Shear Stress Induces Morphology Changes in Human Lung Microvascular Endothelial Cells via Calcium Influx

Introduction: The pulmonary vascular endothelium is in contact with laminar blood flow, resulting in a physiologic degree of shear stress exerted on endothelial cells (ECs). In vitro cell culture of ECs is typically performed under static conditions, leading to underappreciation of the impact of shear stress. Calcium signaling is among the most ubiquitous cell signaling mechanisms, and changes in intracellular calcium concentration ([Ca2+]i) have been linked to shear stress. The impact of shear stress on human lung microvascular endothelial cell (hLMVEC) morphology and cell signaling is not well described. We hypothesized that hLMVECs exposed to shear stress would undergo Ca2+-dependent morphologic changes. Methods: The effect of shear stress on [Ca2+]i was first tested using ratiometric measurement. Early passage (p≤8) primary hLMVECs from three unique donor lots were plated in gelatin-coated Ibidi 0.2 uM depth plates for 16 h, then incubated with the calcium indicator Fura-2 AM for 1 h. Measurement of [Ca2+]i was obtained over 15 minutes under static and physiologic shear stress (0 and 12 dyn/cm2, respectively), using validated flow rates from the Ibidi system. Measured [Ca2+]i was compared between cells treated vehicle or an inhibitor of the mechanosensitive Ca2+-permeable channel TRPV4 (HC-067047). HC treatment was for 1 h prior to and throughout the duration of shear exposure. Morphology changes were then assessed in hLMVECs from the same three cell lots grown in standard 6-well plates; one plate kept in static culture, while another was exposed to 24 h of 12 dyn/cm2 shear stress using an orbital shaker. Treatments in each plate were control, vehicle, and HC. Representative photos of each well were taken at 0 h and at 24 h. Average ratios of shortest to longest dimensions from 30 cells/field were measured using ImageJ and compared between treatments and shear conditions. A 2-way ANOVA with post-test was used to test for statistically significant changes in morphology. Results: Shear stress increased [Ca2+]i within 15 minutes, and both baseline [Ca2+]i and observed change in response to shear stress were decreased by TRPV4 inhibition with HC. Morphologic changes were observed after exposure to shear stress on microscopic examination, with cells grown in static culture having typical cobblestone appearance and shear-adapted cells having an elongated, spindle like appearance aligned in the direction of flow. The calculated ratio (shortest to longest dimension) of all wells at 0 h was ~0.70 with no significant differences between groups. 24 h of shear stress caused a nearly 80% decrease in ratio compared to static culture in untreated cells (p<0.05), with a decrease of only 30% in HC-treated cells after 24 h of shear (p<0.05). Conclusions: Exposure to shear stress at physiological levels results in a rapid increase [Ca2+]i through mechanosensitive, Ca2+-permeable TRPV4 channels as well as notable morphologic changes to hLMVECs with prolonged exposure to shear stress that appear to be mediated in large part by TRPV4. Further investigation into the impact of shear stress on hLMVECs is warranted to elucidate biochemical pathways and other downstream functional consequences of increased [Ca2+]i. NIH-T32HL007534. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

PIEZO1 is a distal nephron mechanosensor and is required for flow-induced K+ secretion.

Ca2+-activated BK channels in renal intercalated cells (ICs) mediate luminal flow-induced K+ secretion (FIKS), but how ICs sense increased flow remains uncertain. We examined whether PIEZO1, a mechanosensitive Ca2+-permeable channel expressed in the basolateral membranes of ICs, is required for FIKS. In isolated cortical collecting ducts (CCDs), the mechanosensitive cation-selective channel inhibitor GsMTx4 dampened flow-induced increases in intracellular Ca2+ concentration ([Ca2+]i), whereas the PIEZO1 activator Yoda1 increased [Ca2+]i and BK channel activity. CCDs from mice fed a high-K+ (HK) diet exhibited a greater Yoda1-dependent increase in [Ca2+]i than CCDs from mice fed a control K+ diet. ICs in CCDs isolated from mice with a targeted gene deletion of Piezo1 in ICs (IC-Piezo1-KO) exhibited a blunted [Ca2+]i response to Yoda1 or increased flow, with an associated loss of FIKS in CCDs. Male IC-Piezo1-KO mice selectively exhibited an increased blood [K+] in response to an oral K+ bolus and blunted urinary K+ excretion following a volume challenge. Whole-cell expression of BKα subunit was reduced in ICs of IC-Piezo1-KO mice fed an HK diet. We conclude that PIEZO1 mediates flow-induced basolateral Ca2+ entry into ICs, is upregulated in the CCD in response to an HK diet, and is necessary for FIKS.

Functional coupling between Piezo1 and TRPM4 influences the electrical activity of HL-1 atrial myocytes.

