Your search keyword '"Charras, Guillaume"' showing total 11 results

1. Polarization of Myosin II Refines Tissue Material Properties to Buffer Mechanical Stress.

Author

Duda M, Kirkland NJ, Khalilgharibi N, Tozluoglu M, Yuen AC, Carpi N, Bove A, Piel M, Charras G, Baum B, and Mao Y

Subjects

Actomyosin metabolism, Animals, Cell Shape physiology, Epithelium metabolism, Cytoskeletal Proteins metabolism, Morphogenesis physiology, Myosin Type II metabolism, Stress, Mechanical

Abstract

As tissues develop, they are subjected to a variety of mechanical forces. Some of these forces are instrumental in the development of tissues, while others can result in tissue damage. Despite our extensive understanding of force-guided morphogenesis, we have only a limited understanding of how tissues prevent further morphogenesis once the shape is determined after development. Here, through the development of a tissue-stretching device, we uncover a mechanosensitive pathway that regulates tissue responses to mechanical stress through the polarization of actomyosin across the tissue. We show that stretch induces the formation of linear multicellular actomyosin cables, which depend on Diaphanous for their nucleation. These stiffen the epithelium, limiting further changes in shape, and prevent fractures from propagating across the tissue. Overall, this mechanism of force-induced changes in tissue mechanical properties provides a general model of force buffering that serves to preserve the shape of tissues under conditions of mechanical stress., (Copyright © 2018 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2019

2. Tissue stiffening coordinates morphogenesis by triggering collective cell migration in vivo.

Author

Barriga EH, Franze K, Charras G, and Mayor R

Subjects

Animals, Epithelial-Mesenchymal Transition, Extracellular Matrix, Female, Gastrulation, Hardness, Integrins metabolism, Mesoderm cytology, Mesoderm embryology, Cell Movement, Mechanotransduction, Cellular, Mesoderm physiology, Morphogenesis, Neural Crest cytology, Xenopus laevis embryology

Abstract

Collective cell migration is essential for morphogenesis, tissue remodelling and cancer invasion. In vivo, groups of cells move in an orchestrated way through tissues. This movement involves mechanical as well as molecular interactions between cells and their environment. While the role of molecular signals in collective cell migration is comparatively well understood, how tissue mechanics influence collective cell migration in vivo remains unknown. Here we investigated the importance of mechanical cues in the collective migration of the Xenopus laevis neural crest cells, an embryonic cell population whose migratory behaviour has been likened to cancer invasion. We found that, during morphogenesis, the head mesoderm underlying the cephalic neural crest stiffens. This stiffening initiates an epithelial-to-mesenchymal transition in neural crest cells and triggers their collective migration. To detect changes in their mechanical environment, neural crest cells use mechanosensation mediated by the integrin-vinculin-talin complex. By performing mechanical and molecular manipulations, we show that mesoderm stiffening is necessary and sufficient to trigger neural crest migration. Finally, we demonstrate that convergent extension of the mesoderm, which starts during gastrulation, leads to increased mesoderm stiffness by increasing the cell density underneath the neural crest. These results show that convergent extension of the mesoderm has a role as a mechanical coordinator of morphogenesis, and reveal a link between two apparently unconnected processes-gastrulation and neural crest migration-via changes in tissue mechanics. Overall, we demonstrate that changes in substrate stiffness can trigger collective cell migration by promoting epithelial-to-mesenchymal transition in vivo. More broadly, our results raise the idea that tissue mechanics combines with molecular effectors to coordinate morphogenesis.

Published

2018

3. Emergence of homeostatic epithelial packing and stress dissipation through divisions oriented along the long cell axis

Author

Wyatt, Tom P. J., Harris, Andrew R., Lam, Maxine, Cheng, Qian, Bellis, Julien, Dimitracopoulos, Andrea, Kabla, Alexandre J., Charras, Guillaume T., and Baum, Buzz

