Global ETD Search

51	Regulation of cancer stem cell activity and epithelial mesenchymal transition by Rac1 in Human lung adenocarcinoma cells Akunuru, Shailaja 23 September 2011 (has links) No description available. Cellular Biology Cancer stem cells EMT Rac1 Metastasis Lung cancer NSCLA
52	O papel de RhoA e Rac1 GTPases nas respostas celulares após danos no DNA induzidos por radiação ionizante gama / The role of RhoA and Rac1 GTPases in cellular responses after DNA damage induced by ionizing gamma radiation Osaki, Juliana Harumi 18 June 2015 (has links) O mecanismo pelo qual uma célula responde a algum dano no seu material genético é extremamente importante. Isto ocorre pela rápida ativação da maquinaria de reparo de danos no DNA, a qual é composta por uma rede intrincada de sinalização proteica, culminando no reparo do DNA; porém se o dano for irreparável ocorre ativação de mecanismos de morte celular. RhoA,e Rac1 pertencem a família das pequenas proteínas sinalizadoras Rho GTPases, as quais atuam como interruptores moleculares ciclando entre estado ativo (ligada a GTP) e inativo (ligada a GDP). Os componentes desta família estão relacionados ao controle dos mais diversos processos celulares como, por exemplo, remodelamento do citoesqueleto, migração, adesão, endocitose, progressão do ciclo celular e oncogênese. No entanto, apesar das proteínas Rho GTPases estarem envolvidas em um amplo espectro de atividades biológicas, há poucas informações sobre seu papel na manutenção da integridade genômica quando células são submetidas a algum agente genotóxico. Para investigar o envolvimento das GTPases RhoA e Rac1 nas respostas de células submetidas a radiação gama, foram gerados, a partir de células de carcinoma de cervix humano - HeLa, sublinhagens clonais mutantes de RhoA e Rac1 expressando exogenamente RhoA constitutivamente ativa (HeLa-RhoA V14), RhoA dominante negativa (HeLa-RhoA N19), Rac1 constitutivamente ativa (HeLa-Rac1 V12) e Rac1 dominante negativa (HeLa-Rac N17). Após estas linhagens celulares serem expostas a diferentes doses de radiação gama, observamos que ambas GTPases, RhoA e Rac1, são ativadas em resposta aos efeitos da radiação. Além disso, a modulação da atividade destas enzimas, através das mutações, levou a uma alteração das respostas celulares frente aos danos no DNA, como uma redução da capacidade de reparar quebras simples e duplas nas fitas do DNA. Por outro lado, a deficiência de RhoA ou Rac1 GTPase levou a uma redução da ativação de Chk1 e Chk2 ou da fosforilação da histona H2AX, respectivamente, prejudicando os mecanismos de detecção de danos no DNA e levando as células a permanecerem mais tempo nos pontos de checagem G1/S e/ou G2/M do ciclo celular. Esses fatores contribuíram de modo expressivo para a redução da proliferação e sobrevivência celular levando as células à morte. Por fim, ensaios celulares de reparo de danos de um DNA exógeno através de mecanismos de Recombinação Homóloga (HR) e Recombinação Não-Homóloga de extremidades (NHEJ), demonstraram que a inibição da atividade de RhoA reduz significativamente a eficiência de ambas vias de reparo. Desta maneira, este trabalho demonstra e reforça a existência de mais um viés de atuação das pequenas GTPases RhoA e Rac1, agora em células HeLa, nas respostas celulares aos danos induzidos por exposição a radiação gama, modulando a sobrevivência, proliferação e indiretamente modulando resposta ao reparo do DNA através da via de Recombinação Homóloga e Não-Homóloga / The mechanism by which a cell responds to DNA damage is extremely important. This occurs by a quick activation of the DNA damage repair machinery, which consists of an intricate protein signaling network culminating in DNA repair. But if the damages are irreparable occurs there is activation of cell death mechanisms. RhoA and Rac1 belong to family of small Rho GTPases, signaling proteins that act as molecular switches cycling between the active state (GTP-bound) and inactive state (GDP-bound). Members of this family are implicated in the control of diverse cellular process such as cytoskeletal remodeling, migration, adhesion, endocytosis, cell cycle progression, and oncogenesis. However, despite Rho proteins are involved in a broad spectrum of biological activities, there is just a few information about their roles in the maintenance of genomic integrity, that is, when the cells are subjected to