The transient receptor potential melastatin 4 (TRPM4) channel contributes extensively to cardiac electrical activity, especially cardiomyocyte action potential formation. Mechanical stretch can induce changes in heart rate and rhythm, and the mechanosensitive channel Piezo1 is expressed in many cell types within the myocardium. Our previous study showed that TRPM4 and Piezo1 are closely co-localized in the t-tubules of ventricular cardiomyocytes and contribute to the Ca2+-dependent signalling cascade that underlies hypertrophy in response to mechanical pressure overload. However, there was no direct evidence showing that Piezo1 activation was related to TRPM4 activation in situ. In the present study, we employed the HL-1mouse atrial myocyte-like cell line as an in vitro model to investigate whether Piezo1-TRPM4 coupling can affect action potential properties. We used the small molecule Piezo1 agonist, Yoda1, as a surrogate for mechanical stretch to activate Piezo1 and detected the action potential changes in HL-1 cells using FluoVolt, a fluorescent voltage sensitive dye. Our results demonstrate that Yoda1-induced activation of Piezo1 changes the action potential frequency in HL-1 cells. This change in action potential frequency is reduced by Piezo1 knockdown using small intefering RNA. Importantly knockdown or pharmacological inhibition of TRPM4significantly affected the degree to which Yoda1-evoked Piezo1 activation influenced action potential frequency. Thus, the present study provides in vitro evidence of a functional coupling between Piezo1 and TRPM4 in a cardiomyocyte-like cell line. The coupling of a mechanosensitive Ca2+ permeable channel and a Ca2+-activated TRP channel probably represents a ubiquitous model for the role of TRP channels in mechanosensory transduction. KEY POINTS: The transient receptor potential melastatin 4 (TRPM4) and Piezo1 channels have been confirmed to contribute to the Ca2+-dependent signalling cascade that underlies cardiac hypertrophy in response to mechanical pressure overload. However, there was no direct evidence showing that Piezo1 activation was related to TRPM4 activation in situ. We employed the HL-1mouse atrial myocyte-like cell line as an in vitro model to investigate the effect of Piezo1-TRPM4 coupling on cardiac electrical properties. The results show that both pharmacological and genetic inhibition of TRPM4significantly affected the degree to which Piezo1 activation influenced action potential frequency in HL-1 cells. Our findings provide in vitro evidence of a functional coupling between Piezo1 and TRPM4 in a cardiomyocyte-like cell line. The coupling of a mechanosensitive Ca2+ permeable channel and a Ca2+-activated TRP channel probably represents a ubiquitous model for the role of TRP channels in mechanosensory transduction in various (patho)physiological processes.

Piezo1 transforms mechanical stress into pro senescence signals and promotes osteoarthritis severity

Osteoarthritis (OA) is a prevalent disease among elderly people and is often characterized by chronic joint pain and dysfunction. Recently, growing evidence of chondrocyte senescence in the pathogenesis of OA has been found, and targeting senescence has started to be recognized as a therapeutic approach for OA. Piezo1, a mechanosensitive Ca2+ channel, has been reported to be harmful in sensing abnormal mechanical overloading and leading to chondrocyte apoptosis. However, whether Piezo1 can transform mechanical signals into senescence signals has rarely been reported. In this study, we found that severe OA cartilage expressed more Piezo1 and the senescence markers p16 and p21. 24 h of periodic mechanical stress induced chondrocyte senescence in vitro. In addition, we demonstrated the pivotal role of Piezo1 in OA chondrocyte senescence induced by mechanical stress. Piezo1 sensed mechanical stress and promoted chondrocyte senescence via its Ca2+ channel ability. Moreover, Piezo1 promoted SASP factors production under mechanical stress, particularly in IL-6 and IL-1β. p38MAPK and NF-κB activation were two key pathways that responded to Piezo1 activation and promoted IL-6 and IL-1β production, respectively. Collectively, our study revealed a connection between abnormal mechanical stress and chondrocyte senescence, which was mediated by Piezo1.

