Global ETD Search

171	FoxO Regulates Microtubule Dynamics and Polarity to Promote Dendrite Branching in Drosophila Sensory Neurons Sears, James Cooper 08 February 2017 (has links) No description available. Biology Biomedical Research Cellular Biology Developmental Biology Genetics Molecular Biology Neurosciences FoxO Dendrites Drosophila EB1 Microtubules Microtubule Polarity Neurodevelopment Development
172	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
173	Coiled-coil domain-containing protein 69 (CCDC69) acts as a scaffold and a microtubule-destabilizing factor to regulate central spindle assembly Pal, Debjani January 1900 (has links) Master of Science / Department of Biochemistry / Qize Wei / Proper regulation of mitosis and cytokinesis is fundamentally important for all living organisms. During anaphase, antiparallel microtubules are bundled between the separating chromosomes, forming the central spindle (also called the spindle midzone), and the myosin contractile ring is assembled at the equatorial cortex. Regulators of central spindle formation and myosin contractile ring assembly are mostly restricted to the interdigitated microtubules of central spindles and they can be collectively called midzone components. It is thought that characteristic microtubule configurations during mitosis and cytokinesis are dictated by the coordinated action of microtubule-stabilizing and -destabilizing factors. Although extensive investigations have focused on understanding the roles of microtubule-bundling/stabilizing factors in controlling central spindle formation, efforts have been lacking in aiming to understand how microtubule-destabilizing factors regulate the assembly of central spindles. This dissertation describes the role of a novel microtubule-destabilizing factor termed CCDC69 (coiled-coil domain-containing protein 69) in controlling the assembly of central spindles and the recruitment of midzone components. Endogenous CCDC69 was localized to the nucleus during interphase and to the central spindle during anaphase. Exogenous expression of CCDC69 in HeLa cells destabilized microtubules and disrupted the formation of bipolar mitotic spindles. RNA interference (RNAi)-mediated knockdown of CCDC69 led to the formation of aberrant central spindles and interfered with the localization of midzone components such as aurora B kinase, protein regulator of cytokinesis 1 (PRC1), MgcRacGAP/HsCYK-4, and pololike kinase 1 (Plk1) at the central spindle. CCDC69 knockdown also decreased equatorial RhoA staining, indicating that CCDC69 deficiency can impair equatorial RhoA activation and ultimately lead to cytokinesis defects. Four coiled-coil domains were found in CCDC69 and the C terminal coiled-coil domain was required for interaction with aurora B. Disruption of aurora B function in HeLa cells by treatment with a small chemical inhibitor led to the mislocalization of CCDC69 at the central spindle. Further, vitro kinase assay showed that Plk1 could phosphorylate CCDC69. Taken together, we propose that CCDC69 acts as a scaffold and a microtubule-destabilizing factor to control the recruitment of midzone components and the assembly of central spindles. Microtubule-destabilizing factor Central spindle assembly Cell Cycle Biology, Cell (0379) Biology, Molecular (0307) Chemistry, Biochemistry (0487)
174	Mechanisms of non-centrosomal MTOC formation at the nucleus in muscle cells / Mécanismes non-centrosomaux impliqués dans la formation du centre organisateur des microtubules au noyaux des cellules musculaires Gimpel, Petra 04 September 2017 (has links) Le juste positionnement du noyau durant la formation musculaire semble important pour la fonction musculaire et des défauts ont été associés à plusieurs maladies musculaires. Le positionnement nucléaire dépend des microtubules (MTs), qui sont réorganisés depuis le centrosome, dans les myoblastes proliférants, vers l’enveloppe nucléaire (EN), dans les myotubes différenciés. Cette réorganisation s'accompagne de la redistribution des protéines centrosomales vers l’EN qui adopte le rôle de centre organisateur des microtubules (MTOC) lors de la différenciation myogénique. Néanmoins, les mécanismes sous-jacents restent inconnus. Ici, nous avons identifié les protéines Nesprin-1 et Sun1/2, localisées respectivement à la membrane nucléaire externe et interne, comme impliquées dans le recrutement de la fonction MTOC à l’EN. Les cellules déficientes en Nesprin-1 ou Sun1/2 ont montré une localisation altérée des protéines centrosomales dans le cytoplasme et l’absence des MTs depuis l’EN. De plus, Nesprin-1alpha, une myo-isoforme de Nesprin-1, s’associait aux protéines centrosomales Akap450, Pericentrin et Pcm1 dans les myotubes C2C12 et était suffisante pour corriger les défauts observés dans des cellules déplétées en Nesprin-1. Parmi les protéines centrosomales recrutées par Nesprin-1alpha, seule Akap450 semble nécessaire à la nucléation des MTs à l’EN. Ce processus, médié par Akap450 et Nesprin-1alpha, s’est avéré important pour le positionnement nucléaire lors du développement des myotubes. Ces résultats renforcent notre compréhension sur le lien causal entre des défauts lors de la formation du MTOC à l’EN et des défauts de positionnement nucléaire dans les dystrophies musculaires. / The accurate position of the nucleus during skeletal muscle formation seems to be important for muscle function, and defects have been associated with numerous muscle diseases. Nuclear positioning requires microtubules (MTs) which are reorganized from the centrosome in