Piezo regulates epithelial topology and promotes precision in organ size control

Mechanosensitive Piezo channels regulate cell division through calcium-mediated activation of ERK signaling or activate Rho signaling to mediate cell extrusion and cell death. However, systems-level functions of Piezo in regulating organogenesis remain poorly understood. Here, we demonstrate that Piezo controls epithelial cell topology to ensure precise organ growth through the integration of live imaging experiments with pharmacological and genetic perturbations and computational modeling. Notably, knockout or knockdown of Piezo led to bilateral asymmetry in wing phenotypes. While pharmacological activation of Piezo stimulated an increase in the frequency of spikes in cytosolic Ca2+, we discovered that Piezo overexpression counterintuitively reduces Ca2+ signaling dynamics. Knockdown of Piezo inhibited proliferation and decreased apoptosis, resulting in an overall increase in epithelial overcrowding. In contrast, either genetic overexpression or pharmacological activation of Piezo increased cell proliferation and cell removal through basal extrusion. Surprisingly, Piezo overexpression increased the hexagonality of cellular topology. To test whether Piezo regulates cell topology, we formulated computational simulations to investigate how expression levels of Piezo protein regulate cell proliferation and apoptosis through modulation of the cut-off tension required for Piezo channel activation. Quantitative analysis validated computational simulation predictions of how perturbations to Piezo impacted epithelial topology. Overall, our findings demonstrate that Piezo promotes robustness in regulating epithelial topology and is necessary for precise organ size control.

[1]  J. D. de Celis,et al.  RNAi screen in the Drosophila wing of genes encoding proteins related to cytoskeleton organization and cell division. , 2023, Developmental biology.

[2]  C. Eloy,et al.  Growth anisotropy of the extracellular matrix shapes a developing organ , 2023, Nature Communications.

[3]  S. Shvartsman,et al.  Stochastic phenotypes in RAS-dependent developmental diseases , 2023, Current Biology.

[4]  Y. Bi,et al.  Immunoregulatory Role of the Mechanosensitive Ion Channel Piezo1 in Inflammation and Cancer , 2022, Molecules.

[5]  Jeremiah J. Zartman,et al.  Balancing competing effects of tissue growth and cytoskeletal regulation during Drosophila wing disc development , 2022, bioRxiv.

[6]  X. Nie,et al.  Piezo channels for skeletal development and homeostasis: Insights from mouse genetic models. , 2022, Differentiation; research in biological diversity.

[7]  W. Wood,et al.  Piezo acts as a molecular brake on wound closure to ensure effective inflammation and maintenance of epithelial integrity , 2022, Current Biology.

[8]  T. Malm,et al.  The State of the Art of Piezo1 Channels in Skeletal Muscle Regeneration , 2022, International journal of molecular sciences.

[9]  S. Megason,et al.  Hydrostatic pressure as a driver of cell and tissue morphogenesis. , 2022, Seminars in cell & developmental biology.

[10]  B. Xiao,et al.  Tethering Piezo channels to the actin cytoskeleton for mechanogating via the cadherin-β-catenin mechanotransduction complex. , 2022, Cell reports.

[11]  B. Gumbiner,et al.  The roles of distinct Ca2+ signaling mediated by Piezo and inositol triphosphate receptor (IP3R) in the remodeling of E-cadherin during cell dissemination , 2021, bioRxiv.

[12]  J. Grosshans,et al.  Ion Channels in Epithelial Dynamics and Morphogenesis , 2021, Cells.

[13]  C. Nelson,et al.  Dynamic changes in epithelial cell packing during tissue morphogenesis , 2021, Current Biology.

[14]  Luis M. Escudero,et al.  Mechanics and self-organization in tissue development. , 2021, Seminars in cell & developmental biology.

[15]  Sophie Theis,et al.  Tyssue: an epithelium simulation library , 2021, J. Open Source Softw..

[16]  Harold F. Gómez,et al.  3D cell neighbour dynamics in growing pseudostratified epithelia , 2021, bioRxiv.

[17]  Xiaohua Xu,et al.  Piezo1 impairs hepatocellular tumor growth via deregulation of the MAPK-mediated YAP signaling pathway. , 2021, Cell calcium.