THU407 CRISPR/Cas9-based Knockout Of CFTR Alters Mechano-sensitivity And Proteomic Profile In An Osteocyte Model

Abstract Disclosure: W. Du: None. J. Chen: None. Y. Ruan: None. Osteocytes, the most abundant bone cell type with recognized endocrine functions, play essential roles in mechano-signal transduction in the skeletal system required for bone modelling/remodelling and mineral homeostasis, although the underlying molecular mechanisms are not fully understood. Bone problems are present in cystic fibrosis (CF), a genetic disease resulted from mutations in CF transmembrane conductance regulator (CFTR), which is a Cl− channel gene recently revealed to be expressed in osteocytes with its exact roles largely unexplored. In the present study, CRISPR/Cas9 technology was used to knock out CFTR (CFTR-KO) in MLO-Y4, a commonly used osteocyte model, which resulted in a significant decrease (by 80.7 ± 7.4%) in shear force-induced Ca2+ oscillations (measured by Fura-2 imaging) as compared to wild-type (WT) cells (n = 205 (WT) and 114 (KO) cells, t-test, p < 0.001). However, the CFTR-KO cells did not show, in comparison with WT cells, any reduction in expressing (measured by quantitative PCR, n = 5) Piezo1 or TRPV4, two reported key mechano-sensitive Ca2+ channels in osteocytes, nor change in cell membrane stiffness (measured by atom force microscope, n = 58 (WT) and 64 (KO) cells, t-test, p > 0.05). Moreover, the shear-force-stimulated Ca2+ oscillations in WT cells were observed to be dependent on extracellular Cl−, which together suggested possibly a direct role of CFTR, through its Cl- channel function, in osteocyte mechano-sensitivity. We next performed proteomic analysis by mass spectrometry detection of whole-cell protein extracts from the MLO-Y4 cells, which revealed downregulation of genes related to focal adhesion, gap junction and actin cytoskeleton regulation in CFTR-KO cells. These results, therefore, have suggested a crucial involvement of CFTR in osteocyte function, providing new insights into mechanistic understanding of the mechano-transduction in the skeletal system. This work was supported in part by Health and Medical Research Fund of Hong Kong (No.18191361), Theme-based Research Scheme of Hong Kong (No. T13-402/17N), and Areas of Excellence Scheme of Hong Kong (AoE/M-402/20). Presentation: Thursday, June 15, 2023

TRPV4 functional status in cystic cells regulates cystogenesis in autosomal recessive polycystic kidney disease (ARPKD) during variations in dietary potassium

Mechanosensitive Ca2+-permeable transient receptor potential vanilloid type 4 (TRPV4) channel plays a dominant role in maintaining intracellular Ca2+ ([Ca2+]i) homeostasis and flow-sensitive [Ca2+]i signaling in the distal segments of renal tubule and collecting duct. Polycystic kidney disease (PKD) manifests as progressive cyst growth with cystic cells exhibiting exacerbated cAMP-dependent fluid secretion along with deficient mechanosensitivity and reduced basal [Ca2+]i levels, and impaired TRPV4 activity. In this study, we tested how regulation of renal TRPV4 function by elevated dietary K+ intake modulates the rate of cystogenesis and mechanosensitive [Ca2+]i signaling in cystic cells of PCK453 rats (1 m.o.), a homologous model of human autosomal recessive PKD (ARPKD), where cyst development is restricted to the collecting duct. One month treatment with both high KCl (5% K+) and KB/C (5% K+ with bicarbonate to citrate in 4:1 ratio) diets significantly increased kidney TRPV4 levels in PCK453 rats when compared to the control group fed regular diet (0.9% K+). High KCl diet also caused an increased TRPV4-dependent Ca2+ influx, higher basal [Ca2+]i, and partial restoration of mechanosensitivity in freshly isolated monolayers of cystic cells. Unexpectedly, high KB/C diet induced an opposite effect by reducing TRPV4 activity and further worsening [Ca2+]i homeostasis. Importantly, high KCl diet decreased, whereas high KB/C diet further increased cAMP levels, as was assessed by the extent of cAMP-dependent translocation of AQP2 water channel to apical membrane in cystic cells. At the systemic level, high KCl diet fed PCK453 rats had significantly lower kidney-to-bodyweight ratio and reduced cystic area in renal sections. The beneficial effects of high KCl diet were negated by a concomitant administration of an orally active TRPV4 antagonist, GSK2193874, resulting in greater kidney weight and accelerated cystogenesis, when compared to these values in control rats. In a similar manner, high KB/C diet exacerbated renal manifestations of ARPKD, consistent with deficient TRPV4 activity in cystic cells. Moreover, KCl+GSK2193874 and high KB/C treated PCK453 rats have increased urinary levels of a renal injury marker, KIM-1.In conclusion, we demonstrate that TRPV4 channel activity negatively regulates cAMP levels in cystic cells upon variations in K+ intake thus attenuating (high activity) or accelerating (low activity) ARPKD progression in PCK453 rats. We propose that pharmacological or dietary means leading to TRPV4 stimulation might be useful to counteract PKD progression in the clinical setting. This research was supported by NIH-NIDDK DK117865, DK119170, AHA EIA35260097 (to O. Pochynyuk) and AHA-19CDA34660148 (to V. N. Tomilin). This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Role of mechanosensitive Piezo1 receptor expressed on macrophage in Periodontitis

