Global ETD Search

291	Funktionelle Analyse von bakteriellen W-xxx-E Rho GTPasen GEF Mimetika mittels Typ 3 Sekretionssystems von Yersinia enterocolitica / Functional analysis of bacterial W-xxx-E Rho GTPase GEF mimetics using the type 3 secretion system of Yersinia enterocolotica Wölke, Stefan January 2010 (has links) (PDF) Die zellulären Rho GTPasen kontrollieren und regulieren zentrale elementare Zellvorgänge wie Phagozytose, Migration und epitheliale Integrität. Aufgrund ihrer zentralen Stellung, interagiert eine Vielzahl von bakteriellen Cytotoxinen und Modulinen mit den Rho GTPasen und wirken so als Pathogenitätsfaktoren. Die zur W-xxx-E Familie gehörenden Effektoren IpgB1 und IpgB2 von Shigella und Map von E. coli (Pathotypen EHEC und EPEC) werden über ein Typ 3 Sekretionssystem (T3SS) in Wirtszellen injiziert und wirken als Rac1, RhoA bzw. Cdc42 GEF Mimetikum. In der vorliegenden Arbeit wurden die Effektor Funktionen von IpgB1 IpgB2 und Map mit Hilfe des Yersinia (Ysc)-T3SS untersucht, was zur Etablierung der „Yersinia-Toolbox“ führte. Damit können heterologe Effektoren isoliert im physiologischen Kontext der Erreger-Zell-Interaktion zellbiologisch untersucht werden unter Vermeidung von simultaner Injektion redundanter oder unbekannter Effektoren. Zur Etablierung der Yersinia-Toolbox wurden zunächst die Gene für die Rho GTPasen modulierenden Shigella Effektoren IpgB1 und IpgB2 sowie der E. coli (EHEC)-Effektor Map mit unterschiedlich langen Gensequenzen der N-terminalen Bereiche des Yersinia-Effektorproteins YopE fusioniert (Hybridproteine: YopEi-X:i = 18, 53 bzw. 138 Aminosäurereste, X = IpgB1, IpgB2 bzw. Map). In der vorliegenden Arbeit wird gezeigt, dass die Hybridproteine YopE53-X und YopE138-X (X=IpgB1, IpgB2, Map) in den Kulturüberstand sezerniert bzw. in Zielzellen injiziert wurden. In einem weiteren Schritt konnte die zellbiologische Aktivität der heterologen Proteine fluoreszenzmikroskopisch durch Aktinzytoskelettumlagerungen gezeigt werden. So wurden „Membrane Ruffles“ (Rac1-Aktivierung) durch YopE138-IpgB1, Stressfasern (RhoA-Aktivierung) durch E138-IpgB2 und „Mikrospikes“ (Cdc42-Aktivierung) durch YopE138-Map nachgewiesen. Invasionstudien zeigten, dass YopEi-IpgB1 (i = 53, 138) die Yersinia-Invasion induzierte, wohingegen YopEi-IpgB2 die Invasionsrate der Stämme WA (pT3SS, pEi-IpgB2) (i=53, 138) verglichen mit dem Stamm WA (pT3SS) reduziert war. Durch Kombination verschiedener Yersinia-Toolbox-Stämme konnte im Co-Infektionsmodell mit HeLa-Zellen gezeigt werden, dass (1) die YopE138-IpgB1 vermittelte Invasion durch YopE138-IpgB2 signifikant inhibiert werden kann, was auf eine antagonistische Wirkung zwischen IpgB1 und IpgB2 schließen lässt, dass (2) YopT ebenfalls die IpgB1 vermittelte Invasionsrate reduziert (inhibitorische Wirkung auf Rac1), und dass (3) YopE als GAP für RhoG/Rac1 (bevorzugt RhoG) praktisch nicht die IpgB1-vermittelte Invasion hemmt. Durch Klonierung der YopE138-IpgB1 und YopE138-IpgB2 kodierenden Fusionsgene in zwei kompatible Plasmidvektoren konnten die Hybridproteine simultan transloziert werden und die Co-Infektionsergebnisse bestätigt werden. In der Literatur ist beschrieben, dass die Ysc-Translokationspore YopB/YopD Rho-abhängig Membranporen-bedingte Zellschädigungen verursacht (LDH-Freisetzung, PI-Kernfärbung). Mit der Yersinia-Toolbox konnte mit dem Stamm WA (pT3SS) Zytoplasmamembranschädigung / Zytotoxizität nachgewiesen werden, nicht aber mit den Stämmen WA (pE138-X) X = IpgB1, IpgB2 oder Map. Co-Infektionen jedoch zeigen, dass vermehrt LDH bei der Infektion mit WA (pT3SS) + WA (pT3SS, pE138-IpgB1) detektiert wurde, wohingegen dieser Effekt von YopE138-IpgB2 in einer Co-Infektion von WA (pT3SS) + WA (pT3SS, pE138-IpgB2) inhibiert wurde. Auch hier wurde der Antagonismus zwischen IpgB1 und IpgB2 erneut sichtbar. Diese Befunde widersprechen publizierten Daten, die eine RhoA-Aktivierung/Aktinpolymerisierung mit verstärkter Porenbildung in einen Zusammenhang bringen. Rho GTPasen sind beteiligt an der Erhaltung der polarisierten Eipthelzellschichtintegrität über Adhäsionskomplexbildung. Mittels Infektion von polarisierten MDCK-Zellschichten mit verschiedenen Yersinia-Stämmen und Messung des transepithelialen elektrischen Widerstandes/Resistenz (TER) konnte gezeigt werden, dass die Ysc-T3SS vermittelte Injektion von YopE138-IpgB1 (Rac1-Aktivierung) oder YopE138-Map (Cdc42-Aktivierung) zur Abnahme der TER und damit Schädigung der Zellschichtintegrität führt, wogegen bei YopE138-IpgB2-Injektion der TER-Wert unverändert blieb. Um bakterielle Rho GTPasen-modulierende Effektorproteine detailliert untersuchen zu können und um die Rolle von Rho GTPasen im Mausinfektionsmodell mit Yersinia enterocolitica und Salmonellen zu bestimmen, wurden Mäuse mit deletierten Genen für RhoA, Rac1 bzw. Cdc42 in