Published

2015

4. Curling of epithelial monolayers reveals coupling between active bending and tissue tension

Author

Ambrosini, Arnaud, Rayer, Mégane, Monier, Bruno, Fouchard, Jonathan, Wyatt, Tom, Proag, Amsha, Lisica, Ana, Khalilgharibi, Nargess, RECHO, Pierre, Suzanne, Magali, Kabla, Alexandre, Charras, Guillaume, Laboratoire Interdisciplinaire de Physique [Saint Martin d’Hères] (LIPhy ), Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), University College of London [London] (UCL), Centre de Biologie Intégrative (CBI), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS), Laboratoire de l'Informatique du Parallélisme (LIP), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-Centre National de la Recherche Scientifique (CNRS), University of Cambridge, Department of Engineering (CUED), University of Cambridge [UK] (CAM), Centre National de la Recherche Scientifique (CNRS)-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-École normale supérieure - Lyon (ENS Lyon), Université de Toulouse (UT)-Université de Toulouse (UT)-Centre National de la Recherche Scientifique (CNRS), and École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL)

Subjects

Materials science, [PHYS.PHYS.PHYS-BIO-PH]Physics [physics]/Physics [physics]/Biological Physics [physics.bio-ph], [SDV]Life Sciences [q-bio], Morphogenesis, 02 engineering and technology, Bending, Curvature, 01 natural sciences, Epithelium, Cell Line, Curling, 03 medical and health sciences, Dogs, 0103 physical sciences, Myosin, Monolayer, Cell Adhesion, Animals, 010306 general physics, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Tension (physics), food and beverages, Biological Sciences, 021001 nanoscience & nanotechnology, Elasticity, Biomechanical Phenomena, Coupling (electronics), Biophysics, Stress, Mechanical, 0210 nano-technology

Abstract

Epithelial monolayers are two-dimensional cell sheets which compartmentalise the body and organs of multi-cellular organisms. Their morphogenesis during development or pathology results from patterned endogenous and exogenous forces and their interplay with tissue mechanical properties. In particular, bending of epithelia is thought to results from active torques generated by the polarization of myosin motors along their apico-basal axis. However, the contribution of these out-of-plane forces to morphogenesis remains challenging to evaluate because of the lack of direct mechanical measurement. Here, we use epithelial curling to characterize the out-of-plane mechan ics of epithelial monolayers. We find that curls of high curvature form spontaneously at the free edge of epithelial monolayers devoid of substrate in vivo and in vitro. Curling originates from an enrichment of myosin in the basal domain that generates an active spontaneous curvature. By measuring the force necessary to flatten curls, we can then estimate the active torques and the bending modulus of the tissue. Finally, we show that the extent of curling is controlled by the interplay between in-plane and out-of-plane stresses in the monolayer. Such mechanical coupling implies an unexpected role for in-plane stresses in shaping epithelia during morphogenesis.

Published

2020

5. Formation of adherens junctions leads to the emergence of a tissue-level tension in epithelial monolayers

Author

Harris, Andrew R., Daeden, Alicia, and Charras, Guillaume T.

Subjects

Keratin-18, Desmosomes, Adherens Junctions, Cadherins, Microscopy, Atomic Force, Actins, Collagen Type I, Epithelium, Cell Line, Atomic force microscopy, Dogs, Tension, Morphogenesis, Cell Adhesion, Animals, Elasticity Imaging Techniques, Humans, Surface Tension, Gels, Cytoskeleton, Research Article

Abstract

Adherens junctions and desmosomes integrate the cytoskeletons of adjacent cells into a mechanical syncitium. In doing so, intercellular junctions endow tissues with the strength needed to withstand the mechanical stresses encountered in normal physiology and to coordinate tension during morphogenesis. Though much is known about the biological mechanisms underlying junction formation, little is known about how tissue-scale mechanical properties are established. Here, we use deep atomic force microscopy (AFM) indentation to measure the apparent stiffness of epithelial monolayers reforming from dissociated cells and examine which cellular processes give rise to tissue-scale mechanics. We show that the formation of intercellular junctions coincided with an increase in the apparent stiffness of reforming monolayers that reflected the generation of a tissue-level tension. Tension rapidly increased, reaching a maximum after 150 min, before settling to a lower level over the next 3 h as monolayers established homeostasis. The emergence of tissue tension correlated with the formation of adherens junctions but not desmosomes. As a consequence, inhibition of any of the molecular mechanisms participating in adherens junction initiation, remodelling and maturation significantly impeded the emergence of tissue-level tension in monolayers.

Published

2014

6. Characterizing the mechanics of cultured cell monolayers.

Author

Harris, Andrew R., Peter, Loic, Bellis, Julien, Baum, Buzz, Kabla, Alexandre J., and Charras, Guillaume T.