Abstract Objectives: The mechanosensitive Ca 2+ion channels, Piezo1, converts the mechanical stimulus into cell signals in a variety of immune cells. However, the pathophysiological property of Piezo1 in the oral polymicrobial infectious disease of periodontitis is largely unknown. This study investigated the role of Piezo1 in the inflammatory and phagocytic reactions by RAW264.7 macrophages in response to the exposures to periodontal pathogen, P.gingivalis. Experimental methods: Short hairpin RNA (shRNA) vector for Piezo1 or control scrambled sequence was transfected to RAW264.7 cells. Then, RAW264.7 cells were incubated for 24 hours in the presence or absence of whole P.gingivalis(MOI; 10) or outer membrane vesicles (OMVs, 1 μg/ml) isolated from P.gingivalis, w or w/o Yoda1 (synthetic Piezo1 activator), or shear stress. qPCR was used to monitor the mRNA expressions of Piezo1, TNF-α, TLR-2, and TLR-4, whereas TNF-α protein was detected by ELISA. RAW264.7’s phagocytic ability was evaluated by cytoplasm-internalization of pHrodo-labeled whole P.gingivalisor OMVs using a flow cytometer. Results: OMVs induced more TNF-α production and phagocytosis by RAW264.7 cells than whole P.gingivalis, both of which were further upregulated by Yoda1 as well as shear stress (p<0.05, ANOVA). Shear stress combined with OMV-stimulation upregulated the gene expression of TLR-4, while downregulating TLR-2 gene in RAW264.7 cells. The shRNA-targeting Piezo1 significantly suppressed the TNF-α production and internalization of OMVs by RAW264.7 cells compared control scramble shRNA (p<0.05, ANOVA). Conclusion: The present study indicated that mechanical stress may dysregulate the macrophage-mediated innate immune responses in periodontitis. NIH NIDCR grants, DE-027851, DE-028715 and DE-029709

Piezo1 and TRPV4 complementary contribute to [Ca2+]i homeostasis in collecting duct cells

Mechanical stress arising from elevated fluid flow is an important regulator of the water-electrolyte transport in the collecting duct (CD). It is well established that mechano-sensitive TRPV4 Ca2+-permeable channel mediates intracellular Ca2+ ([Ca2+]i) responses to high flow in these cells. Piezo1, a Ca2+-permeable channel directly activated by the plasma membrane stretch, is a recent arrival at this scene. Piezo1 expression has been reported in the CD. However, its functional significance is yet to be determined. Here, we applied a combination of Ca2+ imaging and confocal microscopy in freshly isolated split-opened CDs to investigate a potential interplay between TRPV4 and Piezo1 in mediating [Ca2+]i signaling in the CD. Immunofluorescent analysis of split-opened CDs showed presence of Piezo1 in both AQP2-positive (principal cells, PC) and -negative (intercalated cells, IC) with higher intensity in the former. Importantly, Piezo1 was apparent on both apical and basolateral membrane of CD cells. Piezo1 agonists, Yoda-1 (20μM) and Jedi2 (500μM) acutely increase [Ca2+]i in both principal and intercalated cells. The responses were abolished when extracellular Ca2+ was buffered with EGTA suggesting a direct Ca2+ influx via Piezo1. Interestingly, we detected two disparate calcium responses to Piezo1 activation with the majority (70%) cells showing a fast transient response with a sustained plateau, whereas the remaining (30%) population had much slower gradual calcium increase to the same plateau level. Subsequent immunofluorescent analysis revealed that fast Ca2+ responses were attributed to PC, whereas responses with slow kinetics corresponded to IC. Consistently, PCs have ~3 fold higher Piezo-1 signal when compared to neighbor ICs. We next tested whether Piezo1 activity depends on TRPV4 status. Genetic deletion and pharmacological inhibition of TRPV4 with GSK2193874 did not affect Piezo1-dependent elevations in [Ca2+]i. However, high K+ diet, which is known to elevate the flow in the CD and augment both TRPV4 activity and expression, led to diminished Piezo1 responses to Yoda-1. In summary, our results are consistent with the view that Piezo1 and TRPV4 are functional in both principal and intercalated cells of the collecting duct and operate independently to modulate mechanosensitive [Ca2+]i signaling. We hypothesize that augmented TRPV4-dependent [Ca2+]i is compensated by the diminished activity of Piezo1 to account for elevated flow rate upon increased K+ intake. This research was supported by NIH-NIDDK DK117865, DK119170, AHA EIA35260097 (to O. Pochynyuk) and AHA-19CDA34660148 (to V. N. Tomilin). This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Piezo1 regulates expression of BK and TRPV4 channels in mouse cortical collecting duct (CCD)