Makrophagen hergestellt. / Phagocytosis, migration and regulation of epithelial integrity are central cellular aspects that are controlled by the cellular Rho GTPases. In this regard, Rac1, RhoA and Cdc42 have important regulatory roles mediating various cytoskeletal rearrangements in many cell types including epithelial cells as well as professional phagocytes. Because of the central role of the Rho GTPases in cellular integrity and function, bacterial cytotoxins and modulins targeting these cellular switches are very efficient pathogenicity factors. Recently, the T3SS effectors, IpgB1, IpgB2 of Shigella and Map of E. coli (pathotype EHEC/EPEC) were assembled in one protein family sharing the common motif W-xxx-E. Members of this protein family are described to act as GEF mimics for the cellular Rho GTPases. In this study the effector functions of IpgB1, IpgB2 and Map were analyzed with the Yersinia (Ysc)-T3SS which led to the development of the “Yersinia-Toolbox”. Yersinia enterocolitica is very suitable to be used as “T3SS-Toolbox” because (1) a plasmid solely carrying the DNA fragment encoding the Ysc-T3SS without T3SS-effectors is available, (2) in difference to Salmonella and E. coli (EPEC/EHECH) the Ysc-T3SS-effector genes of Yersinia are not localized on the chromosome and (3) heterologous proteins fused to the Ysc-T3SS-effector YopE are secreted and translocated into cells. This allows the analysis of single heterologous effectors without simultanous injection of other (unknown/redundant) T3SS-effectors in a physiological context during the interaction of Yersinia with cells. To develop the Yersinia-Toolbox, the genes of the GTPase modulating effectors IpgB1, IpgB2 of Shigella and Map of E. coli (EHEC) were fused to different long sections of the N-Terminus of the Yersinia-Ysc-T3SS-effector YopE (hybrid proteins: YopEi-X: i = 18, 53 or 138 amino acid residues, X = IpgB1, IpgB2 or Map). This study demonstrates the secretion to the culture supernatent and the injection into target cells of the hybrid proteins YopE53-X and YopE138-X (X = IpgB1, IpgB2 and Map). Furthermore, cell biologic activity was detected for the YopE-X hybrid proteins by fluorescence microscopy as membrane ruffles (Rac1 activation), stress fibres (RhoA activation) and micro spikes (Cdc42 activation) occurred after injection of YopE138-IpgB1,.YopE138-IpgB2 and YopE138-Map, in respective. Invasion studies showed that YopEi-IpgB1 (i = 53, 138) induced invasion of Yersinia, whereas YopEi-IpgB2 reduced invasion of the strains WA (pT3SS, pEi-IpgB2) (i = 53, 138) compared to the strain WA (pT3SS). Combination of different Yersinia-Toolbox strains in the co-infection model with HeLa cells showed that (1) YopE138-IpgB2 reduced the YopE138-IpgB1 induced invasion suggesting an antagonism between IpgB1 and IpgB2, (2) YopT also reduced the YopE138-IpgB1 induced invasion (inhibitory function on Rac1) and (3) that YopE as GAP for RhoG/Rac1 (predominantly RhoG) did not inhibit the YopE138-IpgB1 induced invasion. Because of the construction of two different compatible plasmids carrying the genes for either YopE138-IpgB1 or YopE138-IpgB2, simultanous translocation of the hybrid proteins of one single strain was possible. These studies confirmed the results of the co-infection studies. It has been reported that the Ysc translocation pore YopB/YopD induces Rho dependent membrane pores in cells which leads to cellular damage (LDH release, PI-staining of the nucleus). In this study cellular damage / cytotoxicity was detected after an infection of HeLa cells with the Yersinia-Toolbox strain WA (pT3SS). In contrast to that no cytotoxicity was detected after an infection of HeLa cells with the Yersinia-Toolbox strains WA (pT3SS, pE138-X) X = IpgB1, IpgB2 and Map. Additionally, co-infections with the strains WA (pT3SS) and WA (pT3SS, pE138-IpgB1) resulted in an increased LDH release whereas a co-infection with the strains WA (pT3SS) and WA (pT3SS, pE138-IpgB2) led to the decrease of LDH release compared to single infections with WA (pT3SS), again suggesting an antagonism between IpgB1 and IpgB2. These results are contrary to published data, which suggest a correlation between RhoA activation dependent actin polymerisation and pore formation. The cellular Rho GTPases are involved in the maintenance of epithelial integrity of polarized cells. Infections of polarized MDCK cell layers with different Yersinia-Toolbox strains resulted in a decrease of the transepithelial electric resistance (TER) indicating a damage of the epithelial integrity after injection of YopE138-IpgB1 or YopE138-Map. The TER value was not altered after injection of YopE138-IpgB2 indicating an intact epithelial integrity. To study bacterial Rho GTPase modulating proteins in more detail and to get a deeper insight to the role of Rho GTPases in the murine infection model with Yersinia enterocolitica and Salmonella, mice with gene deletions for RhoA, Rac1 or Cdc42 in macrophages were constructed. Actin Yersinia enterocolitica Shigella flexneri EHEC CRE Knockout <Molekulargenetik> Guanosintriphosphatasen ddc:570
