Your search keyword '"Dumortier JG"' showing total 9 results

1. Inverse blebs operate as hydraulic pumps during mouse blastocyst formation.

Author

Schliffka MF, Dumortier JG, Pelzer D, Mukherjee A, and Maître JL

Subjects

Animals, Mice, Cell Adhesion, Actomyosin metabolism, Female, Cell Communication, Blastocyst metabolism, Blastocyst cytology, Embryonic Development

Abstract

During preimplantation development, mouse embryos form a fluid-filled lumen. Pressurized fluid fractures cell-cell contacts and accumulates into pockets, which coarsen into a single lumen. How the embryo controls intercellular fluid movement during coarsening is unknown. Here we report inverse blebs growing into cells at adhesive contacts. Throughout the embryo we observed hundreds of inverse blebs, each filling with intercellular fluid and retracting within a minute. Inverse blebs grow due to pressure build-up resulting from fluid accumulation and cell-cell adhesion, which locally confines fluid. Inverse blebs retract due to actomyosin contraction, practically pushing fluid within the intercellular space. Importantly, inverse blebs occur infrequently at contacts formed by multiple cells, which effectively serve as fluid sinks. Manipulation of the embryo topology reveals that without sinks inverse blebs pump fluid into one another in futile cycles. We propose that inverse blebs operate as hydraulic pumps to promote luminal coarsening, thereby constituting an instrument used by cells to control fluid movement., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Hydraulic fracturing and active coarsening position the lumen of the mouse blastocyst.

Author

Dumortier JG, Le Verge-Serandour M, Tortorelli AF, Mielke A, de Plater L, Turlier H, and Maître JL

Subjects

Animals, Hydrostatic Pressure, Mice, Blastocyst cytology, Cell Adhesion, Embryonic Development

Abstract

During mouse pre-implantation development, the formation of the blastocoel, a fluid-filled lumen, breaks the radial symmetry of the blastocyst. The factors that control the formation and positioning of this basolateral lumen remain obscure. We found that accumulation of pressurized fluid fractures cell-cell contacts into hundreds of micrometer-size lumens. These microlumens eventually discharge their volumes into a single dominant lumen, which we model as a process akin to Ostwald ripening, underlying the coarsening of foams. Using chimeric mutant embryos, we tuned the hydraulic fracturing of cell-cell contacts and steered the coarsening of microlumens, allowing us to successfully manipulate the final position of the lumen. We conclude that hydraulic fracturing of cell-cell contacts followed by contractility-directed coarsening of microlumens sets the first axis of symmetry of the mouse embryo., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

3. [A developmental checkpoint synchronizes morphogenesis and cellular differentiation in mammalian embryos].

Author

Dumortier JG and Maître JL

Subjects

Amnion embryology, Animals, Cell Cycle Checkpoints genetics, Cell Differentiation physiology, Female, Genes, Developmental physiology, Genes, Switch physiology, Humans, Mice, Morphogenesis physiology, Pregnancy, Cell Cycle Checkpoints physiology, Embryo, Mammalian cytology, Embryonic Development physiology

Published

2018

4. Early embryos kept in check.

Author

Dumortier JG and Maître JL

Subjects

Blastocyst, Embryonic Development

Published

2017

5. Analyzing In Vivo Cell Migration using Cell Transplantations and Time-lapse Imaging in Zebrafish Embryos.

Author

Giger FA, Dumortier JG, and David NB

Subjects

Animals, Gastrulation, Prospective Studies, Time-Lapse Imaging, Cell Movement physiology, Cell Transplantation, Zebrafish embryology

Abstract

Cell migration is key to many physiological and pathological conditions, including cancer metastasis. The cellular and molecular bases of cell migration have been thoroughly analyzed in vitro. However, in vivo cell migration somehow differs from in vitro migration, and has proven more difficult to analyze, being less accessible to direct observation and manipulation. This protocol uses the migration of the prospective prechordal plate in the early zebrafish embryo as a model system to study the function of candidate genes in cell migration. Prechordal plate progenitors form a group of cells which, during gastrulation, undergoes a directed migration from the embryonic organizer to the animal pole of the embryo. The proposed protocol uses cell transplantation to create mosaic embryos. This offers the combined advantages of labeling isolated cells, which is key to good imaging, and of limiting gain/loss of function effects to the observed cells, hence ensuring cell-autonomous effects. We describe here how we assessed the function of the TORC2 component Sin1 in cell migration, but the protocol can be used to analyze the function of any candidate gene in controlling cell migration in vivo.

