Project description:Wolff’s law and the Utah Paradigm of skeletal physiology state that bone architecture adapts to mechanical loads. These models predict the existence of a mechanostat that links strain induced by mechanical forces to skeletal remodeling. However, how the mechanostat influences bone remodeling remains elusive. Here, we find that Piezo1 deficiency in osteoblastic cells leads to loss of bone mass and spontaneous fractures with increased bone resorption. Furthermore, Piezo1-deficient mice are resistant to further bone loss and bone resorption induced by hind limb unloading, demonstrating that PIEZO1 can affect osteoblast-osteoclast crosstalk in response to mechanical forces. At the mechanistic level, in response to mechanical loads, PIEZO1 in osteoblastic cells controls the YAP-dependent expression of type II and IX collagens. In turn, these collagen isoforms regulate osteoclast differentiation. Taken together, our data identify PIEZO1 as the major skeletal mechanosensor that tunes bone homeostasis.

Project description:Group-2 innate-lymphoid cells (ILC2s) are critical mediators of the type-2 immune responses in multiple lung pathologies. We show that Piezo1, a mechanosensitive ion channel, plays a key role in regulating ILC2 functions by linking mechanical cues to biochemical signaling pathways. Both murine and human ILC2s strongly express Piezo1, and its activation by Yoda1 selectively enhances IL-13 production through calcium influx, which activates the mTOR-S6K pathway. This pathway leads to translational reprogramming, favoring IL-13 translation. Piezo1-deficient in ILC2s impairs this process, reducing IL-13 levels and resulting in attenuated lung inflammation and fibrosis in mouse models of IL-33- or Alternaria alternata-induced airway inflammation and bleomycin-induced fibrosis. These findings position Piezo1 as a critical mediator of ILC2-driven type-2 immune responses and highlight its potential as a therapeutic target for lung diseases characterized by excessive inflammation. This streamlined understanding of Piezo1 function improves focus on its mechanistic role in lung pathology.

Project description:Tendon tissue growth is promoted by mechanical stimulation, but the mechanism is not well understood. Piezo1, a mechanical stress-responsive channel receptor, is expressed in tendon cells, and the fact that tendon tissue growth was accelerated in Piezo1 gain of function mice suggests that Piezo1 plays an important role in tendon tissue growth. RNA-seq of tendon tissues from these mice showed increased expression of tendon-related genes and decreased expression of muscle-related genes, suggesting that Piezo1 may play a role in maintaining and enhancing the properties of tendon cells.

Project description:Mechanotransduction has been lately recognized as a major regulator of organ homeostasis under a myriad of pathological conditions. The role of Piezo1 in cardiac hypertrophy has never been explored. Here we performed RNA-Seq assay for wild type and Piezo1-Cko mice under sham or TAC surgery.

Project description:Piezo1 is a mechanosensitive ion channel that has gained recognition for its role in regulating diverse physiological processes. However, the influence of Piezo1 in inflammatory disease, including infection and tumor-immunity, is not well-studied. We postulated that Piezo1 links physical forces to immune regulation in myeloid cells. We discovered signal transduction via Piezo1 in myeloid cells and established this channel as the primary sensor of mechanical stress in these cells. Global inhibition of Piezo1 was protective against both cancer and septic shock and resulted in a diminution in suppressive myeloid cells. Moreover, deletion of Piezo1 in myeloid cells protected against cancer and increased survival in poly-microbial sepsis. Mechanistically, we show that mechanical stimulation promotes Piezo1-dependent myeloid cell expansion by suppressing Rb. We further show Piezo1-mediated silencing of Rb is regulated via upregulation of HDAC2. Collectively, our work uncovers Piezo1 as a targetable immune checkpoint that drives immune-suppressive myelopoiesis in cancer and infectious disease.