292	Cofilin / Cofilin Lee, Kyeong-Hee January 1999 (has links) (PDF) This study has identified cofilin, an actin binding protein, as a control element in the reorganization of the actin cytoskeleton which is highly relevant for T lymphocyte activation. Cofilin is regulated in its activity by reversible phosphorylation which is inducible by stimulation through accessory receptors such as CD2 and CD28. First it could be demonstrated that accessory receptor triggering induces the transient association of cofilin with the actin cytoskeleton and that only the dephosphorylated form of cofilin possesses the capacity to bind cytoskeletal actin in vivo. PI3-kinase inhibitors block both the dephosphorylation of cofilin and its association with the actin cytoskeleton. Importantly, cofilin, actin, PI3-kinase and one of its substrates, namely phosphatidylinositol 4,5-bisphosphate (PtdIns(4,5)P2) which can bind to cofilin, co-localize within CD2-receptor caps. The cofilin/F-actin interaction has been identified as a crucial regulatory element for receptor cap formation and the strength of signal transduction. To this end, appropriately designed cell permeable non-toxic peptides that are homologous to actin binding motifs of the human cofilin sequence were introduced into untransformed human peripheral blood T lymphocytes. These peptides competitively and dose dependently inhibit the activation induced interaction of cofilin with the actin cytoskeleton in vivo. By this approach it was possible to study, for the first time, the functional consequences of this interaction in immunocompetent T cells. The present data demonstrate that inhibition of the actin/cofilin interaction in human T lymphocytes by means of these cofilin derived peptides abolishes receptor cap formation and strongly modulates functional T cell responses such as T cell proliferation, interleukin-2 production, cell surface expression of CD69, gIFN production, and CD95L expression. Importantly, receptor independent activation by PMA and calcium ionophore circumvents these peptide produced inhibitory effects on lymphocyte stimulation and places the cofilin/actin interaction to a proximal step in the cascade of signaling events following T cell activation via surface signals. The present results are novel since as yet no information existed regarding the molecular elements which link cell surface receptor stimulation directly to the resulting reorganization of the actin cytoskeleton. / Die vorliegende Arbeit hat gezeigt, dass Cofilin, ein aktin-bindendes Protein, als Kontrollelement bei der Reorganisation des Aktinzytoskeletts fungiert und damit von besonderer Bedeutung für die Aktivierung von T-Lymphozyten ist. Cofilin wird in seiner Aktivität durch reversible Phosphorylierung reguliert, die induzierbar ist über eine Stimulation durch akzessorische Rezeptoren wie CD2 und CD28. Es konnte gezeigt werden, dass eine Stimulation über akzessorische Rezeptoren zu einer transienten Assoziation von Cofilin mit dem Aktinzytoskelett führt und dass nur die dephosphorylierte Form von Cofilin die Fähigkeit besitzt, in vivo an das Aktinzytoskelett zu binden. Inhibitoren der PI3-Kinase blockieren sowohl die Dephosphorylierung von Cofilin, als auch seine Assoziation mit dem Aktinzytoskelett. Hervorzuheben ist, dass Cofilin, zusammen mit Aktin, PI3-Kinase und einem ihrer Substrate, Phosphatidylinositol 4,5-Bisphosphat (PtdIns(4,5)P2), welches an Cofilin binden kann, mit CD2-Rezeptor-"Caps" kolokalisiert. Die Cofilin/F-Aktin-Interaktion konnte als wesentliches regulatorisches Element für die Rezeptor-"Cap"-bildung und die Stärke der Signalübertragung identifiziert werden. Hierzu wurden maßgeschneiderte zellpermeable Peptide, welche homolog zu aktin-bindenden Motiven der humanen Cofilin-Sequenz sind, in nicht-transformierte humane periphere T-Lymphozyten eingeschleust. Diese Peptide hemmen kompetitiv und dosisabhängig die durch Aktivierung induzierte Interaktion von Cofilin mit dem Aktinzytoskelett in vivo. Dieser Ansatz ermöglichte erstmals die Untersuchung funktioneller Konsequenzen dieser Interaktion in immunkompetenten T-Zellen. Die vorgelegten Ergebnissse zeigen, dass die Blockierung der Interaktion von Cofilin mit dem Aktinzytoskelett in humanen T-Zellen mittels von Cofilin abgeleiteter Peptide die Rezeptor-"Cap"-bildung verhindert, sowie zu einer deutlichen Modulation funktioneller T-Zell-Antworten, wie T-Zellproliferation, Interleukin-2-Produktion, Zelloberflächenexpression von CD69, gIFN-Produktion und Expression von CD95L führt. Hervorzuheben ist, dass rezeptor-unabhängige Aktivierung über PMA und Calciumionophor diese durch Peptide verursachten inhibitorischen Effekte umgeht und die Cofilin/Aktin-Interaktion somit als einen proximalen Schritt in der über Oberflächenmoleküle vermittelten Signalübertragungskaskade in T-Zellen identifiziert. Die vorgestellten Ergebnisse sind neu, da bisher keine Informationen bezüglich der molekularen Elemente existierten, welche eine Stimulation von Zelloberflächenrezeptoren direkt mit der Reorganisation des Aktinzytoskeletts verbinden. T-Lymphozyt Aktivierung <Physiologie> Actin Cofilin Lymphozytentransformation ddc:570