some kinf of genotoxic agent. To investigate the involvement of the GTPases RhoA and Rac1 in cellular responses to gamma radiation, we generated from human cervix carcinoma cells - HeLa, clonal sublines of RhoA and Rac1 mutants, exogenous and stably expressing the constitutively active RhoA (HeLa-RhoA V14), the dominant negative RhoA (HeLa-RhoA N19), the constitutively active Rac1 (HeLa-Rac1 V12) and the dominant negative Rac1 (HeLa-Rac1 N17). After all these cell lines have been exposed to different doses of gamma radiation, we found that both GTPases, RhoA and Rac1, are activated in response to the radiation effects. Furthermore, the modulation of two enzymes activity, by using the mutant clones, led to a change in cellular responses to the DNA damage, as the reduction in the capacity of repairing DNA single and double strand breaksr. On the other hand, the deficiency of RhoA or Rac1 GTPase led to a reduction of Chk1 and Chk2 activation, or on the phosphorylation of histone H2AX, respectively, hindering the mechanisms of DNA damage detection and arresting cells in the G1/S and/or G2/M checkpoints of cell cycle. These factors significantly contributed to the reduction of cell proliferation and survival, leading cells to death. Finally, cellular assays of DNA damage repair of exogenous DNA by Homologous Recombination (HR) and Non-Homologous End Joining (NHEJ), demonstrated that RhoA inhibition significantly reduced the repair efficiency of both pathways. Thus, this work demonstrates and reinforces the existence of other biological functions of small GTPases RhoA and Rac1 in HeLa cells, by regulating cellular responses to DNA damage induced by exposure to gamma radiation, modulating the survival, proliferation and indirectly modulating the response to DNA damage repair pathway through the Homologous Recombination and Non-Homologous Recombination Cell signaling DNA damage response and repair Gamma radiation Genomic integrity and stability Integridade e estabilidade genômica Pequenas Rho GTPases Rac1 Rac1 Radiação gama Resposta a danos e reparo no DNA RhoA RhoA Sinalização celular Small Rho GTPase
53	Les rôles distincts des isoformes de myosine II non-musculaire dans des processus cellulaires impliquant le cytosquelette d'actine. Solinet, Sara 12 1900 (has links) Le complexe actomyosine, formé de l’association de la myosine II avec les filaments d’actine, stabilise le cytosquelette d’actine et génère la contraction cellulaire nécessaire à plusieurs processus comme la motilité et l’apoptose dans les cellules non-musculaires. La myosine II est un hexamère formé d’une paire de chaînes lourdes (MHCs) et de deux paires de chaînes légères MLC20 et MLC17. La régulation de l’activité de la myosine II, c'est-à-dire son interaction avec les filaments d’actine, est directement liée à l’état de phosphorylation des MLC20, mais il reste beaucoup à découvrir sur l’implication des MHCs. Il existe trois isoformes de MHCs de myosine II, MHCIIA, MHCIIB et MHCIIC qui possèdent des fonctions à la fois communes et distinctes. Notre but est de mettre en évidence les différences de fonction entre les isoformes de myosine II, au niveau structurale, dans la stabilisation du cytosquelette d’actine, et au niveau de leur activité contractile, dans la génération des forces de tension. Nous nous sommes intéressés au rôle des isoformes des MHCs dans l’activité du complexe actomyosine qui est sollicité durant le processus de contraction cellulaire de l’apoptose. Dans quatre lignées cellulaires différentes, le traitement conjoint au TNFα et à la cycloheximide causait la contraction et le rétrécissement des cellules suivi de leur détachement du support de culture. Par Western blot, nous avons confirmé que la phosphorylation des MLC20 est augmentée suite au clivage de ROCK1 par la caspase-3, permettant ainsi l’interaction entre la myosine II et les filaments d’actine et par conséquent, la contraction des cellules apoptotiques. Cette contraction est bloquée par l’inhibition des caspases et de ROCK1. MHCIIA est dégradée suite à l’activation de la caspase-3 alors que MHCIIB n’est pas affectée. En utilisant une lignée cellulaire déficiente en MHCIIB, ou MHCIIB (-/-), nous avons observé que la contraction et le détachement cellulaires durant l’induction de l’apoptose se produisaient moins rapidement que dans la lignée de type sauvage (Wt) ce qui suggère que l’isoforme B est