Published

2016

6. The TORC2 component, Sin1, controls migration of anterior mesendoderm during zebrafish gastrulation.

Author

Dumortier JG and David NB

Subjects

Actins metabolism, Animals, Animals, Genetically Modified growth & development, Animals, Genetically Modified metabolism, Cell Movement, Mechanistic Target of Rapamycin Complex 2, Multiprotein Complexes antagonists & inhibitors, Oligonucleotides, Antisense metabolism, Phosphatidylinositol 3-Kinases metabolism, Protein Subunits antagonists & inhibitors, Protein Subunits metabolism, TOR Serine-Threonine Kinases antagonists & inhibitors, Time-Lapse Imaging, Zebrafish metabolism, rac1 GTP-Binding Protein genetics, rac1 GTP-Binding Protein metabolism, Gastrulation, Mesoderm metabolism, Multiprotein Complexes metabolism, TOR Serine-Threonine Kinases metabolism, Zebrafish growth & development, Zebrafish Proteins metabolism

Abstract

TORC2 is a serine-threonine kinase complex conserved through evolution that recently emerged as a new regulator of actin dynamics and cell migration. However, knockout in mice of its core components Sin1 and Rictor is embryonic lethal, which has limited in vivo analyses. Here, we analysed TORC2 function during early zebrafish development, using a morpholino-mediated loss of function of sin1. Sin1 appears required during gastrulation for migration of the prechordal plate, the anterior most mesoderm. In absence of Sin1, cells migrate both slower and less persistently, which can be correlated to a reduction in actin-rich protrusions and a randomisation of the remaining protrusions. These results demonstrate that, as established in vitro, the TORC2 component Sin1 controls actin dynamics and cell migration in vivo. We furthermore establish that Sin1 is required for protrusion formation downstream of PI3K, and is acting upstream of the GTPase Rac1, since expression of an activated form of Rac1 is sufficient to rescue sin1 loss of function.

Published

2015

7. Inhibitory signalling to the Arp2/3 complex steers cell migration.

Author

Dang I, Gorelik R, Sousa-Blin C, Derivery E, Guérin C, Linkner J, Nemethova M, Dumortier JG, Giger FA, Chipysheva TA, Ermilova VD, Vacher S, Campanacci V, Herrada I, Planson AG, Fetics S, Henriot V, David V, Oguievetskaia K, Lakisic G, Pierre F, Steffen A, Boyreau A, Peyriéras N, Rottner K, Zinn-Justin S, Cherfils J, Bièche I, Alexandrova AY, David NB, Small JV, Faix J, Blanchoin L, and Gautreau A

Subjects

Animals, Carrier Proteins genetics, Carrier Proteins metabolism, Cell Line, Dictyostelium genetics, Dictyostelium metabolism, Embryo, Nonmammalian, Gene Knockout Techniques, HEK293 Cells, Humans, Mice, Proteins genetics, Proteins metabolism, Proto-Oncogene Proteins c-akt metabolism, Zebrafish genetics, Actin-Related Protein 2-3 Complex metabolism, Cell Movement genetics, Pseudopodia genetics, Pseudopodia metabolism, Signal Transduction

Abstract

Cell migration requires the generation of branched actin networks that power the protrusion of the plasma membrane in lamellipodia. The actin-related proteins 2 and 3 (Arp2/3) complex is the molecular machine that nucleates these branched actin networks. This machine is activated at the leading edge of migrating cells by Wiskott-Aldrich syndrome protein (WASP)-family verprolin-homologous protein (WAVE, also known as SCAR). The WAVE complex is itself directly activated by the small GTPase Rac, which induces lamellipodia. However, how cells regulate the directionality of migration is poorly understood. Here we identify a new protein, Arpin, that inhibits the Arp2/3 complex in vitro, and show that Rac signalling recruits and activates Arpin at the lamellipodial tip, like WAVE. Consistently, after depletion of the inhibitory Arpin, lamellipodia protrude faster and cells migrate faster. A major role of this inhibitory circuit, however, is to control directional persistence of migration. Indeed, Arpin depletion in both mammalian cells and Dictyostelium discoideum amoeba resulted in straighter trajectories, whereas Arpin microinjection in fish keratocytes, one of the most persistent systems of cell migration, induced these cells to turn. The coexistence of the Rac-Arpin-Arp2/3 inhibitory circuit with the Rac-WAVE-Arp2/3 activatory circuit can account for this conserved role of Arpin in steering cell migration.