293	The actin cytoskeleton and the nuclear translocation of β-catenin in human oesophageal squamous carcinoma cell lines Dahan, Yael-Leah 16 November 2006 (has links) Student Number : 9906751K - MSc dissertation - School of Molecular and Cell Biology - Faculty of Science / In addition to its crucial role in cell adhesion, β-catenin is also known to augment gene expression by forming a complex with lymphoid enhancer factor/T-cell factor in the nucleus. Unregulated β-catenin expression and/or its increased nuclear presence can lead to abnormal cell proliferation, tumour invasion and metastasis. Pertinent is the fact that the actin cytoskeleton is central to the translocation of several nuclear proteins. This study investigated whether the actin cytoskeleton influences the nuclear translocation of β-catenin in human oesophageal squamous cell carcinoma (HOSCC), a metastatic disease of common occurrence in South Africa. Disruption of the actin cytoskeleton of five moderately differentiated HOSCC cell lines, with cytochalasin D (cytoD), showed that the nuclear β-catenin level was unaltered in SNO, WHCO1 and WHCO5, but decreased in WHCO3 and WHCO6. CytoD treatment did not affect the cytoplasmic/membrane β-catenin level in these cell lines. Further examination of the possible association between the actin cytoskeleton and nuclear β-catenin translocation, required the design and stable transfection, of a vector containing full-length human β-catenin cDNA into one of the HOSCC lines. Stimulation of exogenous β-catenin expression in transfected WHCO1 cells did not increase cellular β-catenin level, nor did the stimulation of endogenous β-catenin expression with DMSO. In most cases (SNO, WHCO1 and WHCO5) the nuclear distribution of β-catenin in HOSCC is independent of a functional actin cytoskeleton, nonetheless there are some exceptions (WHCO3 and WHCO6). The observed variation within the HOSCC lines is possibly due to specific underlying event/s particular to the cell line. The stable level of β-catenin expression could be a consequence of regulatory pathways in WHCO1 compensating for the induced imbalance of β-catenin expression. β-catenin actin cytoskeleton nuclear translocation oesphageal squamous carcinoma cell lines
294	Aspectos moleculares e destino de células tumorais humanas submetidas a alterações de ploidia. / Molecular aspects and fate of human tumor cells undergoing ploidy changes. Oliveira, Maria Aparecida de 06 November 2017 (has links) A instabilidade cromossômica e a aneuploidia são características associadas às células malignas. Sabe-se que essas alterações podem ser resultantes de erros em eventos durante a mitose. Com o objetivo de gerar uma população com ganho de ploidia, utilizamos dois inibidores de fases distintas da mitose. Resultando no aumento da frequência celular em G2/M, ou seja, células com 4 vezes o número de cromossomos (4C) e de células com DNA acima de 4, hipertetraploide. Quantificamos a quantidade de núcleos e demonstramos que o tratamento, especificamente, levou a uma NCI, e não a multinucleação. Ambas linhagens celulares submetidas ao tratamento apresentaram alterações morfológicas, como protrusões de membrana, indicando alterações no citoesquelto. Nas análises de mRNA e da expressão proteica, observamos alterações na regulação da actina, coincidindo com a elevação dos mRNAs de YAP/TAZ, efetores co-transcricionais da via Hippo, regulada por alterações no citoesqueleto de actina. Desde modo, propomos, que o tratamento utilizado é um método eficiente para o estudo de células aneuploides e da NCI, que o citoesqueleto de actina é modulado por esse fenótipo e requer YAP/TAZ, provavelmente para manter a sobrevivência e favorecer a proliferação celular observada após o tratamento. / Chromosomal instability and aneuploidy are characteristics associated with malignant cells. It is known that these changes may be due to errors in events during mitosis. In order to generate a population with gain of ploidy, we used two inhibitors of distinct phases of mitosis. Resulting in increasing cell frequency in G2/M, cells with 4 times the number of chromosomes (4C) and cells with