impliquée dans la contraction des cellules apoptotiques. Parallèlement, la kinase atypique PKCζ, qui phosphoryle MHCIIB et non MHCIIA, est activée durant l’apoptose. PKCζ joue un rôle important puisque son inhibition bloque la contraction des cellules apoptotiques. Par la suite, nous nous sommes intéressés à la modulation de la morphologie cellulaire par la myosine II. Les fibroblastes MHCIIB (-/-), présentent un large lamellipode dont la formation semble dû uniquement à l’absence de l’isoforme MHCIIB, alors que les fibroblastes Wt ont une morphologie cellulaire étoilée. La formation du lamellipode dans les fibroblastes MHCIIB (-/-) est caractérisée par l’association de la cortactine avec la membrane plasmique. L’observation en microscopie confocale nous indique que MHCIIA interagit avec la cortactine dans les fibroblastes Wt mais très peu dans les fibroblastes MHCIIB (-/-). Le bFGF active la voie des MAP kinases dans les fibroblastes Wt et MHCIIB (-/-) et induit des extensions cellulaires aberrantes dans les fibroblastes MHCIIB (-/-). Nos résultats montrent que l’implication de l’isoforme B de la myosine II dans la modulation de la morphologie cellulaire. L’ensemble de nos résultats participe à distinguer la fonction structurale et contractile de chacune des isoformes de myosine II dans la physiologie cellulaire. / We are interested in studying the modulation of the actomyosin complex which is involved in different cellular processes such as cell locomotion and apoptosis. The actomyosin complex is formed by the association of actin filaments and myosin II. The non-muscle myosin II is a hexamer formed by one pair of heavy chains (MHCs) and two pairs of light chain (MLC20 and MLC17). The actomyosin activity is dependent on MLC20 and MHCs phosphorylation. There are three isoforms of MHCs (MHCIIA, MHCIIB and MHCIIC) which have common but also distinctive roles in several cellular processes. Our aim is to clarify the structural and contractile functions of each isoforme of myosin II in different cellular processes, in particular, cell contraction and cell morphology. First, we studied the implication of myosin II isoforms in cell shrinkage and detachment during apoptosis which are both dependent on actomyosin contractility. We treated four different cell lines with TNFα in combination with cycloheximide (CHX) to trigger apoptosis. We confirmed that TNFα induced caspase-3 activation, ROCK1 cleavage and increased MLC20 phosphorylation. We showed that TNFα/CHX induced the caspase-dependent MHCIIA degradation, whereas MHCIIB levels and association with the actin cytoskeleton remained virtually unchanged. Cell shrinkage and detachment were blocked by caspase and ROCK1 inhibitors. Using the MHCIIB (-/-) cell line, we observed that the absence of MHCIIB did not affect cell death rate. However, MHCIIB (-/-) fibroblasts showed more resistance to TNFα-induced actin disassembly, cell shrinkage and detachment than wild type (Wt) fibroblasts, indicating the participation of MHCIIB in these events. PKCζ, which only phosphorylates MHCIIB, was cleaved during apoptosis, co-immunoprecipitated preferentially with MHCIIB and, interestedly, PKCζ inhibition blocked TNFα-induced shrinkage and detachment. Our results demonstrate that MHCIIB, together with MLC phosphorylation and actin, constitute the actomyosin cytoskeleton that mediates contractility during apoptosis. Second, we studied the involvement of myosin II isoforms in cell shape modulation. Fibroblasts MHCIIB (-/-) spontaneously formed lamellipodia whereas Wt fibroblasts presented a stellate shape. Cortactin was associated with the leading edge of lamellipodia in MHCIIB (-/-) fibroblasts, but it localised diffusely in the cytoplasm or at the end of fine cellular projections in Wt fibroblasts. The levels of cortactin and cortactin phosphorylated in Tyr421 associated with membrane in MHCIIB (-/-) fibroblasts were higher than in Wt fibroblasts. Confocal microscopy showed cortactin/MHCIIA colocalization in wild type but not in MHCIIB (-/-) fibroblasts. bFGF activates Erk1/2 in wild type and MHCIIB (-/-) fibroblasts and induces the formation of aberrant membrane projections in MHCIIB (-/-) fibroblasts. In conclusion, our results contribute to characterize the structural and contractile role of each myosin II isoforms in the physiology of the cell. cytosquelette d’actine actin cytoskeleton myosine non-musculaire II nonmuscle myosin II complexe actomyosine actomyosin complex contraction cellulaire cell contraction apoptose apoptosis cortactine cortactin GTPase Rac1 GTPase Rac1 lamellipode lamellipodia formation
