Global ETD Search

61	Etude du rôle de la P-cadhérine dans la migration cellulaire collective / The rôle of P-cadherin in collective cell migration Plutoni, Cédric 21 October 2014 (has links) La migration cellulaire collective (MCC) est un processus fondamental qui intervient au cours du développement, de la réparation tissulaire, de l'invasion tumorale et de la formation de métastases. Les cellules qui migrent collectivement possèdent deux types d'interaction avec leur environnement : i) l'un avec leur substrat et ii) l'autre avec les cellules voisines en migration. Deux grandes familles de protéines permettent ces interactions ainsi que la génération de forces mécaniques: i) la famille des intégrines (les récepteurs de la matrice extracellulaire) et ii) la famille des cadhérines (formant les jonctions intercellulaires). Les cadhérines classiques sont impliquées dans la formation des jonctions intercellulaires et sont les principaux acteurs de la MCC au cours du développement normal et tumoral. La transmission de force entre les cellules en migration est nécessaire à leur cohésion et à la communication des cellules entre elles. Des études récentes montrent que les cadhérines sont nécessaires à la transmission des forces au substrat. Néanmoins, les processus par lesquels les cadhérines agissent sur ses forces dans le contexte d'une MCC restent inexplorés. Nous avons identifié l'expression de la P-cadhérine comme étant associée à l'agressivité du rhabdomyosarcome de type alvéolaire (ARMS), sous type ayant le plus mauvais pronostic car très invasif. Nos données, ainsi que de récentes études qui démontrent que la P-cadhérine est impliquée dans l'agressivité des tumeurs du sein, nous ont conduits à étudier le rôle de cette cadhérine dans la migration cellulaire, processus majeur dans le développement tumoral. Nous nous sommes intéressés à l'impact de l'expression de la P-cadhérine sur la migration des myoblastes murins normaux C2C12. Pour ce faire nous utilisons un test de migration in vitro en 2D proche du test de blessure qui consiste à retirer une barrière physique induisant la migration des cellules vers l'espace libre ainsi créé. Nous avons pu monter que l'expression de la P-cadhérine dans les myoblastes C2C12 augmente les paramètres caractéristiques d'une MCC in vitro : la vitesse, la polarité, la persistance et la directionalité de la migration des cellules du front et au sein du feuillet. De plus, à l'aide de techniques microscopiques de mesure des forces nous avons montré une augmentation des forces intercellulaires allant du front vers le feuillet cellulaire au cours de la migration des cellules exprimant la P-cadhérine. Cela suggère une augmentation de la cohésion cellulaire. L'ensemble de ces résultats démontrent clairement que l'expression de la P-cadhérine induit une MCC. Nous avons aussi mesuré et cartographié les forces de traction au substrat connues pour être le moteur de la migration cellulaire. Nos données indiquent que l'expression de la P-cadhérine augmente l'anisotropie de ces forces de traction ainsi que leur intensité, et ce, uniquement au front de migration. L'expression de la P-cadhérine remodèle et stimule la dynamique des plaques focales d'adhérence à cet endroit.Afin de mieux comprendre comment la P-cadhérine modifie la dynamique des adhésions focales et augmente les forces de traction, nous avons étudié l'activité spatiotemporelle des petites protéines G de la famille Rho. Nous montrons que l'expression de la P-cadhérine active Rac1 et Cdc42 au front de migration, entrainant ainsi le remodelage et l'organisation des plaques focales d'adhérence à cet endroit. L'inhibition de Rac1 et Cdc42 bloque la MCC induite par la P-cadhérine. Pour conclure, en combinant la mesure des paramètres de migration cellulaire avec la mesure des forces mécaniques intercellulaires et au substrat, nous avons démontré que la P-cadhérine induit un comportement collectif des cellules et ce dépendamment de l'activité de Rac1 et de Cdc42. De plus nous mettons en avant l'existence de propriétés mécano-transductrices de cette cadhérine au cours de la MCC. / Collective cell migration (CCM), the coordinated movement of multiple cells that are connected by cell-cell adhesion, is a fundamental process in development, tissue repair and tumor invasion and metastasis. Cells part of a moving collective have two different types of interactions, i) one with the substratum, and ii) one with surrounding moving cells. Two protein families allow these interactions and also the generation of mechanical forces: i) typically integrins on the underlying extracellular matrix (ECM) and ii) cadherins at intercellular adhesion sites. Classical cadherins are involved in cell-cell adhesion and are major drivers of collective cell migration in embryonic development and tumorigenesis.Mechanical coupling between migratory cells may result in the production of force-dependent signals by which the cells influence each other. Moreover, whereas recent data showed that cadherin-dependent cell-cell adhesions are important for the force transmission to the ECM, how intercellular adhesion impacts on cell-ECM forces in the context of collective cell migration is totally unexplored. We identified P-cadherin expression to be associated with alveolar rhabdomyosarcoma (ARMS) aggressiveness, tumors with a bad prognosis due to the propensity for early and wide dissemination. Our data and recent findings showing that P-cadherin is associated with breast tumor invasiveness