DNA above 4, hypertetraploid. We quantified the number of nuclei and demonstrated that the treatment specifically led to NCI, not multinucleation. Both cell lines submitted to treatment presented morphological alterations, such as membrane protrusions, indicating changes in the cytoskeleton. In the analysis of mRNA and protein expression, we observed alterations in actin regulation, coinciding with the elevation of YAP / TAZ mRNAs, co-transcriptional effectors of the Hippo signaling pathway, regulated by changes in the actin cytoskeleton. We propose, that the treatment used is an efficient method for the study of aneuploid cells as well NCI. Also, the actin cytoskeleton is modulated by that phenotype which requires high YAP / TAZ, probably to maintain cell survival and promote cell proliferation observed. Actin cytoskeleton Aneuploidia Aneuploidy Cancer Câncer Chromosomal instability Citoesqueleto de actina HIPPO HIPPO Instabilidade cromossômica
295	Mécanismes de formation et de fermeture des phagosomes dans les macrophages / Mechanisms of formation and closure of phagosomes in macrophages Marie-Anaïs, Florence 27 September 2016 (has links) La phagocytose est un mécanisme cellulaire essentiel de l’organisme. Elle joue un rôle à la fois dans le maintien de l’homéostasie tissulaire mais également dans le système immunitaire. Ce processus, réalisé par des cellules phagocytaires, telles que les cellules dendritiques, les polymorphonucléaires neutrophiles ou les macrophages, permet l’ingestion et l’élimination quotidienne de particules de grandes tailles (>0,5 µm) : bactéries, champignons ou débris cellulaires. Il est induit par de nombreux récepteurs phagocytaires tels que les récepteurs aux fragments cristallisables des immunoglobulines (FcR) et les récepteurs au complément (CR3). Ceux-ci induisent des cascades de signalisation différentes mais aboutissant, toutes deux, à un remodelage du cytosquelette d’actine et de la membrane plasmique. Il y alors formation d’une coupe phagocytaire entourant et enfermant la particule à internaliser dans un compartiment clos appelé phagosome. Alors que de nombreuses études ont permis de disséquer l’organisation des coupes phagocytaires induites par les FcR, le mécanisme de fermeture des phagosomes n’était pas élucidé. Par ailleurs, les mécanismes moléculaires impliqués dans la formation des phagosomes suite à l’engagement des CR3 sont moins bien décrits. Au cours de ce travail, nous avons analysé le rôle de la dynamine 2, une GTPase impliquée dans les mécanismes de fission des vésicules d’endocytose, au cours de la formation et de la fermeture des phagosomes. Nous avons utilisé un système expérimental original utilisant la microscopie à ondes évanescentes pour montrer, que la dynamine 2 est recrutée avec l’actine dans les coupes phagocytaires en formation et qu’elle s’accumule au site de fermeture des phagosomes dans des macrophages vivants. L’inhibition de son activité GTPase induit une inhibition de l’efficacité de phagocytose et un défaut de la dynamique de l’actine lors de l’extension des coupes phagocytaires. De façon surprenante, la dépolymérisation de l’actine conduit à un défaut de recrutement de la dynamine 2 au site de la phagocytose mettant en évidence une régulation croisée entre la dynamine 2 et l’actine. Enfin cette étude a montré que la dynamine 2 joue un rôle critique dans la scission du phagosome. Dans un second temps, nous avons initié l’étude des mécanismes impliqués dans la régulation de l’activité du récepteur au complément CR3. L’activation de ce récepteur phagocytaire, qui fait partie de la famille des intégrines, requiert un ancrage à l’actine nécessaire à la signalisation vers la polymérisation d’actine et à la formation des coupes phagocytaires. L’ensemble de ces résultats contribue à une meilleure connaissance des mécanismes moléculaires fins impliqués dans la phagocytose. / Phagocytosis is an important cellular mechanism. It plays a role in both the maintenance of tissue homeostasis and in the immune system. This process, performed by phagocytic cells, including dendritic cells, polymorphonuclear neutrophils or macrophages, enables daily ingestion and elimination of large particles (> 0.5 microns) e.g. bacteria, fungi or cellular debris. It is induced by many phagocytic receptors such as the receptors for crystallizable fragments of immunoglobulins (FcR) and complement receptor (CR3). These receptors induce different signaling cascades but ultimately lead to a remodelling of the actin cytoskeleton and the plasma membrane. Next there is the formation of a phagocytic cup which surrounds and encloses the ingested particle in a closed compartment called the phagosome. While many studies have dissected the phagocytic cup organization induced by the FcR, the mechanism of phagosome