54	Les rôles distincts des isoformes de myosine II non-musculaire dans des processus cellulaires impliquant le cytosquelette d'actine Solinet, Sara 12 1900 (has links) No description available. cytosquelette d’actine actin cytoskeleton myosine non-musculaire II nonmuscle myosin II complexe actomyosine actomyosin complex contraction cellulaire cell contraction apoptose apoptosis cortactine cortactin GTPase Rac1 GTPase Rac1 lamellipode lamellipodia formation
55	O papel de RhoA e Rac1 GTPases nas respostas celulares após danos no DNA induzidos por radiação ionizante gama / The role of RhoA and Rac1 GTPases in cellular responses after DNA damage induced by ionizing gamma radiation Juliana Harumi Osaki 18 June 2015 (has links) O mecanismo pelo qual uma célula responde a algum dano no seu material genético é extremamente importante. Isto ocorre pela rápida ativação da maquinaria de reparo de danos no DNA, a qual é composta por uma rede intrincada de sinalização proteica, culminando no reparo do DNA; porém se o dano for irreparável ocorre ativação de mecanismos de morte celular. RhoA,e Rac1 pertencem a família das pequenas proteínas sinalizadoras Rho GTPases, as quais atuam como interruptores moleculares ciclando entre estado ativo (ligada a GTP) e inativo (ligada a GDP). Os componentes desta família estão relacionados ao controle dos mais diversos processos celulares como, por exemplo, remodelamento do citoesqueleto, migração, adesão, endocitose, progressão do ciclo celular e oncogênese. No entanto, apesar das proteínas Rho GTPases estarem envolvidas em um amplo espectro de atividades biológicas, há poucas informações sobre seu papel na manutenção da integridade genômica quando células são submetidas a algum agente genotóxico. Para investigar o envolvimento das GTPases RhoA e Rac1 nas respostas de células submetidas a radiação gama, foram gerados, a partir de células de carcinoma de cervix humano - HeLa, sublinhagens clonais mutantes de RhoA e Rac1 expressando exogenamente RhoA constitutivamente ativa (HeLa-RhoA V14), RhoA dominante negativa (HeLa-RhoA N19), Rac1 constitutivamente ativa (HeLa-Rac1 V12) e Rac1 dominante negativa (HeLa-Rac N17). Após estas linhagens celulares serem expostas a diferentes doses de radiação gama, observamos que ambas GTPases, RhoA e Rac1, são ativadas em resposta aos efeitos da radiação. Além disso, a modulação da atividade destas enzimas, através das mutações, levou a uma alteração das respostas celulares frente aos danos no DNA, como uma redução da capacidade de reparar quebras simples e duplas nas fitas do DNA. Por outro lado, a deficiência de RhoA ou Rac1 GTPase levou a uma redução da ativação de Chk1 e Chk2 ou da fosforilação da histona H2AX, respectivamente, prejudicando os mecanismos de detecção de danos no DNA e levando as células a permanecerem mais tempo nos pontos de checagem G1/S e/ou G2/M do ciclo celular. Esses fatores contribuíram de modo expressivo para a redução da proliferação e sobrevivência celular levando as células à morte. Por fim, ensaios celulares de reparo de danos de um DNA exógeno através de mecanismos de Recombinação Homóloga (HR) e Recombinação Não-Homóloga de extremidades (NHEJ), demonstraram que a inibição da atividade de RhoA reduz significativamente a eficiência de ambas vias de reparo. Desta maneira, este trabalho demonstra e reforça a existência de mais um viés de atuação das pequenas GTPases RhoA e Rac1, agora em células HeLa, nas respostas celulares aos danos induzidos por exposição a radiação gama, modulando a sobrevivência, proliferação e indiretamente modulando resposta ao reparo do DNA através da via de Recombinação Homóloga e Não-Homóloga / The mechanism by which a cell responds to DNA damage is extremely important. This occurs by a quick activation of the DNA damage repair machinery, which consists of an intricate protein signaling network culminating in DNA repair. But if the damages are irreparable occurs there is activation of cell death mechanisms. RhoA and Rac1 belong to family of small Rho GTPases, signaling proteins that act as molecular switches cycling between the active state (GTP-bound) and inactive state (GDP-bound). Members of this family are