and aggressiveness, led us to investigate the role of P-cadherin in cell migration. We analyzed cell migration of normal mouse C2C12 myoblasts that express P-cadherin using a “wound-healing like assay” in which migration is analyzed after removal of a physical barrier. We observed that P-cadherin expression in C2C12 myoblasts increased the speed, polarity, persistence and directionality of migration toward the free space of both cells at the border and cells into the sheet. Using monolayer stress microscopy we showed that P-cadherin increases inter-cellular stresses and force transmission across the cell sheet. According to those observations we concluded that P-cadherin induces CCM.Traction forces exerted by the cells on the substrate are important for cell migration. Using traction force microscopy, we demonstrated that P-cadherin expression increases the traction forces anisotropy specifically at the multicellular leading row. To better understand how these mechanical signals induce CCM, we studied both the organization of the focal adhesions and the spatio-temporal activity of Rho GTPase. We showed that P-cadherin expression activates Rac1 and Cdc42 which induces extensive focal adhesions remodeling at the leading edge of cells at the leading row. Rac1 and Cdc42 inhibition impaired P-cadherin-induced CCM, focal adhesion remodeling and forces generation. In conclusion, combining a detailed measurement of the parameters of cell migration with physical measure of the intercellular stresses and traction forces, we have shown that P-cadherin promotes collective behavior of cells during migration through Rac1 and Cd42 activity. Also, those results provide evidence for mechano-transmission properties of P-cadherin during collective cell migration. P-Cadhérine Migration cellulaire collective GTPases-Rho P-Cadherin Collective cell migration Rho-GTPases
62	Sécrétion des phéochromocytomes : impact sur le développement tumoral et rôle des GTPases Rho / Secretion in pheochromocytomas : impact in tumor development and role of the Rho GTPases Croise, Pauline 09 January 2015 (has links) La sécrétion d'hormones et de neuropeptides par les cellules neuroendocrines est assurée par un processus d'exocytose, contrôlé notamment par les GTPases Rho. La compréhension des mécanismes moléculaires régulant la sécrétion neuroendocrine est primordiale. En effet, la majorité des cancers neuroendocrines tels que les phéochromocytomes, sont associés à une perturbation du processus de sécrétion. Actuellement, les mécanismes moléculaires qui induisent de telles perturbations de la sécrétion ainsi que l’impact de l’activité sécrétrice sur le développement des tumeurs neuroendocrines ne sont pas élucidés. Mes travaux de thèse proposent pour la première fois un lien fonctionnel direct entre l'activité sécrétrice des cellules et la vitesse de développement des phéochromocytomes ainsi qu’une altération des voies moléculaires impliquant certaines protéines Rho, en démontrant un lien entre la baisse de l’activité de Rac1 et Cdc42 observée dans les phéochromocytomes et la diminution de l’expression de leurs régulateurs ARHGEF1 et FARP1. / Neuroendocrine cells secrete hormones and neuropeptides through calcium-regulated exocytosis, controlled especially by Rho GTPases. Neuroendocrine tumours, such pheochromocytomas, are generally associated with a dysfunction of secretion. Although this aspect is well known by clinicians, it has never been explored at the molecular level. Moreover, the potential link between secretion and tumour development remains uninvestigated. Altogether, our results demonstrate for the first time the importance of secretion in tumor development of pheochromocytomas and an alteration of the Rho GTPase pathway, by demonstrating a link between the inhibition of Rac1 and Cdc42 activity observed in pheochromocytomas and the decrease of their activators ARHGEF1 and FARP1 expression. Phéochromocytomes Sécrétion GTPases Rho Développement tumoral Pheochromocytomas Secretion Rho GTPases Tumoral development 572.4 616.99
63	The plasticity of melanoma cell invasiveness / The plasticity of melanoma cell invasiveness Gandalovičová, Aneta January 2016 (has links) and keywords: During metastasis, cancer cells can invade the extracellular matrix using various strategies. When invading individually, they employ either the amoeboid invasion mode, during which the cell body dynamically deforms by enhanced contractility to squeeze through pores within the matrix, or protease dependent mesenchymal migration that takes advantage of the possibility to digest the surrounding matrix. Cells migrating in one mode can actively switch to the other by mesenchymal-amoeboid (MAT) or amoeboid-mesenchymal transitions (AMT). This enables escape mechanisms and considerably complicates anti-metastatic treatment. It is well known that Rho GTPases are master regulators of cytoskeleton re-arrangements and thus, unsurprisingly, play a major role in both invasion modes and can directly drive the transitions. However, upstream activation of these pathways is still largely unclear. This thesis aimed to optimize 3D conditions suitable for studying plasticity of cell invasion in vitro, establish AMT and MAT in melanoma cells based on manipulation of Rho GTPases and verify novel candidates regulating cell invasion plasticity based on previous RNA sequencing of cells before and after MAT. Last, by synthesis of published data, results from sequencing and new findings presented in this...