closure was not understood. Furthermore, the molecular mechanisms involved in phagosome formation following CR3 engagement are less well described. In this work, we analyzed the role of dynamin 2, a GTPase involved in fission mechanisms of endocytosis vesicles, and in the formation and closure of phagosomes. We used an original experimental system using the total internal reflection fluorescence microscopy (TIRFM) to show that dynamin 2 is recruited with actin during phagocytic cup formation and accumulates at the site of phagosome closure in living macrophages. The inhibition of its GTPase activity induced an inhibition of phagocytosis and a defect in actin dynamics during pseudopod extension. Surprisingly, the depolymerization of actin lead to a defective recruitment of dynamin 2 at the phagocytic site showing there is a cross-regulation between dynamin 2 and actin. Finally, this study showed that dynamin 2 plays a critical role in the scission of the phagosome. Secondly, we initiated the study of the mechanisms involved in regulating the activity of the complement receptor CR3. Enabling this phagocytic receptor, part of the integrin family, requires anchoring actin which is necessary for signaling to the actin polymerization and the formation of phagocytic cups. All these results contribute to a better understanding of the molecular mechanisms involved in phagocytosis purposes. Actine Dynamine Phagocytose Pseudopodes Fermeture des phagosomes Macrophages Actin Dynamin Phagocytosis Pseudopods Phagosomes closure Macrophage 571.96
296	Stereocilia Morphogenesis and Maintenance is dependent on the Dynamics of Actin Cytoskeletal Proteins Pallabi Roy (6481925) 10 June 2019 (has links) <p>Age-related hearing loss is an acute health problem affecting people worldwide, often arising due to defects in the proper functioning of sensory hair cells in the inner ear. The apical surface of sensory hair cells contains actin-based protrusions known as stereocilia, which detect sound and head movements. Since hair cells are not regenerated in mammals, it is important to maintain the functioning of stereocilia for the life of an organism to maintain hearing ability. The actin filaments within a stereocilium are extensively crosslinked by various actin crosslinking proteins, which are important for stereocilia development and maintenance. Multiple studies have shown that the stereocilia actin core is exceptionally stable whereas actin is dynamic only at the tips of stereocilia. However, whether the actin crosslinking proteins, which are nearly as abundant as actin itself, are similarly stable or can freely move in and out of the core remains unknown. Loss or mutation of crosslinkers like plastin-1, fascin-2, and XIRP2 causes progressive hearing loss along with stereocilia degeneration while loss of espin prevents stereocilia from even developing properly. Do these phenotypes stem from an unstable stereocilia core? Does crosslinking confer stability to the core? To address these questions, we generated novel transgenic reporter lines to monitor the dynamics of actin in mice carrying fascin-2R109H mutation and espin null mice and also to study the dynamics of actin crosslinkers, in vivo and ex-vivo. We established that actin crosslinkers readily exchange within the highly stable F-actin structure of the stereocilia core. In addition, we determined that stereocilia degeneration in mice carrying fascin-2R109H mutation and espin null mice could possibly occur due to a less stable actin core. These studies suggest that dynamic crosslinks stabilize the core to maintain proper stereocilia functioning. Future work warrants understanding the reason behind the importance of dynamic crosslinks within a stable stereocilia core. Actin stability not only depends on actin crosslinkers, but also on actin filament composition as evident from distinct stereocilia degeneration and progressive hearing loss patterns in hair-cell specific knockout of actin isoforms. Although beta- and gamma- actin polypeptide sequences differ by only 14 four amino acids, whether the latter determine the unique function of each cytoplasmic actin isoform was previously unknown. Here we determined that these four critical amino acids determine the unique functional importance of beta-actin isoform in sensory hair cells. Taken together, our study demonstrates that actin cytoskeletal proteins are important for the morphogenesis and</p> <p>maintenance of stereocilia.</p> Cell Biology Age-related hearing loss Actin Auditory hair cell Stereocilia