implicated in the control of diverse cellular process such as cytoskeletal remodeling, migration, adhesion, endocytosis, cell cycle progression, and oncogenesis. However, despite Rho proteins are involved in a broad spectrum of biological activities, there is just a few information about their roles in the maintenance of genomic integrity, that is, when the cells are subjected to some kinf of genotoxic agent. To investigate the involvement of the GTPases RhoA and Rac1 in cellular responses to gamma radiation, we generated from human cervix carcinoma cells - HeLa, clonal sublines of RhoA and Rac1 mutants, exogenous and stably expressing the constitutively active RhoA (HeLa-RhoA V14), the dominant negative RhoA (HeLa-RhoA N19), the constitutively active Rac1 (HeLa-Rac1 V12) and the dominant negative Rac1 (HeLa-Rac1 N17). After all these cell lines have been exposed to different doses of gamma radiation, we found that both GTPases, RhoA and Rac1, are activated in response to the radiation effects. Furthermore, the modulation of two enzymes activity, by using the mutant clones, led to a change in cellular responses to the DNA damage, as the reduction in the capacity of repairing DNA single and double strand breaksr. On the other hand, the deficiency of RhoA or Rac1 GTPase led to a reduction of Chk1 and Chk2 activation, or on the phosphorylation of histone H2AX, respectively, hindering the mechanisms of DNA damage detection and arresting cells in the G1/S and/or G2/M checkpoints of cell cycle. These factors significantly contributed to the reduction of cell proliferation and survival, leading cells to death. Finally, cellular assays of DNA damage repair of exogenous DNA by Homologous Recombination (HR) and Non-Homologous End Joining (NHEJ), demonstrated that RhoA inhibition significantly reduced the repair efficiency of both pathways. Thus, this work demonstrates and reinforces the existence of other biological functions of small GTPases RhoA and Rac1 in HeLa cells, by regulating cellular responses to DNA damage induced by exposure to gamma radiation, modulating the survival, proliferation and indirectly modulating the response to DNA damage repair pathway through the Homologous Recombination and Non-Homologous Recombination Integridade e estabilidade genômica Pequenas Rho GTPases Rac1 Radiação gama Resposta a danos e reparo no DNA RhoA Sinalização celular Cell signaling DNA damage response and repair Gamma radiation Genomic integrity and stability Rac1 RhoA Small Rho GTPase
56	Differential Roles of Mammalian Target of Rapamycin Complexes 1 and 2 in Migration of Prostate Cancer Cells Venugopal, Smrruthi Vaidegi 20 May 2019 (has links) In this study, we investigated differential activation and the role of two mTOR complexes in cell migration of prostate cancer cells. Specific knock-down of endogenous RAPTOR and RICTOR by siRNA resulted in decreased cell migration in LNCaP, DU145, and PC3 cells indicating that both mTORC1 and mTORC2 are required for cell migration. EGF treatment induced the activation of both mTORC1 and mTORC2 as determined by complex-specific phosphorylation of mTOR protein. Specific knock-down or inhibition of Rac1 activity in PC3 cells blocked EGF-induced activation of mTORC2, but had no effect on mTORC1 activation. Furthermore, the over-expression of constitutively active Rac1 (Rac1Q61L) resulted in significant increase in cell migration and activation of mTORC2 in PC3 cells, but had no effect on mTORC1 activation. Constitutively active Rac1 (Rac1Q61L) in PC3 cells was localized in the plasma membrane and was found to be in a protein complex which contained mTOR and RICTOR proteins, but not RAPTOR. In conclusion, we suggested that EGF-induced activation of Rac1 causes the phosphorylation/activation of mTORC2 via RICTOR, specific regulator of mTORC2 activation in numerous cancer cells. The major role played by mTOR in a wide array of cancers has in the recent decades led to the development of numerous mTOR inhibitors. One of the drawback of these first generation mTOR inhibitors are that m TORC1 activity is inhibited but effect on mTORC2 activity require high dosages and prolonged exposure in different cancer cell types including HeLa, PC3, LNCaP, and A549. High dosage of rapamycin and its associated rapalogs required for mTORC2 inhibition is clinically unsuitable. Studies have shown that the dual mTORC1/C2 inhibitors trigger feedback loops causing metastasis and affect the cell viability of normal tissues in vitro and in vivo. There is a need for specific mTORC1 and mTORC2 inhibitor, which overcome the disadvantages of the previously developed mTOR inhibitors. The Rac1-RICTOR axis suggested in this study could be used as a potential target for the development of mTORC2 inhibitor and lead to a potential therapeutic treatment for aggressive prostate cancer. Cell migration prostate cancer mTOR Rac1 PI3K/AKT pathway RICTOR Biology Cancer Biology Cell Biology Laboratory and Basic Science Research