Within the CCD, an acute increase in tubular fluid flow rate (TFFR) leads to an immediate high amplitude increase in [Ca 2+ ] i , due to release of IP3-sensitive internal Ca 2+ stores coupled to extracellular Ca 2+ entry at the basolateral membrane in both principal (PC) and intercalated (IC) cells therein (Liu et al., 2003, 2005, 2007). This is followed by a decay in [Ca 2+ ] i to a sustained plateau elevation due, at least in part, to luminal Ca 2+ entry through TRPV4 (Berrout et al., 2012). This flow-induced increase in [Ca 2+ ] i is necessary for BK channel-mediated flow induced K + secretion (FIKS) in the microperfused mammalian CCD. We generated a mouse with IC-specific targeted deletion of the mechanosensitive Ca 2+ permeable channel, Piezo1, which is expressed on the basolateral membranes of PCs and ICs in the mouse CCD (Dalghi et al., 2019). Microperfused CCDs isolated from these IC-PIEZO1-KO mice fed a high K (HK, 5% K + ) diet and subject to an increase in TFFR did not exhibit either a peak or plateau elevation in [Ca 2+ ] i in response to flow, and FIKS was eliminated. The absence of FIKS and the plateau elevation in [Ca 2+ ] during sustained flow in the CCDs of KO mice led us to examine whether BK and TRPV4 channel expression was impacted by deletion of PIEZO1.Indirect immunofluorescence (IF) staining was performed to examine expression and localization of the BK and TRPV4 channels in PCs and ICs of IC-PIEZO1-KO mice. Whole cell and apical + subapical fluorescence intensities in cryosections were analyzed using LAS X software from a total of 3 male and 3 female control mice and 3 male and 3 female IC-PIEZO1-KO mice fed HK diet x 10d.IF analysis showed reduced whole cell BKα expression in ICs of both male (p≤0.05) and female (p≤0.01) IC-PIEZO1-KO mice. We also saw reduced BKα expression in PCs from female but not male KOs. In addition, ICs in female but not male KO mice had reduced whole cell TRPV4 expression vs. controls (p≤0.01). Also, whole cell expression of TRPV4 in PCs from female KO mice was reduced vs. female controls (p≤0.01). The ratio of apical-to-whole cell expression of BKα was similar in PCs and ICs of KO and control mice. Male, but not female, KO mice had modestly reduced apical TRPV4 expression in PCs vs. controls (p≤0.01). Piezo1 plays a role in the regulation of BK and TRPV4 channel expression in CCDs. In addition, sex differences exist in whole cell expression of these channels in response to IC-selective deletion of PIEZO1. R01 DK038470 (TK, LMS); R01 DK129285 (TK, LMS); P30 DK079307 (TK) This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Membrane curvature governs the distribution of Piezo1 in live cells.

Piezo1 is an evolutionarily conserved mechanosensitive ion channel in eukaryotic cells. Since its discovery, vital biological roles of Piezo1 have been found in cell migration, cell-cell adhesion and cell differentiation, featuring Piezo1's force sensing capability. However, mechanosensitive Ca2+ signals in filopodia were reported to be independent of Piezo1. Moreover, inhomogeneous distributions of Piezo1 were observed in cell migration, cytokinesis, and on the surface of red blood cells. Understanding the subcellular distribution of Piezo1 can be critical for explaining many biological processes. Using live cell fluorescence microscopy, first, we show that Piezo1 is depleted from highly curved membrane protrusions, such as filopodia and manually pulled membrane tethers. Further experiments on nanopatterned substrates show an enrichment of Piezo1 to membrane invaginations. The correlation between Piezo1 density and membrane curvature fits well to a 2-parameter membrane bending model, revealing the nano-geometries of Piezo1-membrane complexes. Chemically activated Piezo1 has higher density on filopodia, with or without Ca2+. These observations are consistent with flattening of Piezo1 upon activation. Furthermore, Piezo1 expression mechanically suppresses filopodia formation, an effect that is weakened by chemical activation.

TRPC1 channels underlie stretch-modulated sarcoplasmic reticulum calcium leak in cardiomyocytes.