64	GTPases Rho e o potencial regenerativo da retina de mamíferos / Rho GTPases and the regenerative potential of the mammalian retina Carolina Beltrame Del Debbio 09 February 2010 (has links) O Corpo Ciliar (CC) é uma fonte de células tronco da retina de animais adultos, mas sua ativação permanece desconhecida. GTPases Rho são proteínas que reorganizam do citoesqueleto de actina, regulam vias de sinalização e transcrição gênica, sobrevivência celular e proliferação. Neste trabalho, investigamos a expressão das GTPases Rho nas células do CC e seu efeito na regulação do ciclo celular. As GTPases RhoA, RhoB e Rac1 foram expressas nas células do CC e sua ativação pelo ácido lisofosfatidico (LPA) aumentou a expressão dos genes progenitores retinianos Pax6 e Chx10. A inibição das proteínas por Toxina A de Clostridium difficile aumentou a proliferação no CC e potencializou o efeito proliferativo dos fatores de crescimento. A inibição especifica destas proteínas diminuiu a expressão dos transcritos de p21cip, p27kip, p16INK4a e p19INK4d e aumentou de Ki67, CiclinaA e D1. O estudo da via de Wnt indicou que Rac1 regulou os genes de componentes da degradação de -catenina e Lef1. Concluímos que a inativação das GTPases Rho induziu a proliferação das células progenitoras retinianas localizadas no CC e regulou a via de Wnt. Sua ativação induziu o perfil de célula progenitora, sugerindo uma nova ferramenta para o mecanismo de reparo retiniano. / Ciliary Body (CB) is a potential source of stem cells in the adult retina, but its activation is still unknown. Rho GTPases play a role in actin-based cytoskeleton reorganization, regulate signaling pathways and gene transcription, cell survival and cell proliferation. In this study we investigated the expression of Rho GTPases in CB cells and their role on cell cycle regulation. The GTPases RhoA, RhoB and Rac1 were present in CB cells and the activation by lysophosphatidic acid (LPA) increased the expression of the progenitor genes Pax6 and Chx10. The inhibition by Clostridium difficile Toxin A increased the proliferation of CB cells and potentiated the proliferative effect of growth factors. The specific inhibition decreased the expression of p21cip, p27kip, p16INK4a and p19INK4d as well as increased Ki67, cyclinA and D1 transcripts. The Wnt pathway study indicated that Rac1 regulated -catenin degradation genes components and Lef1. Taken together, the inactivation of Rho GTPases stimulated the proliferation of progenitor cells located in CB as well as regulate the Wnt signaling pathway. The proteins activation was correlated to progenitor profile induction. These different mechanisms may provide a potential new approach on retinal repair. Corpo Ciliar GTPases Rho Progenitores retinianos Proliferação Ciliary Body Proliferation Retinal progenitor cells Rho GTPases
65	Roles of Interphase Node Protein Nod1 and UNC-13/Munc13 Protein Ync13 during Fission Yeast Cytokinesis Zhu, Yihua January 2017 (has links) No description available. Genetics Molecular Biology Cellular Biology Cytokinesis Rho GTPases membrane trafficking Rho GEF cell integrity pathway
66	Regulation of Effector/Memory T Cell Activation by Inducible Co-Stimulator (ICOS) Franko, Jennifer Lynne January 2009 (has links) No description available. Immunology human T cells signal transduction cell adhesion co-stimulation Rho-GTPases filopodia microspikes cytosolic extensions
67	Rational targeting of Cdc42 in hematopoietic stem cell mobilization and engraftment Liu, Wei January 2011 (has links) No description available. Surgery hematopoietic stem cell mobilization engraftment Rho GTPases Cdc42 HSC niche
68	Identification and characterization of RhoGAPs involved in the regulation of invadopodia Snyder, Kyle L. January 2016 (has links) No description available. Biology Cellular Biology Molecular Biology Cancer Metastasis Invadopodia Rho GTPases RhoGAPs TCGAP CHN1 ARHGAP12
