Global ETD Search

51	Selective histone deacetlyase inhibition decreases disease in lupus-prone mice Castaneda, Adrian Lance 15 September 2016 (has links) Histone deacetylase 6 (HDAC6) is a cytoplasmic enzyme that acetylates several proteins that are involved in the immune response. HDAC6 inhibition has been shown in various models to decrease inflammation by altering various proteins involved in the dysregulation of B and T cell responses. In our current studies we sought to determine if HDAC6 inhibition would decrease disease in lupus-prone mice using two murine mouse models of SLE: MRL/lpr mice and NZB/W F1 mice. Both mouse models were fed a rodent diet formulated with the selective HDAC6 inhibitor ACY-738 (N-hydroxy-2-(1-phenylcycloproylamino) pyrimidine-5-carboxamide). NZBW mice received 18 weeks of treatment starting at 16-weeks-of-age and had an average of 57.3 +/- 14.6 ng/mL of ACY-738 in the plasma. MRL/lpr mice received 7 weeks of treatment starting at 11-weeks-of-age and had an average of 78.5 +/- 17.3 ng/mL of ACY-738 in the plasma. Controls received either dexamethasone 5x a week or were left untreated. As the mice aged, body weight, urine protein, and blood sera was collected weekly. Spleen cells were isolated following euthanasia for flow cytometry and kidneys were also collected for histological analyses. We found that in both mouse models that mice treated with ACY-738 had reduced splenic weight and IgG immunoglobulin isotypes. MRL/lpr mice that were treated with ACY-738 had a reduction in the number of IL-17+, ROR-gamma-t TH17 cells. NZBW/ F1 mice that received ACY-738 treatment also had a reduction in the TH17 cells and we observed a significant reduction in kidney pathology. Selective HDAC6 targeting may warrant future investigations as a potential therapeutic target for the treatment of SLE. / Master of Science SLE T cells α -tubulin Autoimmunity HDACi HDAC6
52	Mécanisme de l’hyperacétylation de la tubuline en réponse aux stress / Mechanism of stress-induced tubulin hyperacetylation Mackeh, Rafah 06 December 2013 (has links) Au-delà de sa présence sur les microtubules stables, l'acétylation de l’-tubuline peut être augmentée après exposition des cellules aux UV ou après une carence en nutriments, phénomène que l’on appelle « hyperacétylation ». Cependant, le mécanisme d’induction de cette hyperacétylation est encore inconnu. Dans cette étude, nous montrons que l’hyperacétylation de la tubuline est une réponse générale aux stress cellulaire, et nous avons cherché à caractériser cette réponse, à identifier la voie de signalisation activée par le stress et conduisant à cette réponse, et à étudier la signification biologique de ce phénomène rapide et réversible. Nous avons trouvé que MEC-17/-TAT1, l’acétyltransférease majeure de l’ tubuline, est une enzyme nécessaire à l’induction de l’hyperacétylation en réponse aux stress, et qu'elle est régulée, à l’état basal par une autre acétyltransférase appelée p300. Au cours du stress, nous montrons que l'augmentation de la production des espèces réactives de l'oxygène (ROS), conduit à l'activation de la kinase « AMP-activated protein kinase (AMPK) », qui, à son tour provoque la phosphorylation de MEC-17, et probablement son activation. Enfin, nous montrons que l’hyperacétylation de la tubuline induite par le stress, participe à la survie des cellules dans des conditions de stress et à l'induction de l'autophagie de survie. / Beyond its presence in stable microtubules, -tubulin acetylation can be boosted after UV exposure or after nutrient deprivation but the mechanisms of this hyperacetylation are still unknown. In this study, we show that tubulin hyperacetylation is a general cell stress response, and aimed to characterize this response, to identify the stress-activated signaling pathway leading to its induction and the biological significance of this rapid and reversible phenomenon. We found that the major tubulin acetyltransferase MEC-17/-TAT1 is the main enzyme required for mediating tubulin hyperacetylation upon stress, and that it is regulated under normal conditions by the acetyltransferase p300. Upon stress, we show that the increased production of reactive oxygen species (ROS), leads to the activation of AMP-activated protein kinase (AMPK), which in turn mediates MEC-17 phosphorylation, and probably its subsequent activation. Finally, we show that tubulin hyperacetylation induced upon stress participate in cell survival under stress conditions and in the induction of protective autophagy. Microtubules Tubuline Acétyl-tubuline MEC-17/-TAT1 P300 ROS AMPK Microtubules Tubulin Acetyl-tubulin MEC-17/-TAT1 P300 ROS AMPK
53	Molecular dissection of established and proposed members of the Op18/Stathmin family of tubulin binding proteins / Brännström, Kristoffer, January 2009 (has links) Diss. (sammanfattning) Umeå : Univ., 2009. / Härtill 4 uppsatser.