Project description:Mechanotransduction converts mechanical stimuli into biochemical signals to regulate cell growth, differentiation, and survival. However, how mechanotransduction is linked to gene expression remains poorly understood. Here, we report the identification of UBE2A as an mechano-sensitive trans-acting factor, which translocates from the cytosol to the nucleus upon mechanical stimuli. UBE2A is an E2 enzyme that catalyzes ubiquitination of histone, which eventually results in transcription activation of downstream genes. Using ChIP-seq and RNAseq analysis, we identify downstream genes of UBE2A, including YAP1, a well-known mechanotransducer. Knock-down of UBE2A/B significantly downregulates YAP1 protein expression. Our findings identify the new mechanotransduction pathway that regulates gene expression through histone ubiquitination by UBE2A/B.

Project description:Mechanotransduction converts mechanical stimuli into biochemical signals to regulate cell growth, differentiation, and survival. However, how mechanotransduction is linked to gene expression remains poorly understood. Here, we report the identification of UBE2A as an mechano-sensitive trans-acting factor, which translocates from the cytosol to the nucleus upon mechanical stimuli. UBE2A is an E2 enzyme that catalyzes ubiquitination of histone, which eventually results in transcription activation of downstream genes. Using ChIP-seq and RNAseq analysis, we identify downstream genes of UBE2A, including YAP1, a well-known mechanotransducer. Knock-down of UBE2A/B significantly downregulates YAP1 protein expression. Our findings identify the new mechanotransduction pathway that regulates gene expression through histone ubiquitination by UBE2A/B.

Project description:PIEZO1 is a mechanically-activated ion channel that contributes to flow sensing in vascular endothelium. Moreover, deletion of endothelial PIEZO1 was recently found to suppress activation of Notch1 target genes in hepatic microvascular endothelium. Here, because of the liver’s dominant role in lipid regulation, we set out to test the novel hypothesis that endothelial PIEZO1 regulates hepatic lipid homeostasis. We performed bulk RNA sequencing on PIEZO1-deleted mice exposed to chow and high fat diets. Our transcriptomics analysis reveal unexpected relevance to lipid and glucose homeostasis.

Project description:Although cells of the immune system experience force and pressure throughout their lifecycle, almost nothing is known about how these mechanical processes regulate the immune response. Immune cells in highly mechanical organs, such as the lung, are constantly exposed to tonic and dynamically changing mechanical cues. Here using reverse genetics, we show that myeloid cells respond to force and alterations in cyclical hydrostatic pressure (CHP) via the mechanosensory ion channel (MSIC) PIEZO1. Unbiased RNA-sequencing from macrophages subjected to CHP reveals a striking state of proinflammatory reprogramming. We report a novel mechanosensory-immune signaling circuit which PIEZO1 initiates in response to CHP, activating c-JUN, upregulating Endothelin-1 (EDN1), and stabilizing HIF1α to facilitate a prolonged program of proinflammatory mediators. Using mice conditionally deficient of PIEZO1 in myeloid cells, and cellular depletion assays, we show infiltrating monocytes respond to cyclical force to recruit neutrophils and clear pulmonary Pseudomonas aeruginosa infection. Furthermore, myeloid PIEZO1 also drove lung pathology in a mouse model of pulmonary fibrosis. Our results demonstrate a novel environmental sensory axis that myeloid cells recognize to mount an inflammatory response, and is the first report showing a physiological role for PIEZO1 and mechanosensation in immunity.

Project description:The mechanisms by which physical forces regulate cells to determine complexities of vascular structure and function are enigmatic. Here we show the role the ion channel subunit Piezo1 (FAM38A). Disruption of mouse Piezo1 gene disturbed vascular development and was embryonic lethal within days of the heart beating to cause blood flow. Importance of Piezo channels as sensors of blood flow was indicated by Piezo1 dependence of shear stress-evoked ionic current and calcium influx in endothelial cells and the ability of exogenous Piezo1 to confer shear stress sensitivity on cells that otherwise lacked. Downstream of this calcium influx was proteoase activity and spatial organization of endothelial cells to the polarity of the applied force. Without Piezo1, normal endothelial cell organization was lacking. The data suggest Piezo1 channels as pivotal integrators of vascular architacture with physiological mechanical force.