Transient receptor potential canonical 1 (TRPC1) channels are Ca2+-permeable ion channels expressed in cardiomyocytes. An involvement of TRPC1 channels in cardiac diseases is widely established. However, the physiological role of TRPC1 channels and the mechanisms through which they contribute to disease development are still under investigation. Our prior work suggested that TRPC1 forms Ca2+ leak channels located in the sarcoplasmic reticulum (SR) membrane. Prior studies suggested that TRPC1 channels in the cell membrane are mechanosensitive, but this was not yet investigated in cardiomyocytes or for SR localized TRPC1 channels. We applied adenoviral transfection to overexpress or suppress TRPC1 expression in neonatal rat ventricular myocytes (NRVMs). Transfections were evaluated with RT-qPCR, western blot, and fluorescent imaging. Single-molecule localization microscopy revealed high colocalization of exogenously expressed TRPC1 and the sarco/endoplasmic reticulum Ca2+ ATPase (SERCA2). To test our hypothesis that TRPC1 channels contribute to mechanosensitive Ca2+ SR leak, we directly measured SR Ca2+ concentration ([Ca2+]SR) using adenoviral transfection with a novel ratiometric genetically encoded SR-targeting Ca2+ sensor. We performed fluorescence imaging to quantitatively assess [Ca2+]SR and leak through TRPC1 channels of NRVMs cultured on stretchable silicone membranes. [Ca2+]SR was increased in cells with suppressed TRPC1 expression vs. control and Transient receptor potential canonical 1-overexpressing cells. We also detected a significant reduction in [Ca2+]SR in cells with Transient receptor potential canonical 1 overexpression when 10% uniaxial stretch was applied. These findings indicate that TRPC1 channels underlie the mechanosensitive modulation of [Ca2+]SR. Our findings are critical for understanding the physiological role of TRPC1 channels and support the development of pharmacological therapies for cardiac diseases.

Intestinal enteroendocrine cells rely on ryanodine and IP3 calcium store receptors for mechanotransduction.

Enteroendocrine cells (EECs) are specialized sensors of luminal forces and chemicals in the gastrointestinal (GI) epithelium that respond to stimulation with a release of signalling molecules such as serotonin (5-HT). For mechanosensitive EECs, force activates Piezo2 channels, which generate a very rapidly activating and inactivating (∼10ms) cationic (Na+ , K+ , Ca2+ ) receptor current. Piezo2 receptor currents lead to a large and persistent increase in intracellular calcium (Ca2+ ) that lasts many seconds to sometimes minutes, suggesting signal amplification. However, intracellular calcium dynamics in EEC mechanotransduction remain poorly understood. The aim of this study was to determine the role of Ca2+ stores in EEC mechanotransduction. Mechanical stimulation of a human EEC cell model (QGP-1) resulted in a rapid increase in cytoplasmic Ca2+ and a slower decrease in ER stores Ca2+ , suggesting the involvement of intracellular Ca2+ stores. Comparing murine primary colonic EECs with colonocytes showed expression of intercellular Ca2+ store receptors, a similar expression of IP3 receptors, but a >30-fold enriched expression of Ryr3 in EECs. In mechanically stimulated primary EECs, Ca2+ responses decreased dramatically by emptying stores and pharmacologically blocking IP3 and RyR1/3 receptors. RyR3 genetic knockdown by siRNA led to a significant decrease in mechanosensitive Ca2+ responses and 5-HT release. In tissue, pressure-induced increase in the Ussing short circuit current was significantly decreased by ryanodine receptor blockade. Our data show that mechanosensitive EECs use intracellular Ca2+ stores to amplify mechanically induced Ca2+ entry, with RyR3 receptors selectively expressed in EECs and involved in Ca2+ signalling, 5-HT release and epithelial secretion. KEY POINTS: A population of enteroendocrine cells (EECs) are specialized mechanosensors of the gastrointestinal (GI) epithelium that respond to mechanical stimulation with the release of important signalling molecules such as serotonin. Mechanical activation of these EECs leads to an increase in intracellular calcium (Ca2+ ) with a longer duration than the stimulus, suggesting intracellular Ca2+ signal amplification. In this study, we profiled the expression of intracellular Ca2+ store receptors and found an enriched expression of the intracellular Ca2+ receptor Ryr3, which contributed to the mechanically evoked increases in intracellular calcium, 5-HT release and epithelial secretion. Our data suggest that mechanosensitive EECsrely on intracellular Ca2+ stores and are selective in their use of Ryr3 for amplification of intracellular Ca2+ . This work advances our understanding of EEC mechanotransduction and may provide novel diagnostic and therapeutic targets for GI motility disorders.