[18]  J. Seo,et al.  Multisensory interactions regulate feeding behavior in Drosophila , 2021, Proceedings of the National Academy of Sciences.

[19]  Xin Wang,et al.  Piezo type mechanosensitive ion channel component 1 facilitates gastric cancer omentum metastasis , 2021, Journal of cellular and molecular medicine.

[20]  M. von Lindern,et al.  Mechanical Stress Induces Ca2+-Dependent Signal Transduction in Erythroblasts and Modulates Erythropoiesis , 2021, International journal of molecular sciences.

[21]  Pavel A. Brodskiy,et al.  MAPPER: A new image analysis pipeline unmasks differential regulation of Drosophila wing features , 2020, bioRxiv.

[22]  Y. Jan,et al.  Visceral Mechano-sensing Neurons Control Drosophila Feeding by Using Piezo as a Sensor , 2020, Neuron.

[23]  Jiae Lee,et al.  Dissemination of RasV12-transformed cells requires the mechanosensitive channel Piezo , 2020, Nature Communications.

[24]  A. Alaimo,et al.  Mechanosensitive Piezo Channels in Cancer: Focus on altered Calcium Signaling in Cancer Cells and in Tumor Progression , 2020, Cancers.

[25]  Nilay Kumar,et al.  Epithelial organ shape is generated by patterned actomyosin contractility and maintained by the extracellular matrix , 2020, bioRxiv.

[26]  R. Kay,et al.  Pressure sensing through Piezo channels controls whether cells migrate with blebs or pseudopods , 2020, Proceedings of the National Academy of Sciences.

[27]  Benoit Aigouy,et al.  EPySeg: a coding-free solution for automated segmentation of epithelia using deep learning , 2020, bioRxiv.

[28]  Wesley M. Botello-Smith,et al.  A mechanism for the activation of the mechanosensitive Piezo1 channel by the small molecule Yoda1 , 2019, Nature Communications.

[29]  H. Petrie,et al.  Dynamic changes in epithelial cell morphology control thymic organ size during atrophy and regeneration , 2019, Nature Communications.

[30]  A. Kalli,et al.  Force Sensing by Piezo Channels in Cardiovascular Health and Disease , 2019, Arteriosclerosis, thrombosis, and vascular biology.

[31]  M. Galko,et al.  Growth Factor Signaling Regulates Mechanical Nociception in Flies and Vertebrates , 2019, The Journal of Neuroscience.

[32]  Johannes L. Schönberger,et al.  SciPy 1.0: fundamental algorithms for scientific computing in Python , 2019, Nature Methods.

[33]  Joel Nothman,et al.  SciPy 1.0-Fundamental Algorithms for Scientific Computing in Python , 2019, ArXiv.

[34]  F. Davis,et al.  An element for development: Calcium signaling in mammalian reproduction and development. , 2019, Biochimica et biophysica acta. Molecular cell research.

[35]  J. de Rooij,et al.  Faculty Opinions recommendation of Mechanical regulation of stem-cell differentiation by the stretch-activated Piezo channel. , 2019, Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature.

[36]  Fisun Hamaratoglu,et al.  Cell elimination strategies upon identity switch via modulation of apterous in Drosophila wing disc , 2019, bioRxiv.

[37]  Jeremiah J. Zartman,et al.  From spikes to intercellular waves: Tuning intercellular calcium signaling dynamics modulates organ size control , 2019, bioRxiv.

[38]  Ajit Singh,et al.  Machine Learning With Python , 2019 .

[39]  Fernando Ontiveros,et al.  Microfluidics on the fly: Inexpensive rapid fabrication of thermally laminated microfluidic devices for live imaging and multimodal perturbations of multicellular systems. , 2019, Biomicrofluidics.

[40]  Jeremiah J Zartman,et al.  Tools to reverse-engineer multicellular systems: case studies using the fruit fly , 2019, Journal of Biological Engineering.

[41]  Katherine L. Thompson-Peer,et al.  The Mechanosensitive Ion Channel Piezo Inhibits Axon Regeneration , 2019, Neuron.

[42]  Eftychios A Pnevmatikakis,et al.  Analysis pipelines for calcium imaging data , 2019, Current Opinion in Neurobiology.