54	Mechanismen der sensiblen Mechanotransduktion in Kardiomyozyten Schreiber, Anna 18 October 2016 (has links) Die vorgelegte Dissertationsschrift dient der Identifizierung des Mechanismus, über welchen neonatale Kardiomyozyten der Ratte biaxialen zyklischen Stretch wahrnehmen. Angriffspunkt dafür bildeten sowohl Stretch Activated Ion Channels (SAIC) als auch die mit Integrinen assoziierte Focal Adhesion Kinase (FAK). Die Inhibition der SAIC erfolgte mit Gadolinium und eine Blockade der FAK konnte durch den FAK-Inhibitor II erreicht werden. Eigens angelegte Zellkulturen wurden unter definierten Parametern für 24 Stunden unter Einwirkung genannter Stoffe gestretcht und anschließend einer Analyse mittels Immunfluoreszenz und Western Blot unterzogen. Gestretchte Kardiomyozyten richteten sich schräg zur Achse der einwirkenden Kraft aus und wiesen eine Polarisierung von Connexin 43 auf, außerdem zeigte sich dessen gesteigerte Expression. Durch die Blockade der FAK konnte lediglich eine aufgehobene Polarisierung von Connexin 43 bei unveränderter Expression und Ausrichtung der Kardiomyozyten festgestellt werden. Auch die Mikrotubuli veränderten nach Stretch ihre Orientierung bezogen auf die Zellachse. Die zunächst annähernde Parallelität der Fasern zeigte sich nach Inhibition der FAK deutlich aufgelockert. Für die Aktinfilamente konnte dies nicht nachgewiesen werden. Die Integrine dienen demnach der Wahrnehmung von Stretch und vermitteln die Polarisierung von Connexin 43 sowie die Orientierung der Mikrotubuli über die FAK. Für die anderen genannten Prozesse ist die Aktivierung eines FAK-unabhängigen Integrin-Signalweges denkbar. Gadolinium hatte insgesamt keinen Effekt auf beschriebene Veränderungen, sodass ein Einfluss der SAIC auf Stretch-induzierte Veränderungen in Kardiomyozyten ausgeschlossen werden konnte. Gleichzeitig konnte durch die Beobachtung der Polarisierung von Microtubule Organizing Center, Kinesin und Golgi-Apparat die Hypothese der sich durch Stretch orientierenden neonatalen Kardiomyozyte unterstützt werden, welche die Voraussetzung für die Anordnung von Connexin 43 an den Zellpolen darstellen könnte. Sowohl die Selbstorganisation des Myokards im Rahmen der Embryogenese als auch die Pathophysiologie verschiedener kardialer Erkrankungen könnte dadurch womöglich besser verstanden werden. info:eu-repo/classification/ddc/610 ddc:610
55	Regulační mechanizmy nukleace centrozomálních mikrotubulů / Regulatory mechanisms of centrosomal microtubule nucleation Klebanovych, Anastasiya January 2021 (has links) The spatio-temporal organization and dynamic behavior of microtubules accurately react to cellular needs during intracellular transport, signal transduction, growth, division, and differentiation. The cell generates centrosomal microtubules de novo with the help of γ-tubulin complexes (γTuRCs). The post-translational modifications fine-tune microtubule nucleation by targeting the proteins, interacting with γTuRCs. However, the exact signaling pathways, regulating centrosomal microtubule nucleation, remain mostly unknown. In the presented thesis, we functionally characterized protein tyrosine phosphatase SHP-1 and E3 UFM-protein ligase 1 (UFL1) with its interacting protein CDK5RAP3 (C53) in the regulation of centrosomal microtubule nucleation. We also elucidated the role of actin regulatory protein profilin 1 in this process. We found that SHP-1 formed complexes with γTuRC proteins and negatively regulated microtubule nucleation by modulating the amount of γ-tubulin/γTuRC at the centrosomes in bone marrow-derived mast cells (BMMCs). We suggested a novel mechanism with centrosomal tyrosine-phosphorylated Syk kinase, targeted by SHP-1 during Ag-induced BMMCs activation, regulating microtubules. We showed for the first time that UFL1/C53 protein complex is involved in the regulation of microtubule...