297	Cellular and molecular mechanism controlling collective glial cell migration in drosophila / Les mécanismes cellulaire el moléculaire contrôlant la migration collective des cellules Kumar, Arun 28 June 2013 (has links) Le bon fonctionnement des réseaux neuronaux dépend des interactions entre les neurones et les cellules gliales. Alors que de nombreux efforts ont été faits pour comprendre les interactions entre les neurones, moins est connu sur la nature des interactions entre les cellules gliales ; ceci est due à la complexité du système nerveux des vertébrés, qui comprend plus de cellules gliales que de neurones. Cependant, le système nerveux de la drosophile à un rapport neurones-cellules gliales faible, ce qui fait de cet animal simple un modèle idéal pour évaluer ce concept. J’ai utilisé des approches génétiques à résolution cellulaire pour disséquer les mécanismes cellulaires et moléculaires de la migration collective des cellules gliales in vivo. En résumé, mes données révèlent les bases du mécanisme contrôlant la migration cellulaire collective : 1) les cellules du front de migration interagissent entre elles en amont et en aval et 2) N-cad est nécessaire pour une migration optimal de la glie. / The functionality of the complex neural network depends on the interactions between neurons and glia. While many efforts have been made to understand the neuron-neuron interactions, less is known about those amongst glial cells. Due to the complexity of the vertebrate nervous system, which comprises manifold more glia than neurons, it is hard to tackle the role of glia-glia interactions. The nervous system of Drosophila, however, has a lower glia-neuron ratio, which makes this simple animal an ideal model. I use genetic approaches at cellular resolution to dissect the cellular and molecular mechanisms of glial collective migration in vivo. In Sum, I have shown some basic mechanism controlling collective cell migration: 1) cells at the front of the collective interact with each other through anterograde and retrograde bidirectional interaction. 2) N-cad appears necessary for timely movement of glial community. Cellules gliales Migration cellulaire Drosophile Cell migration Glia Drosophila Actin cytoskeleton 572.8
298	Efeitos do bloqueador do canal de cálcio (Verapamil) sobre fibroblastos dérmicos humanos. / Effects of calcium channel blocker (Verapamil) on human dermal fibroblasts. Boggio, Ricardo Frota 16 June 2008 (has links) O excesso de tecido cicatricial (quelóides e cicatrizes hipertróficas) é um defeito do processo de cicatrização das feridas, caracterizado por um aumento na produção da matriz extracelular. Neste estudo, fibroblastos dérmicos humanos tratados com 50 <font face=\"symbol\">mM verapamil apresentaram discreta modificação na distribuição dos microfilamentos e alteraram sua morfologia de fusiformes para estrelados/arredondados. Estes efeitos poderiam estar associados a baixos níveis de cálcio citosólico. Esta hipótese foi confirmada através marcação de fibroblastos tratados com calcium green. Observamos também, que o verapamil inibiu a proliferação celular em 64,4%, aumentou a secreção de MMP1 e diminuiu o colágeno sintetizado pelos fibroblastos, sem aparentes efeitos citotóxicos. O metabolismo celular do cálcio está aparentemente relacionado a produção da matriz extracelular e portanto as patologias hipertróficas da cicatrização (quelóides e cicatrizes hipertróficas) podem responder ao tratamento com bloqueadores do canal de cálcio (verapamil). / Excessive scar tissue (keloids and hypertrophic scars) is a defective wound healing process characterized by overproduction of extracellular matrix. In the present study human dermal fibroblasts treated with 50 <font face=\"symbol\">mM verapamil changed their normal spindle-shaped morphology to stellate/rounded and showed discrete reorganization of microfilaments We hypothesized that these effects would be associated to lower levels of cytosolic Ca2+. Indeed, short time loading with calcium green confirmed that verapamil-treated fibroblasts exhibited lower intracellular calcium levels. We also observed that verapamil decrease cellular proliferation by 64.4%, increase the secretion of MMP1 and decrease synthesis of collagen in cultured fibroblasts. This alterations induced by verapamil are not associated with cytotoxic effects. The cellular calcium metabolism appears to regulate extracellular matrix production and so those hypertrophic disorders of wound healing (keloids and hypertrophic scars) may respond to therapy with calcium antagonist drugs (verapamil). Actin Actina Cálcio Citosólico Colagenase Colágeno Collagen Collagenase Cytosolic calcium Fibroblastos humanos Human fibroblasts Verapamil Verapamil