[43]  T. Liu,et al.  Piezo-like Gene Regulates Locomotion in Drosophila Larvae. , 2019, Cell reports.

[44]  Pavel A. Brodskiy,et al.  Decoding Calcium Signaling Dynamics during Drosophila Wing Disc Development. , 2019, Biophysical journal.

[45]  J. Vermot,et al.  Mechanically activated piezo channels modulate outflow tract valve development through the Yap1 and Klf2-Notch signaling axis , 2019, bioRxiv.

[46]  Pengcheng Zhou,et al.  CaImAn an open source tool for scalable calcium imaging data analysis , 2019, eLife.

[47]  C. Hui,et al.  A Feedforward Mechanism Mediated by Mechanosensitive Ion Channel PIEZO1 and Tissue Mechanics Promotes Glioma Aggression , 2018, Neuron.

[48]  A. Malik,et al.  Mechanosensing Piezo channels in tissue homeostasis including their role in lungs , 2018, Pulmonary circulation.

[49]  Pavel A. Brodskiy,et al.  Calcium as a signal integrator in developing epithelial tissues , 2018, Physical biology.

[50]  F. Rubio-Moscardo,et al.  Piezo2 channel regulates RhoA and actin cytoskeleton to promote cell mechanobiological responses , 2018, Proceedings of the National Academy of Sciences.

[51]  A. Chesler,et al.  Portraits of a pressure sensor , 2018, eLife.

[52]  M. Shono,et al.  Piezo type mechanosensitive ion channel component 1 functions as a regulator of the cell fate determination of mesenchymal stem cells , 2017, Scientific Reports.

[53]  R. MacKinnon,et al.  Structure-based membrane dome mechanism for Piezo mechanosensitivity , 2017, eLife.

[54]  B. Xiao,et al.  A protein interaction mechanism for suppressing the mechanosensitive Piezo channels , 2017, Nature Communications.

[55]  Natalie A. Dye,et al.  Cell dynamics underlying oriented growth of the Drosophila wing imaginal disc , 2017, Development.

[56]  Fergus R. Cooper,et al.  Mechanocellular models of epithelial morphogenesis , 2017, Philosophical Transactions of the Royal Society B: Biological Sciences.

[57]  Jörn Dunkel,et al.  Actomyosin-based tissue folding requires a multicellular myosin gradient , 2017, Development.

[58]  K. Basler,et al.  Forces controlling organ growth and size , 2017, Mechanisms of Development.

[59]  E. Piddini,et al.  Epithelial Homeostasis: A Piezo of the Puzzle , 2017, Current Biology.

[60]  J. Rosenblatt,et al.  Mechanical stretch triggers rapid epithelial cell division through Piezo1 , 2017, Nature.

[61]  Guillermo A. Gomez,et al.  Measurement of Mechanical Tension at Cell-cell Junctions Using Two-photon Laser Ablation. , 2016, Bio-protocol.

[62]  B. Shraiman,et al.  Differential growth triggers mechanical feedback that elevates Hippo signaling , 2016, Proceedings of the National Academy of Sciences.

[63]  Jochen Guck,et al.  Mechanosensing is critical for axon growth in the developing brain , 2016, Nature Neuroscience.

[64]  Thomas Lecuit,et al.  Mechanical Forces and Growth in Animal Tissues. , 2016, Cold Spring Harbor perspectives in biology.

[65]  Keiji Naruse,et al.  Mechanosensitive ion channels , 2016 .

[66]  Pavel A. Brodskiy,et al.  Patterning of wound-induced intercellular Ca2+ flashes in a developing epithelium , 2015, Physical biology.

[67]  Thomas Mangeat,et al.  Apico-basal forces exerted by apoptotic cells drive epithelium folding , 2015, Nature.

[68]  Jeremiah J Zartman,et al.  Sizing it up: the mechanical feedback hypothesis of organ growth regulation. , 2014, Seminars in cell & developmental biology.

[69]  N. Yuldasheva,et al.  Piezo1 integration of vascular architecture with physiological force , 2014, Nature.

[70]  Shu Chien,et al.  Piezo1, a mechanically activated ion channel, is required for vascular development in mice , 2014, Proceedings of the National Academy of Sciences.

