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The regulation of the serum response network by the RGS RHOGEFS is critical for YAP1 activity and cell fate decisionsLane, Brandon S. 17 November 2016 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The growth of mammary epithelial cells is regulated by interactions with
neighboring cells and by exposure to soluble factors including hormones and growth
factors. These cues are integrated within the cell, perpetuating changes onto the
organization of the actin cytoskeleton, resulting in altered transcriptional programs. Rho
family GTPases regulates actin dynamics that facilitate transcriptional reprogramming. In
particular, RhoA induces the formation of actin stress fibers to promote the
transcriptional co-activator YAP1 to translocate from the cytosol into the nucleus. There,
it co-activates TEAD family transcription factors to drive the expression of pro-growth
and survival genes. Rho family members are activated by guanine exchange factors
(GEF) and inhibited by GTPase activating proteins (GAP). Here, we determined the
relative effects of expression of 67 RhoGEFs and RhoGAPs on the activation of TEAD.
This revealed that regulator of G-protein signaling (RGS) domain containing ArhGEF1,
ArhGEF11 and ArhGEF12 all promoted YAP1 dependent activation of TEAD. These
RhoGEFs mediate signaling from heptahelical receptors that are stimulated by lipid
mitogens to activate the heterotrimeric G-proteins Gα12 and Gα13. Consistently, loss of
expression of ArhGEF12 and to a lesser degree ArhGEF11 prevented actin stress fiber
accumulation and activation of YAP1 mediated signaling by serum. Conversely, several
complementary experiments revealed that ArhGEF1 dominantly limits Gα13 selective
activation of YAP1 and the mitogen activated protein kinase (MAPK) cascades.
Furthermore excessive Gα13 activity results in both high levels of filamentous actin and arrest cells in the G1/0 phase of the cell cycle. This is likely due to the systemic inhibition
of cell cycle promoting signaling and a loss of protein translation. Further, YAP1 was
found to be essential for the survival of ArhGEF1 silenced cells. Together, these studies
define a circuit whereby the rgRhoGEFs regulate Gα 12/13-RhoA signaling flux to regulate
cellular growth that is promoted by serum factors.
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Rôle du facteur d’échange nucléotidique Arhgef1 dans l’hémostase / Role of the Arhgef1 nucleotide exchange factor in hemostasisRouillon, Camille 18 September 2019 (has links)
Une des propriétés majeures de la thrombine est le caractère pléiotropique de ses effets physiologiques et pathologiques à la fois dans le compartiment sanguin et tissulaire de la paroi. La voie de signalisation RhoA est activée par la fixation de la thrombine aux récepteurs PARs et cette voie est un régulateur principal de la mécanotransduction et de la plasticité cellulaire. Le facteur d’échange de RhoA, Arhgef1, est impliqué dans le développement de l’hypertension dépendante de l’angiotensine II et dans l’athérothrombose. Notre hypothèse est que le contrôle de la signalisation intracellulaire de RhoA par Arhgef1 est un élément régulateur de la coagulation plasmatique et pourrait participer aux modifications phénotypiques des plaquettes et des cellules vasculaires et ainsi contribuer à l’augmentation de la génération de thrombine tissulaire. Les objectifs ont été de caractériser la génération de thrombine et la fonction plaquettaire depuis leur activation jusqu’à leurs implications dans un modèle de thrombose tissulaire et d’étudier le rôle prothrombotique des cellules musculaires lisses vasculaires (CMLVs) chez des souris Arhgef1 -/-. Résultats : Les souris Arhgef1-/- ont une numération plaquettaire normale mais présentent une diminution significative de l’activation plaquettaire, de la génération de thrombine en sang total et en présence de plaquettes (mais pas en plasma pauvre en plaquettes) et de l’adhérence plaquettaire par rapport aux souris contrôles. Ces modifications se traduisent, in vivo, par un plus grand nombre d’arrêts transitoires de l’écoulement sanguin dans le modèle de saignement à la queue et un allongement du temps de survenue du thrombus occlusif carotidien en réponse au FeCl3 chez les souris Arhgef1 -/- comparées aux contrôles. Les CMLVs des souris Arhgef1 -/- génèrent moins de thrombine à leur surface et ont une prolifération diminuée par rapport aux CMLVs des souris contrôles. En conclusion, les résultats démontrent le rôle d’Arhgef1 dans les fonctions plaquettaires et dans la régulation du phénotype des CMLVs. Le mécanisme principal fait intervenir la Rho GTPase dans l’adhésion plaquettaire et la génération de thrombine à la surface CMLVs qui contrôlent la formation du thrombus. Ces résultats suggèrent que ce facteur d’échange est capable d’amplifier la thrombose artérielle et pourrait être impliqué via les récepteurs à la thrombine dans le couplage thrombine tissulaire-rigidité cellulaire via les plaquettes et les CMLVs dans les pathologies vasculaires. / One of the major properties of thrombin is the pleiotropic character of its physiological and pathological effects in both the blood and the tissue compartment of the vessel wall. The RhoA signaling pathway is activated by the binding of thrombin to the PARs receptors and this pathway is a major regulator of mechanotransduction and cellular plasticity. The RhoA exchange factor, Arhgef1, is involved in the development of angiotensin II-dependent hypertension and in atherothrombosis. Our hypothesis is that the control of intracellular RhoA signaling by Arhgef1 is a regulatory element of plasma coagulation and could participate in phenotypic modifications of platelets and vascular cells and thus contribute to the increase of tissue thrombin generation. The objectives were to characterize thrombin generation and platelet function from their activation to their implications in a model of tissue thrombosis, and to study the prothrombotic role of vascular smooth muscle cells (VSMCs) in Arhgef1 -/- mice. Results: Arhgef1 -/- mice had a normal platelet count but showed a significant decrease in platelet activation, thrombin generation in whole blood and in the presence of platelets (but not in platelet poor plasma) and platelet adhesion compared to control mice. These modifications result, in vivo, by a greater number of transitory stopping of the blood flow in the tail bleeding model and an increase in the time of occurrence of the carotid occlusive thrombus in response to FeCl3 in Arhgef1 -/- mice compared to controls. The VSMCs of Arhgef1 -/- mice generate less thrombin at their surface and have decreased proliferation compared to VSMCs of the control mice. In conclusion, the results demonstrate the role of Arhgef1 in platelet function and in the regulating of the phenotype of VSMCs. The main mechanism involves Rho GTPase in platelet adhesion and in thrombin generation at the VSMC surface that control thrombus formation. These results suggest that this exchange factor is able to amplify aterial thrombosis and could be involved via thrombin receptors in tissue thrombin-cell stiffness coupling via platelets and VSMCs in vascular pathologies.
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