Abstract 15915: Ultrasound Targeted Microbubble Cavitation-Induced Endothelial Hyperpermeability is Calcium-Dependent and Regulated by Enos Signaling

Introduction: Ultrasound ( US )-targeted microbubble ( MB ) cavitation ( UTMC ) facilitates delivery of cell-impermeant drugs across the endothelial barrier; mechanisms are poorly understood. We reported that UTMC causes inter-endothelial gaps in cultured endothelial cell ( EC ) monolayers, which could increase barrier permeability, and that UTMC increases Ca 2+ influx into ECs. Given that increased intracellular Ca 2+ activates eNOS, and nitric oxide (NO) release promotes microvascular permeability, we hypothesized that UTMC increases intracellular Ca 2+ through activation of mechanosensitive Piezo-1 Ca 2+ channels, leading to NO synthesis and endothelial barrier hyperpermeability. Methods: Transwells were endothelialized with human coronary artery ECs. Lipid MBs were added, and US was delivered for 10 s (1 MHz, 250 kPa, 10 cycles, 10 ms interval). Permeability was measured using dextran transfer and transendothelial electrical resistance ( TEER ). GsMTx4 and L-NAME were used to inhibit Piezo1 and eNOS, respectively; Fluo-4 AM to visualize Ca 2+ influx; DAF-FM to detect NO. S-nitrosylation was measured with biotin switch assay. Results: UTMC reduced TEER (1.7 fold, p<0.05 ) and increased dextran flux across the transwell (2-fold, p<0.01 for 70 kDa dextran, 1.6 fold, p<0.05 for 10 kDa dextran), which was abrogated by L-NAME. UTMC significantly increased Ca 2+ influx into ECs and tripled NO ( p<0.05 ), but these increases and UTMC-mediated hyperpermeability were blunted by Piezo1 channel inhibition ( p<0.0001) . UTMC increased S-nitrosylation of proteins (1.7 fold, p<0.01 ) and was associated with s-nitrosylation of VE-cadherin, its redistribution into focal adhesion junctions, and increased stress fiber formation, which were abolished by L-NAME. Conclusions: UTMC causes endothelial barrier hyperpermeability through a Ca 2+ -dependent mechanism, where Ca 2+ influx into ECs, mediated in part by mechanosensitive Piezo1 channels, modulates eNOS signaling. Our data suggest that eNOS regulates UTMC-induced hyperpermeability, possibly through s-nitrosylation of VE-cadherin. Further studies to examine mechanisms regulating UTMC bioeffects will aid in clinical translation and optimization of UTMC for delivery of cell-impermeant drugs.

Systemic effect of NF-kB-mediated Signaling Pathway Induced by Mechanosensitive Ca2+-Channel TRPV4 in Pulmonary Endothelial Cells

Systemic effect of NF-kB-mediated Signaling Pathway Induced by Mechanosensitive Ca2+-Channel TRPV4 in Pulmonary Endothelial Cells

Mechanosensitive cation currents through TRPC6 and Piezo1 channels in human pulmonary arterial endothelial cells.

Mechanosensitive cation channels and Ca2+ influx through these channels play an important role in the regulation of endothelial cell functions. Transient receptor potential canonical channel 6 (TRPC6) is a diacylglycerol-sensitive nonselective cation channel that forms receptor-operated Ca2+ channels in a variety of cell types. Piezo1 is a mechanosensitive cation channel activated by membrane stretch and shear stress in lung endothelial cells. In this study, we report that TRPC6 and Piezo1 channels both contribute to membrane stretch-mediated cation currents and Ca2+ influx or increase in cytosolic-free Ca2+ concentration ([Ca2+]cyt) in human pulmonary arterial endothelial cells (PAECs). The membrane stretch-mediated cation currents and increase in [Ca2+]cyt in human PAECs were significantly decreased by GsMTX4, a blocker of Piezo1 channels, and by BI-749327, a selective blocker of TRPC6 channels. Extracellular application of 1-oleoyl-2-acetyl-sn-glycerol (OAG), a membrane permeable analog of diacylglycerol, rapidly induced whole cell cation currents and increased [Ca2+]cyt in human PAECs and human embryonic kidney (HEK)-cells transiently transfected with the human TRPC6 gene. Furthermore, membrane stretch with hypo-osmotic or hypotonic solution enhances the cation currents in TRPC6-transfected HEK cells. In HEK cells transfected with the Piezo1 gene, however, OAG had little effect on the cation currents, but membrane stretch significantly enhanced the cation currents. These data indicate that, while both TRPC6 and Piezo1 are involved in generating mechanosensitive cation currents and increases in [Ca2+]cyt in human PAECs undergoing mechanical stimulation, only TRPC6 (but not Piezo1) is sensitive to the second messenger diacylglycerol. Selective blockers of these channels may help develop novel therapies for mechanotransduction-associated pulmonary vascular remodeling in patients with pulmonary arterial hypertension.

The Role of Mechanically-Activated Ion Channels Piezo1, Piezo2, and TRPV4 in Chondrocyte Mechanotransduction and Mechano-Therapeutics for Osteoarthritis.