69	Coordination by Cdc42 of actin, contractility, and adhesion for melanoblast movement in mouse skin 28 February 2020 (has links) Yes / The individual molecular pathways downstream of Cdc42, Rac, and Rho GTPases are well documented, but we know surprisingly little about how these pathways are coordinated when cells move in a complex environment in vivo. In the developing embryo, melanoblasts originating from the neural crest must traverse the dermis to reach the epidermis of the skin and hair follicles. We previously established that Rac1 signals via Scar/WAVE and Arp2/3 to effect pseudopod extension and migration of melanoblasts in skin. Here we show that RhoA is redundant in the melanocyte lineage but that Cdc42 coordinates multiple motility systems independent of Rac1. Similar to Rac1 knockouts, Cdc42 null mice displayed a severe loss of pigmentation, and melanoblasts showed cell-cycle progression, migration, and cytokinesis defects. However, unlike Rac1 knockouts, Cdc42 null melanoblasts were elongated and displayed large, bulky pseudopods with dynamic actin bursts. Despite assuming an elongated shape usually associated with fast mesenchymal motility, Cdc42 knockout melanoblasts migrated slowly and inefficiently in the epidermis, with nearly static pseudopods. Although much of the basic actin machinery was intact, Cdc42 null cells lacked the ability to polarize their Golgi and coordinate motility systems for efficient movement. Loss of Cdc42 de-coupled three main systems: actin assembly via the formin FMNL2 and Arp2/3, active myosin-II localization, and integrin-based adhesion dynamics. / Cancer Research UK (to L.M.M. [A17196], R.H.I. [A19257], and S.W.G.T.) and NIH grants P01-GM103723 and P41-EB002025 (to K.M.H.). N.R.P. is supported by a Pancreatic Cancer Research Fund grant (to L.M.M.). Funding to Prof. Rottner by the Deutsche Forschungsgemeinschaft (grant RO2414/3-2). Rho GTPases Migration Actin cytoskeleton Cell motility Melanocyte Myosin Actin Adhesion Integrin Cdc42
70	The Role and Regulation of the Exchange Factor GEF-H1 in Tubular Cells Waheed, Faiza 01 September 2014 (has links) The Rho family small GTPases are key regulators of the cytoskeleton, through which they impact and control many vital cellular functions, including growth, vesicle trafficking, intercellular junctions, transepithelial transport, migration, and gene transcription. Activation of Rho GTPases is induced by Guanine Nucleotide Exchange Factors (GEFs). We have previously shown that Tumour Necrosis Factor-α (TNF), plasma membrane depolarization, and immunosuppressive drugs activate RhoA through a specific exchange factor, GEF-H1. However, the question of whether other stimuli, such as hyperosmolarity, that activate RhoA, act through GEF-H1 and whether GEF-H1 activates other RhoGTPases was not known. The overall objective of this research project has been to gain insights into the complex mechanism through which the Rho GTPases, Rac and RhoA, are regulated in tubular cells. Specifically, we wished to explore the role and pathway-specific regulation of GEF-H1 in hyperosmotic stress- and TNF-induced signalling in tubular cells. In order to accomplish our goals, we optimized and used affinity precipitation assays to detect GEF-H1 activation (RhoA(G17A) and Rac(G15A)). We found that 1) GEF-H1 is activated by hyperosmotic stress and mediates the hyperosmolarity-induced RhoA activation, as well as nuclear translocation of the Myocardin-Related Transcription Factor (MRTF); 2) TNF induces activation of both Rac and RhoA through GEF-H1, but via different mechanisms. Epidermal Growth Factor Receptor (EGFR)- and Extracellular signal Regulated Kinase (ERK)-dependent phosphorylation at the Thr678 site of GEF-H1 is a prerequisite for RhoA activation only, while both Rac and RhoA activation require GEF-H1 phosphorylation on Ser885. Interestingly, Rac is required for TNF-induced RhoA activation. Together these findings highlight a role for GEF-H1 as an osmosensitive molecule that regulates cellular reprogramming through MRTF. Importantly, we have also uncovered a novel mechanism explaining hierarchical activation of Rac and RhoA by TNF. Such a mechanism could be key in coordinating GEF function and fine-tuning Rac and RhoA activation. Rho GTPases Tumour Necrosis Factor-alpha (TNF) Guanine Nucleotide Exchange Factors GEF-H1 Cytoskeletal remodelling Hyperosmotic stress 0379 0307

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