57	PHARMACOGENETIQUE DES MEDICAMENTS THIOPURINIQUES Implication des enzymes TPMT et IMPDH2 et de la RhoGTPase RAC1 Garat, Anne 09 September 2009 (has links) (PDF) Les médicaments thiopuriniques que sont l'azathioprine, la 6-mercaptopurine et la 6-thioguanine sont utilisés depuis des décennies pour leurs propriétés cytotoxiques et immunosuppressives dans le traitement de certaines leucémies, de maladies inflammatoires chroniques ou auto-immunes ainsi que dans la prévention du rejet de greffe. Certains patients, traités par des doses conventionnelles de ces molécules, développent cependant des effets indésirables parfois très sévères. Le déficit d'activité, d'origine génétique, de la thiopurine S-méthyltransférase (TPMT), enzyme impliquée dans le métabolisme des thiopurines, constitue l'un des facteurs majeurs de la myélotoxicité de ces médicaments. La détermination du phénotype TPMT par génotypage, qui est une mesure préventive avant l'introduction d'un traitement thiopurinique, repose sur l'identification des mutations inactivatrices les plus fréquentes du gène TPMT. Une partie de ce travail a consisté en l'analyse fonctionnelle de quatre variants alléliques rares du gène TPMT dans un système d'expression hétérologue, la levure S. cerevisiae. Le caractère non-fonctionnel de deux d'entre eux a ainsi été démontré. Cependant, le déficit d'activité de la TPMT ne permet d'expliquer qu'environ 30 % des cas de myélotoxicité sous thiopurines, ce qui laisse supposer l'existence d'autres anomalies génétiques affectant d'autres gènes impliqués dans la réponse de l'organisme à ces molécules. Ainsi, nous avons étudié le polymorphisme génétique de deux autres protéines candidates, celui de l'inosine monophosphate déshydrogénase de type 2 (IMPDH2), enzyme-clé de la formation des métabolites actifs des thiopurines, et celui de la RhoGTPase RAC1, qui est l'une des cibles pharmacologiques de ces molécules. Certains des polymorphismes que nous avons identifiés dans ces deux gènes semblent affecter in vitro l'expression et/ou l'activité de ces protéines et pourraient, par conséquent, contribuer aux variations inter-individuelles de réponse aux thiopurines pharmacogénétique thiopurine - méthyltransférase polymorphisme génétique IMP dehydrogenase protéine RAC1 azathioprine mercaptopurine thioguanine
58	Prognostic Biomarkers and Target Proteins for Treatment of High-grade Gliomas Sooman, Linda January 2014 (has links) The survival for high-grade glioma patients is poor and the treatment may cause severe side effects. A common obstacle in the treatment is chemoresistance. To improve the quality of life and prolong survival for these patients prognostic biomarkers and new approaches for chemotherapy are needed. To this end, a strategy to evade chemoresistance was evaluated by combining chemotherapeutic drugs with agents inhibiting resistance mechanisms identified by a bioinformatic analysis (paper I). The prognostic value of 13 different proteins was analyzed in this thesis (papers II-IV). Two of them, p38 mitogen-activated protein kinase (MAPK) and protein tyrosine phosphatase non-receptor type 6 (PTPN6, also known as SHP1) were analyzed for their potential as targets in combination chemotherapy (in paper III and IV, respectively). We found that: PTPN6 expression and methylation status may be important for survival of anaplastic glioma patients, p38 MAPK phosphorylation may be a potential negative prognostic biomarker for high-grade glioma patients and FGF2 expression may be a potential negative prognostic biomarker for proneural glioma patients. PTPN6 may be a useful target for combination chemotherapy with cisplatin, melphalan or bortezomib in high-grade gliomas. The following drug combinations; camptothecin combined with an EGFR or RAC1 inhibitor, imatinib combined with a Notch or RAC1 inhibitor, temozolomide combined with an EGFR or FAK inhibitor and vandetanib combined with a p38 MAPK inhibitor may be useful combination chemotherapy for high-grade gliomas. High-grade glioma prognostic biomarkers combination chemotherapy DNA methylation FGF2 p38 MAPK PTPN6 camptothecin imatinib vandetanib EGFR RAC1 Notch