Mechanical factors play critical roles in the pathogenesis of joint disorders like osteoarthritis (OA), a prevalent progressive degenerative joint disease that causes debilitating pain. Chondrocytes in the cartilage are responsible for extracellular matrix (ECM) turnover, and mechanical stimuli heavily influence cartilage maintenance, degeneration, and regeneration via mechanotransduction of chondrocytes. Thus, understanding the disease-associated mechanotransduction mechanisms can shed light on developing effective therapeutic strategies for OA through targeting mechanotransducers to halt progressive cartilage degeneration. Mechanosensitive Ca2+-permeating channels are robustly expressed in primary articular chondrocytes and trigger force-dependent cartilage remodeling and injury responses. This review discusses the current understanding of the roles of Piezo1, Piezo2, and TRPV4 mechanosensitive ion channels in cartilage health and disease with a highlight on the potential mechanotheraputic strategies to target these channels and prevent cartilage degeneration associated with OA.

Different modes of Piezo1 Ca2+ signaling in principal and intercalated cells of the collecting duct

It has been recognized that mechanical stress arising from elevated fluid flow and variations in osmolarity is an important regulator of the water‐electrolyte transport in the real tubule. The collecting duct is the terminal segment of the renal tubule, which is commonly exposed to the highest level of mechanical forces. It consists of electrically uncoupled principal and intercalated cells having different morphology and discrete functional roles. Using genetic animal models, we previously demonstrated that mechano‐activated TRPV4 and TRPC3 Ca2+‐permeable channels mediate responses to high flow and hypotonicity, respectively. However, both channels are not considered to be truly mechanosensitive, but rather being activated in response to a primary putative mechanosensor. Piezo1 has been recently identified as a Ca2+‐permeable channel directly activated by the plasma membrane stretch. Piezo1 expression has been found in the renal epithelia, but its role in mechanosensitive Ca2+ signaling is not known. Here, we used freshly isolated split‐opened cortical collecting ducts to show that selective Piezo1 activators, YODA‐1(20uM) and Jedi2 (500uM) acutely increase [Ca2+]i in both principal and intercalated cells. The responses were abolished when extracellular Ca2+ was buffered with EGTA suggesting a direct Ca2+ influx via Piezo1. Interestingly, we detected two disparate calcium responses to Piezo1 activation with the majority (70%) cells showing a fast transient response with a sustained plateau, whereas the remaining (30%) population had much slower gradual calcium increase, to the same plateau level. The subsequent immunofluorescent analysis revealed that the cells with rapid responses to Piezo1 stimulation express AQP2, a selective marker of principal cells. In contrast, AQP2‐negative intercalated cells matched the population of cells with the slow response. Genetic deletion and pharmacological inhibition of TRPV4 and TRPC3 (with GSK2193874 and Pyr10, respectively) did not affect Piezo1‐dependent elevations in [Ca2+]i arguing against a functional link between channel activation with flow‐ and osmo‐sensitive Ca2+ signaling. In summary, our results demonstrate that Piezo1 is functional in both principal and intercalated cells of the collecting duct with a greater expression in the former. Activation of the channel is not directly associated with mechanosensitive Ca2+ signaling via TRPV4 and TRPC3. Future studies are necessary to unravel the significance and physiological roles of different Piezo1 expression in principal and intercalated cells of the collecting duct.

The mechanosensitive Ca2+ channel, OSCA1.1, modulates root hydrotropic bending in Arabidopsis thaliana

Roots exhibit positive hydrotropism in response to soil moisture gradients in arid conditions. However, the mechanisms that regulate hydrotropism are yet to be elucidated. Ca2+ is involved in this response, but the molecular factors that interact with Ca2+ are currently unknown. To understand the role of Ca2+ in hydrotropism, as well as to identify proteins that are involved in this process, we examined the physiology of Arabidopsis thaliana seedlings cultured in Ca2+-free medium. Treatment with cytosolic and apoplastic Ca2+ chelators triggered an increase in hydrotropic root bending, which became more pronounced during the latter stages of the hydrotropic response. Furthermore, we found that the phenotypes of mutants defective in OSCA1.1, a mechanosensitive Ca2+ channel, resembled those of wild-type seedlings treated with Ca2+ chelators. Although treatment with Ca2+ chelators also affected root gravitropism, no significant differences in root gravitropism were observed in osca1 mutants, suggesting that OSCA1.1 has a specific function in root hydrotropism. Moreover, transcript level of MIZ1 in OSCA1.1 knockout mutant was higher than that of wild type, specifically at latter stages of the hydrotropic response. Double mutants that carry miz1–1 or miz2 alleles in addition to the osca1 knockout allele lacked hydrotropic response, the phenotypes of which were resembled those of miz1–1 or miz2 single mutants. Our results suggest that OSCA1.1 functions within the same signaling pathway as MIZ1 and MIZ2, and that OSCA1.1-mediated Ca2+ influx across the plasma membrane is required to regulate hydrotropic root bending by regulating MIZ1 expression at the latter stages.