56	The Role of Tubulin Polyglycylation and Polyglutamylation in Ciliary Mechanics Alvarez Viar, Gonzalo 13 December 2021 (has links) Tubulin post-translational modifications (tPTMs) are currently studied as vital, yet obscure, cytoskeletal regulators. Their regulatory function relies on the spatiotemporal control over the activity of multiple tubulin modifying enzymes that functionalize microtubules, enabling their differentiation. The cilium, one of the organelles with the richest tPTMs diversity, has been studied with determination for the last decades, allowing the interrogation of the molecular processes that give rise to its function. The inner structure of this thin organelle, the axoneme, comprises a microtubule scaffold periodically decorated with macromolecular complexes whose characterization has been achieved with pseudoatomic detail. The molecular distribution and mechanism of action of tPTMs in cilia remain elusive. Using a combination of immunolabelling and cryoelectron tomography we interrogated the molecular function two tPTMs in the axonemal context. We showed that tubulin polyglycylation spanned most of the microtubular surface and was required for axonemal dynein activity regulation and male fertility. Additionally, there was an enrichment of polyglutamylation on a single microtubule protofilament, forming a pattern complementary to that of polyglycylation, that was required for proper coupling of microtubule sliding and bending forces during ciliary beating. info:eu-repo/classification/ddc/570 ddc:570
57	Characterization of γ-tubulin complex proteins and investigation of the regulation of nuclear proteasome localization in Aspergillus nidulans Xiong, Yi 27 July 2011 (has links) No description available. Cellular Biology Genetics &947 -Tubulin &947 -Tubulin Complex protein microtubule mitosis proteasome Cut8 nuclear pores
58	Impact of tululin binding cofactor C (TBCC) on microtubule mass and dynamics, cell cycle, tumor growth and response to chemotherapy in breast cancer / Effets de la protéine tubulin binding cofactor C (TBCC) sur la masse et la dynamique microtubulaire, le cycle cellulaire, la croissance tumorale et la réponse à la chimiothérapie dans le cancer du sein Hage-Sleiman, Rouba 11 June 2010 (has links) La mise en conformation de l’α et β tubulines en hétérodimeres polymérisables nécessite l’intervention de cinq protéines « Tubulin Binding Cofactors » (TBCA a TBCE) dont TBCC qui joue un rôle indispensable. Dans des cellules humaines d’adénocarcinome mammaire, nous avons modifié le niveau d’expression de TBCC et nous avons montre que ceci avait un impact sur le contenu des fractions de tubuline, la dynamique des microtubules ainsi que sur le phénotype et chimiosensibilité des cellules. La distribution en cycle cellulaire et les durées de la mitose et de la phase S ont été altérées. La modification de TBCC avait un faible effet sur la vitesse de prolifération in vitro par contre les cellules présentaient des différences significatives de croissance tumorale in vivo. Les réponses aux agents antimicrotubulaires et à la gemcitabine ont montrées une chimiosensibilité dépendante de la distribution en cycle cellulaire. Tous ces résultats montrent l’importance de la régulation du contenu en tubulines et l’impact de ceci sur le comportement de la cellule en général et vis-à-vis des