59	Role of ARF6 in breast cancer cell invasion / Rôle de la protéine ARF6 dans le processus invasif du cancer du sein. Marchesin, Valentina 18 September 2014 (has links) La migration des cellules tumorales à travers la matrice extracellulaire dépend de l'activité d'une métalloprotéase matricielle, MT1-MMP, ancrée à la membrane plasmique. MT1-MMP accumule aux invadopodes, des protrusions membranaires à base d'actine responsables de la dégradation de la matrice. La petite protéine G ARF6 est impliquée dans la régulation du trafic membranaire et dans le remodelage du cytosquelette d'actine. Dans mon travail de thèse, j'ai montré qu'ARF6 et deux de ses protéines effectrices JIP3 et JIP4, sont nécessaires à l'exocytose de MT1-MMP au niveau des invadopodes et, par conséquent, à la capacité des cellules tumorales à remodeler la matrice extracellulaire et migrer à travers un environnement matriciel tridimensionnel. ARF6, à travers son interaction avec JIP3/4, contrôle négativement l'activité du complexe dynactine/dynéine, un moteur moléculaire qui se déplace en direction du bout (-) des microtubules, et donc la clairance des endosomes MT1-MMP à partir de la périphérie cellulaire. En plus dans des échantillons humaines ARF6 est accumulée au niveau de la membrane plasmique, avec MT1-MMP, dans un sous-groupe de carcinomes mammaires agressifs, en confirmant donc l'implication d'un axe ARF6-JIP3/JIP4-MT1-MMP dans le processus invasif du cancer du sein. Dans une deuxième étude, j'ai montré que l'hyperactivation d'ARF6 induit un réarrangement important du cytosquelette d'actine à la surface ventrale des cellules tumorales mammaires et contribue à l'activation et au ciblage de Rac1 au front cellulaire. Mon travail a permis d'identifier de nouveaux mécanismes moléculaires par lesquels ARF6 contribue au programme invasif des cellules tumorales mammaires. / The ability of cancer cells to traffic through the extracellular matrix relies on the action of the membrane-anchored matrix metalloprotease MT1-MMP. MT1-MMP is exocytosed to invadopodia, the actin-based membrane protrusions responsible for matrix degradation. The small GTP-binding protein ARF6 is known to coordinate post-endocytic recycling and actin cytoskeletal organization at the plasma membrane and was shown to be up-regulated in breast cancer cells. In my PhD work I showed that ARF6 and two of its effectors JIP3 and JIP4 are required for MT1-MMP endosomes intracellular positioning and exocytosis at invadopodia and consequently for tumor cells ability to remodel the matrix and invade through a three-dimensional matrix environment. ARF6, through the interaction with JIP3/4, negatively controls the activity of the minus-end-directed microtubule motor dynactin/dynein, thus negatively regulating the clearance and inward movement of MT1-MMP endosomes from the cell periphery. In human samples ARF6 is accumulated at the plasma membrane, together with MT1-MMP, in a subset of highly aggressive breast carcinomas, thus corroborating the ARF6-JIP3/JIP4-MT1-MMP axis in breast cancer invasion. In a second study I addressed the contribution of ARF6 activation on actin cytoskeleton remodeling in breast cancer cells. ARF6 links epidermal growth factor receptor signaling to Rac1 activation and targeting to the leading edge where it activates the SCAR/WAVE complex and regulates ventral actin polymerization during lamellipodia extension. Collectively my work identifies novel molecular mechanisms through which ARF6 contributes to the invasive program of breast tumor cells Invasion cellulaire Cancer du sein Arf6 Métalloprotéase de surface Trafic membranaire Moteurs des microtubules Remodelage de l'actine RAC1 Breast cancer Microtubule motor 571.6
60	A Mitotic Actin Regulating Pathway Induces Chromosomal Instability In Human Cancer Cells Glaubke, Elina 28 April 2020 (has links) No description available. 570 Cancer Chromosomal Instability Actin Microtubule EB1 TRIO Rac1 Arp2/3 Cortex architecture Cortex tension Biologie (PPN619462639)

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