Published

2013

8. Collective mesendoderm migration relies on an intrinsic directionality signal transmitted through cell contacts.

Author

Dumortier JG, Martin S, Meyer D, Rosa FM, and David NB

Subjects

Animals, Cadherins metabolism, Cell Polarity physiology, Endoderm cytology, In Situ Hybridization, Mesoderm cytology, Time-Lapse Imaging, Wnt Signaling Pathway physiology, Zebrafish, Cell Movement physiology, Endoderm physiology, Mesoderm physiology, Morphogenesis physiology, Signal Transduction physiology

Abstract

Collective cell migration is key to morphogenesis, wound healing, or cancer cell migration. However, its cellular bases are just starting to be unraveled. During vertebrate gastrulation, axial mesendoderm migrates in a group, the prechordal plate, from the embryonic organizer to the animal pole. How this collective migration is achieved remains unclear. Previous work has suggested that cells migrate as individuals, with collective movement resulting from the addition of similar individual cell behavior. Through extensive analyses of cell trajectories, morphologies, and polarization in zebrafish embryos, we reveal that all prechordal plate cells show the same behavior and rely on the same signaling pathway to migrate, as expected if they do so individually. However, by using cell transplants, we demonstrate that prechordal plate migration is a true collective process, as isolated cells do not migrate toward the animal pole. They are still polarized and motile but lose directionality. Directionality is restored upon contact with the endogenous prechordal plate. This contact dependent orientation relies on E-cadherin, Wnt-PCP signaling, and Rac1. Importantly, groups of cells also need contact with the endogenous plate to orient correctly, showing an instructive role of the plate in establishing directionality. Overall, our results lead to an original model of collective migration in which directional information is contained within the moving group rather than provided by extrinsic cues, and constantly maintained in cells by contacts with their neighbors. This self-organizing model could account for collective invasion of new territories, as observed in cancer strands, without requirement for any attractant in the colonized tissue.

Published

2012

9. The Fz-Dsh planar cell polarity pathway induces oriented cell division via Mud/NuMA in Drosophila and zebrafish.

Author

Ségalen M, Johnston CA, Martin CA, Dumortier JG, Prehoda KE, David NB, Doe CQ, and Bellaïche Y

Subjects

Adaptor Proteins, Signal Transducing genetics, Animals, Cell Cycle Proteins, Cell Line, Cell Lineage, Dishevelled Proteins, Drosophila Proteins genetics, Dyneins metabolism, Embryo, Nonmammalian anatomy & histology, Embryo, Nonmammalian physiology, Frizzled Receptors genetics, Gastrulation, Guanine Nucleotide Dissociation Inhibitors genetics, Guanine Nucleotide Dissociation Inhibitors metabolism, Humans, Membrane Proteins genetics, Nerve Tissue Proteins genetics, Nuclear Matrix-Associated Proteins genetics, Phosphoproteins genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Signal Transduction physiology, Spindle Apparatus metabolism, Zebrafish Proteins genetics, Zebrafish Proteins metabolism, Adaptor Proteins, Signal Transducing metabolism, Cell Division physiology, Cell Polarity physiology, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Drosophila melanogaster physiology, Frizzled Receptors metabolism, Membrane Proteins metabolism, Nerve Tissue Proteins metabolism, Nuclear Matrix-Associated Proteins metabolism, Phosphoproteins metabolism, Zebrafish anatomy & histology, Zebrafish physiology

Abstract

The Frizzled receptor and Dishevelled effector regulate mitotic spindle orientation in both vertebrates and invertebrates, but how Dishevelled orients the mitotic spindle is unknown. Using the Drosophila S2 cell "induced polarity" system, we find that Dishevelled cortical polarity is sufficient to orient the spindle and that Dishevelled's DEP domain mediates this function. This domain binds a C-terminal domain of Mud (the Drosophila NuMA ortholog), and Mud is required for Dishevelled-mediated spindle orientation. In Drosophila, Frizzled-Dishevelled planar cell polarity (PCP) orients the sensory organ precursor (pI) spindle along the anterior-posterior axis. We show that Dishevelled and Mud colocalize at the posterior cortex of pI, Mud localization at the posterior cortex requires Dsh, and Mud loss-of-function randomizes spindle orientation. During zebrafish gastrulation, the Wnt11-Frizzled-Dishevelled PCP pathway orients spindles along the animal-vegetal axis, and reducing NuMA levels disrupts spindle orientation. Overall, we describe a Frizzled-Dishevelled-NuMA pathway that orients division from Drosophila to vertebrates., (Copyright © 2010 Elsevier Inc. All rights reserved.)

Published

2010