traitements / The proper folding pathway of α and β-tubulin into the α/β-tubulin heterodimers involve five Tubulin Binding Cofactors (TBCA to TBCE). TBCC plays a crucial role in the formation of polymerization-competent the α/β-tubulin heterodimers. To evaluate the impact of microtubule mass and dynamics on the phenotype and chemosensitivity of breast cancer cells, we targeted TBCC in human breast adenocarcinoma and developed variants of breast cancer cells with modified content of TBCC. We have shown that the modifications in TBCC expression level influenced tubulin fraction distribution and microtubule dynamics. Cell cycle distribution and the durations of mitosis and S-phase were altered. The proliferation rate in vitro was slightly modified whereas in vivo the TBCC variants presented major differences in tumor growth capacity. Chemosensitivity to antimicrotubule agents (paclitaxel and vinorelbine) as well as to gemcitabine was observed to be dependent on the cell cycle distribution of the TBCC variants. These results underline the essential role of fine tuned regulation of tubulin content in tumor cells and the major impact of dysregulation of tubulin dimer content on tumor cell phenotype, cell cycle progression and response to chemotherapy. A better understanding of how the microtubule cytoskeleton is dysregulated in cancer cells would greatly contribute to a better understanding of tumor cell biology and characterization of resistant phenotypes Tubulin Binding Cofactors C (TBCC) Voie de repliement de la tubuline Microtubule Dynamique des microtubules Cycle cellulaire Cancer du sein Agents antimicrotubulaires Tubulin Binding Cofactors C (TBCC) Tubulin folding pathway Microtubule Microtubule dynamics Cell cycle Breast cancer Antimicrotubule agents 616.994
59	Úloha autofagie a vybraných izotypů beta-tubulinu v rezistenci k taxanům u nádorových linií prsu / The role of autophagy and selected beta-tubulin isotypes in taxane resistance in breast cancer cells Kábelová, Adéla January 2015 (has links) Drug resistance in cancer cells is a frequent cause of breast cancer therapy failure. The aim of this thesis was to elucidate mechanisms of resistance to taxanes, that are used in therapy of various types of cancer, including breast cancer. We particularly assessed the role of autophagy and changes in βII- and βIII isotype gene expression in development of taxane resistance. As model of breast cancer we used human sensitive cell lines SK-BR-3, MCF-7 a T47-D and resistant sublines SK-BR-3-PAC/REZ a MCF-7- PAC/REZ which grow in paclitaxel concentration lethal for sensitive sublines. In cell lines SK-BR-3 and MCF-7, taxane application decreased the level of autophagy, however in cell line T47-D led to its activation. We detected no difference between basal levels of autophagy in sensitive subline SK-BR-3 compared to resistant subline SK-BR-3-PAC/REZ, but we observed increased basal level of autophagy in sensitive subline MCF-7 compared to the resistant subline. Increase or decrease level of autophagy did not affect taxane resistance, except activation of autophagy in resistant subline SK-BR-3-PAC/REZ, that further increased the resistance to paclitaxel. Taxane application in cell line T47-D increased the levels of βII- and βIII-tubuline expression, however we did not find any similar effect in other tested...
60	Regulation of tubulin heterodimer partitioning during interphase and mitosis / Holmfeldt, Per, January 2008 (has links) Diss. (sammanfattning) Umeå : Umeå universitet, 2008. / Härtill 4 uppsatser.

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