299	Relier la dynamique de la force de tension cellulaire avec l'architecture de l'actine / Linking cellular tensional force dynamics with actin architecture Andersen, Tomas 22 October 2018 (has links) La stabilité structurale et l'intégrité mécanique sont des éléments clés pour le bon fonctionnement et la préservation des systèmes vivants complexes. Étant en interaction constante avec leur environnement et en ce qui concerne les intrants externes, de tels systèmes doivent pouvoir faire face aux changements afin de prospérer. Ces entrées peuvent affecter le système dans son ensemble. Toute perturbation qui ne peut pas être supportée mécaniquement par le système vivant entraînera un dysfonctionnement crucial ou, en fin de compte, sa mort. Le mécanisme responsable du maintien des conditions physiologiques du système à l'état correct, malgré les variations environnementales, est identifié comme étant l'homéostasie. Plus précisément, le processus connu en mécanobiologie pour préserver l'équilibre mécanique approprié d'un système vivant est appelé homéostasie tensionnelle.Il est important de noter que tout ce qui précède est vrai à la fois à l'échelle du comportement collectif des organismes complexes et jusqu'au niveau de la cellule unique. En fait, c'est en fait cette dernière petite échelle qui nous intéresse. Les cellules font face à des perturbations mécaniques constantes de leur environnement et sont capables de répondre au maintien d'un état mécanique interne relativement stable. L'existence de cet équilibre tensionnel interne est liée à un processus très dynamique avec des boucles de rétroaction constantes entre les machines contractiles biochimiques internes et les forces actives externes générées.Notre intérêt est de comprendre ce mécanisme dynamique en perturbant dynamiquement le système homéostatique tensionnel en étudiant son retour à l'équilibre. / The structural stability and mechanical integrity are key elements for the proper functioning and preservation of complex living systems. Being in constant interaction with their surroundings and subjected to external inputs, such systems need to be able to face changes in order to thrive. These inputs can affect the system both in a localized way or disturb it as a whole. Any perturbations that cannot be mechanically withstand by the living system will result in a crucial malfunctioning or, ultimately, in its death. The mechanism responsible for maintaining the system’s physiological conditions at the proper state, despite environmental variations, is identified as homeostasis. More specifically, the process known in mechanobiology to preserve the appropriate mechanical equilibrium of a living system is called tensional homeostasis.It is important to note that all of the above stated holds true both at the scale of collective behaviour of complex organisms, and all the way down to the single cell level. In fact, it is actually this last small scale which draws our interest. Cells face constant mechanical perturbations from their surrounding and are able to respond accordingly maintaining a relatively stable internal mechanical state. The existence of this internal tensional equilibrium relies on a very dynamic process with constant feedback loops between the internal biochemical contractile machinery and the external active generated forces.Our interest is to understand better this active mechanism by dynamically perturbing the tensional homeostatic system while studying its return to equilibrium. Optogénétique Micropattern Force Energie de contraction Actine Optogenetics Micropattern Force Contractile energy Actin 530
300	Analýza strumpellinu, podjednotky WASH komplexu / Analysis of WASH complex member strumpellin Pácalt, Ondřej January 2019 (has links) Actin polymerization facilitated by the Arp2/3 complex plays a critical role in a wide range of cellular processes such as motility, endocytosis and cargo recycling. Activation and appropriate localization of the Arp2/3 complex is mediated by an interaction with the nucleation-promoting factor (NPF). WASH complex is the major endosomal NPF which plays a crucial role in the cargo recycling back to the trans-Golgi network (TGN) or plasma membrane. It is composed of five subunits: WASH1, SWIP, FAM21, CCDC53 and strumpellin. While WASH1 and FAM21 have been extensively studied, much less is known about strumpellin, a protein causally implicated in the onset of hereditary spastic paraplegia (HSP). This work focuses on strumpellin function in the cells, showing that only full-length protein incorporates into the WASH complex. In a strumpellin knock out cell line, we demonstrated that loss of strumpellin resulted in destabilization of the other WASH complex subunits. Still, an incomplete WASH complex without strumpellin was assembled. Cells also displayed enlarged endosomal subdomains and WASH complex nucleation activity on endosomes was largely diminished as assessed by loss of the actin patches. Finally, the absence of strumpellin was also accompanied by the accumulation of glucose transporter 1 (GLUT1)...

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