Subjects

CELLULAR mechanics, TISSUE mechanics, CYTOPLASMIC filaments, MONOMOLECULAR films, MORPHOGENESIS, CYTOSKELETON, MYOSIN

Abstract

One-cell-thick monolayers are the simplest tissues in multicellular organisms, yet they fulfill critical roles in development and normal physiology. In early development, embryonic morphogenesis results largely from monolayer rearrangement and deformation due to internally generated forces. Later, monolayers act as physical barriers separating the internal environment from the exterior and must withstand externally applied forces. Though resisting and generating mechanical forces is an essential part of monolayer function, simple experimental methods to characterize monolayer mechanical properties are lacking. Here, we describe a system for tensile testing of freely suspended cultured monolayers that enables the examination of their mechanical behavior at multi-, uni-, and subcellular scales. Using this system, we provide measurements of monolayer elasticity and show that this is two orders of magnitude larger than the elasticity of their isolated cellular components. Monolayers could withstand more than a doubling in length before failing through rupture of intercellular junctions. Measurement of stress at fracture enabled a first estimation of the average force needed to separate cells within truly mature monolayers, approximately ninefold larger than measured in pairs of isolated cells. As in single cells, monolayer mechanical properties were strongly dependent on the integrity of the actin cytoskeleton, myosin, and intercellular adhesions interfacing adjacent cells. High magnification imaging revealed that keratin filaments became progressively stretched during extension, suggesting they participate in monolayer mechanics. This multiscale study of monolayer response to deformation enabled by our device provides the first quantitative investigation of the link between monolayer biology and mechanics. [ABSTRACT FROM AUTHOR]

Published

2012

7. Actin cortex mechanics and cellular morphogenesis

Author

Salbreux, Guillaume, Charras, Guillaume, and Paluch, Ewa

Subjects

*ACTIN, *BIOMECHANICS, *CELL morphology, *MORPHOGENESIS, *CELL membranes, *CELL physiology, *CYTOKINESIS

Abstract

The cortex is a thin, crosslinked actin network lying immediately beneath the plasma membrane of animal cells. Myosin motors exert contractile forces in the meshwork. Because the cortex is attached to the cell membrane, it plays a central role in cell shape control. The proteic constituents of the cortex undergo rapid turnover, making the cortex both mechanically rigid and highly plastic, two properties essential to its function. The cortex has recently attracted increasing attention and its functions in cellular processes such as cytokinesis, cell migration, and embryogenesis are progressively being dissected. In this review, we summarize current knowledge on the structural organization, composition, and mechanics of the actin cortex, focusing on the link between molecular processes and macroscopic physical properties. We also highlight consequences of cortex dysfunction in disease. [ABSTRACT FROM AUTHOR]

Published

2012

8. Reassembly of contractile actin cortex in cell blebs.

Author

Charras, Guillaume T., Hu, Chi-Kuo, Coughlin, Margaret, and Mitchison, Timothy J.

Subjects

*ACTIN, *MORPHOGENESIS, *CYTOKINESIS, *CELL morphology, *CELL membranes

Abstract

Contractile actin cortex is involved in cell morphogenesis, movement, and cytokinesis, but its organization and assembly are poorly understood. During blebbing, the membrane detaches from the cortex and inflates. As expansion ceases, contractile cortex reassembles under the membrane and drives bleb retraction. This cycle enabled us to measure the temporal sequence of protein recruitment to the membrane during cortex reassembly and to explore dependency relationships. Expanding blebs were devoid of actin, but proteins of the erythrocytic submembranous cytoskeleton were present. When expansion ceased, ezrin was recruited to the membrane first, followed by actin, actin-bundling proteins, and, finally, contractile proteins. Complete assembly of the contractile cortex, which was organized into a cage-like mesh of filaments, took ∼30 s. Cytochalasin D blocked recruitment of actin and α-actinin, but had no effect on membrane association of ankyrin B and ezrin. Ezrin played no role in actin nucleation, but was essential for tethering the membrane to the cortex. The Rho pathway was important for cortex assembly in blebs. [ABSTRACT FROM AUTHOR]