[71]  G. Morin,et al.  The Drosophila effector caspase Dcp-1 regulates mitochondrial dynamics and autophagic flux via SesB , 2014, The Journal of cell biology.

[72]  Lennart Kester,et al.  Differential proliferation rates generate patterns of mechanical tension that orient tissue growth , 2013, The EMBO journal.

[73]  Thomas Lecuit,et al.  A global pattern of mechanical stress polarizes cell divisions and cell shape in the growing Drosophila wing disc , 2013, Development.

[74]  Stefan R. Pulver,et al.  Ultra-sensitive fluorescent proteins for imaging neuronal activity , 2013, Nature.

[75]  Johannes E. Schindelin,et al.  Fiji: an open-source platform for biological-image analysis , 2012, Nature Methods.

[76]  Chi-Bin Chien,et al.  Crowding induces live cell extrusion to maintain homeostatic cell numbers in epithelia , 2012, Nature.

[77]  Andy Weyer,et al.  Faculty Opinions recommendation of Piezo proteins are pore-forming subunits of mechanically activated channels. , 2012 .

[78]  A. Patapoutian,et al.  The role of Drosophila Piezo in mechanical nociception , 2011, Nature.

[79]  F. Sachs,et al.  The mechanosensitive ion channel Piezo1 is inhibited by the peptide GsMTx4. , 2011, Biochemistry.

[80]  M. Gibson,et al.  Interkinetic Nuclear Migration Is a Broadly Conserved Feature of Cell Division in Pseudostratified Epithelia , 2011, Current Biology.

[81]  Radhika Nagpal,et al.  Control of the Mitotic Cleavage Plane by Local Epithelial Topology , 2011, Cell.

[82]  Gaël Varoquaux,et al.  Scikit-learn: Machine Learning in Python , 2011, J. Mach. Learn. Res..

[83]  B. Graveley The developmental transcriptome of Drosophila melanogaster , 2010, Nature.

[84]  Manuela Schmidt,et al.  Piezo1 and Piezo2 Are Essential Components of Distinct Mechanically Activated Cation Channels , 2010, Science.

[85]  Frank Jülicher,et al.  The Influence of Cell Mechanics, Cell-Cell Interactions, and Proliferation on Epithelial Packing , 2007, Current Biology.

[86]  John D. Hunter,et al.  Matplotlib: A 2D Graphics Environment , 2007, Computing in Science & Engineering.

[87]  N. Perrimon,et al.  The emergence of geometric order in proliferating metazoan epithelia , 2006, Nature.

[88]  R. Nusse,et al.  Wingless signaling modulates cadherin-mediated cell adhesion in Drosophila imaginal disc cells , 2006, Journal of Cell Science.

[89]  D. Ingber,et al.  Cellular mechanotransduction: putting all the pieces together again , 2006, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[90]  Tomoyuki Yamada,et al.  dsCheck: highly sensitive off-target search software for double-stranded RNA-mediated RNA interference , 2005, Nucleic Acids Res..

[91]  M. Berridge,et al.  The versatility and universality of calcium signalling , 2000, Nature Reviews Molecular Cell Biology.

[92]  A. Garcı́a-Bellido The engrailed story. , 1998, Genetics.

[93]  H. Steller,et al.  DCP-1, a Drosophila Cell Death Protease Essential for Development , 1997, Science.

[94]  A Goldbeter,et al.  One-pool model for Ca2+ oscillations involving Ca2+ and inositol 1,4,5-trisphosphate as co-agonists for Ca2+ release. , 1993, Cell calcium.

[95]  Gáspár Jékely,et al.  Content-aware image restoration for electron microscopy. , 2019, Methods in cell biology.

[96]  M. Manning,et al.  Cell volume changes contribute to epithelial morphogenesis in zebrafish Kupffer’s vesicle , 2018, eLife.

[97]  Skipper Seabold,et al.  Statsmodels: Econometric and Statistical Modeling with Python , 2010, SciPy.

[98]  M. Gibson,et al.  Cell topology, geometry, and morphogenesis in proliferating epithelia. , 2009, Current topics in developmental biology.

[99]  Christopher D. Brown,et al.  Identification of Functional Elements and Regulatory Circuits by Drosophila modENCODE , 2011 .