Published

2006

9. How mechanics orchestrate morphogenesis: Mesodermal stiffening triggers neural crest migration in vivo.

Author

Barriga, Elias, Franze, Kristian, Charras, Guillaume, and Mayor, Roberto

Subjects

*MORPHOGENESIS, *BIOMECHANICS, *TISSUE mechanics, *NEURAL crest, *CELL migration

Published

2017

10. Cellular Control of Cortical Actin Nucleation.

Author

Bovellan, Miia, Romeo, Yves, Biro, Maté, Boden, Annett, Chugh, Priyamvada, Yonis, Amina, Vaghela, Malti, Fritzsche, Marco, Moulding, Dale, Thorogate, Richard, Jégou, Antoine, Thrasher, Adrian J., Romet-Lemonne, Guillaume, Roux, Philippe P., Paluch, Ewa K., and Charras, Guillaume

Subjects

*MICROFILAMENT proteins, *NUCLEATION, *CEREBRAL cortex, *CELL membranes, *MORPHOGENESIS, *METASTASIS

Abstract

The contractile actin cortex is a thin layer of actin, myosin, and actin-binding proteins that subtends the membrane of animal cells. The cortex is the main determinant of cell shape and plays a fundamental role in cell division [1-3], migration [4], and tissue morphogenesis [5]. For example, cortex contractility plays a crucial role in amoeboid migration of metastatic cells [6] and during division, where its misregulation can lead to aneuploidy [7]. Despite its importance, our knowledge of the cortex is poor, and even the proteins nucleating it remain unknown, though a number of candidates have been proposed based on indirect evidence [8-15]. Here, we used two independent approaches to identify cortical actin nucleators: a proteomic analysis using cortex-rich isolated blebs, and a localization/small hairpin RNA (shRNA) screen searching for phenotypes with a weakened cortex or altered contractility. This unbiased study revealed that two proteins generated the majority of cortical actin: the formin mDia1 and the Arp2/3 complex. Each nucleator contributed a similar amount of F-actin to the cortex but had very different accumulation kinetics. Electron microscopy examination revealed that each nucleator affected cortical network architecture differently. mDia1 depletion led to failure in division, but Arp2/3 depletion did not. Interestingly, despite not affecting division on its own, Arp2/3 inhibition potentiated the effect of mDia1 depletion. Our findings indicate that the bulk of the actin cortex is nucleated by mDia1 and Arp2/3 and suggest a mechanism for rapid fine-tuning of cortex structure and mechanics by adjusting the relative contribution of each nucleator. • The Arp2/3 complex and the formin mDia1 nucleate the bulk of cortical F-actin • Nucleator depletion alters the cortex ultrastructural organization • Actin nucleated by mDia1 accumulates faster than actin nucleated by Arp2/3 • mDia1 depletion leads to mitosis failure, an effect potentiated by Arp2/3 inhibition. Bovellan et al. show that two actin nucleators, the formin mDia1 and the Arp2/3 complex, generate the bulk of the submembranous cortical F-actin. These nucleators have very different actin accumulation kinetics and play distinct roles in cortical actin organization, and their depletion differentially affects progression through the cell cycle. [ABSTRACT FROM AUTHOR]

Published

2014

11. In vivo collective cell migration requires an LPAR2-dependent increase in tissue fluidity.

Author

Sei Kuriyama, Theveneau, Eric, Benedetto, Alexandre, Parsons, Maddy, Masamitsu Tanaka, Charras, Guillaume, Mayor, Roberto, and Kabla, Alexandre

Subjects

*CELL migration, *MORPHOGENESIS, *NEURAL crest, *LYSOPHOSPHOLIPIDS, *CELL adhesion, *CANCER cells

Abstract

Collective cell migration (CCM) and epithelial-mesenchymal transition (EMT) are common to cancer and morphogenesis, and are often considered to be mutually exclusive in spite of the fact that many cancer and embryonic cells that have gone through EMT still cooperate to migrate collectively. Here we use neural crest (NC) cells to address the question of how cells that have down-regulated cell-cell adhesions can migrate collectively. NC cell dissociation relies on a qualitative and quantitative change of the cadherin repertoire. We found that the level of cell-cell adhesion is precisely regulated by internalization of N-cadherin downstream of lysophosphatidic acid (LPA) receptor 2. Rather than promoting the generation of single, fully mesenchymal cells, this reduction of membrane N-cadherin only triggers a partial mesenchymal phenotype. This intermediate phenotype is characterized by an increase in tissue fluidity akin to a solid-like-to-fluid-like transition. This change of plasticity allows cells to migrate under physical constraints without abolishing cell cooperation required for collectiveness. [ABSTRACT FROM AUTHOR]

Published

2014