proliferating myoblasts to the nuclear envelope (NE) in differentiated myotubes. This dramatic MT reorganization is accompanied by a redistribution of proteins from the centrosome to the NE which thus takes over the function as a microtubule-organizing center (MTOC) during myogenic differentiation. However, the underlying mechanisms are still unknown. Here, we identified Nesprin-1 and Sun1/2, outer and inner nuclear membrane proteins, respectively, to be involved in the recruitment of MTOC function to the NE. Nesprin-1 or Sun1/2 deficient cells displayed mislocalization of centrosomal proteins to the cytoplasm and failed to regrow MTs from the NE. Moreover, the muscle-specific isoform of Nesprin-1, namely Nesprin-1alpha, was shown to be highly associated with the centrosomal proteins Akap450, Pericentrin and Pcm1 in C2C12 myotubes and to be sufficient to rescue the observed defects in Nesprin-1 depleted cells. Among the centrosomal proteins localizing at the NE during myogenic differentiation, solely Akap450 seemed to be required for MT nucleation. Akap450-Nesprin-1alpha-mediated MT nucleation from the NE was demonstrated to play an important role in nuclear positioning during myotube formation. These findings strengthen our understanding on how defects in MTOC formation at the NE can link to nuclear positioning defects in muscular dystrophies. Muscle squelettique Nesprin-1alpha Akap450 Centrosome L'enveloppe Nucléaire Centre organisateur des microtubules Possitionnement du noyau Nuclear envelope Centrosome 571.6
175	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) (PDF) 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. Tubulin Binding Cofactors C (TBCC) Voie de repliement de la tubuline Microtubule Dynamique des microtubules Cycle cellulaire Cancer du sein Agents antimicrotubulaires
176	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) (PDF) 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. Tubulin Binding Cofactors C (TBCC) Voie de repliement de la tubuline Microtubule Dynamique des microtubules Cycle cellulaire Cancer du sein Agents antimicrotubulaires
177	Regulation of Mitotic Spindle Assembly in Caenorhabditis elegans Embryos / Regulation der Bildung der mitotischen Spindel in Caenorhabditis elegans embryos Schlaitz, Anne-Lore 10 June 2007 (has links) (PDF) The mitotic spindle is a bipolar microtubule-based structure that mediates proper cell division by segregating the genetic material and by positioning the cytokinesis cleavage plane. Spindle assembly is a complex process, involving the modulation of microtubule dynamics, microtubule focusing at spindle poles and the formation of stable microtubule attachments to chromosomes. The cellular events leading to spindle formation are highly regulated, and mitotic kinases have been implicated in many aspects of this process. However, little is known about their counteracting phosphatases. A screen for genes required for early embryonic cell divisions in C. elegans identified rsa-1 (for regulator of spindle assembly 1), a putative Protein Phosphatase 2A (PP2A) regulatory subunit whose silencing causes defects in spindle formation. Upon rsa-1(RNAi), spindle poles collapse onto each other and microtubule amounts are strongly reduced. My thesis work demonstrates that RSA-1 indeed functions as a PP2A regulatory subunit. RSA-1 associates with the PP2A enzyme and recruits it to centrosomes. The centrosome binding of PP2A furthermore requires the new protein RSA-2 as well as the core centrosomal protein SPD-5 and is based on a hierarchical protein-protein interaction pathway. When PP2A is lacking at centrosomes after rsa-1(RNAi), the centrosomal amounts of two critical mitotic effectors, the microtubule destabilizer KLP-7 and the kinetochore microtubule stabilizer TPXL-1, are altered. KLP-7 is increased, which may account for the reduction of microtubule outgrowth from centrosomes in rsa-1(RNAi) embryos. TPXL-1 is lost from centrosomes, which may explain why spindle poles collapse in the absence of RSA-1. TPXL-1 physically associates with RSA-1 and RSA-2, suggesting that it is a direct target of PP2A. In summary, this work defines the role of a novel PP2A complex in mitotic spindle assembly and suggests a model for how different microtubule re-organization steps might be coordinated during spindle formation. mitosis spindle assembly protein phosphatase 2A centrosome microtubule Caenorhabditis elegans embryo Mitose mitotische Spindel Protein Phosphatase 2A Centrosom Mikrotubulus Caenorhabditis elegans Embryo ddc:570 rvk:WG 2100
178	Characterization of specific domains of the cellulose and chitin synthases from pathogenic oomycetes Brown, Christian January 2015 (has links) Some oomycetes species are severe pathogens of fish or crops. As such, they are responsible for important losses in the aquaculture industry as well as in agriculture. Saprolegnia parasitica is a major concern in aquaculture as there is currently no method available for controlling the diseases caused by this microorganism. The cell wall is an extracellular matrix composed essentially of polysaccharides, whose integrity is required for oomycete viability. Thus, the enzymes involved in the biosynthesis of cell wall components, such as cellulose and chitin synthases, represent ideal targets for disease control. However, the biochemical properties of these enzymes are poorly understood, which limits our capacity to develop specific inhibitors that can be used for blocking the growth of pathogenic oomycetes. In our work, we have used Saprolegnia monoica as a model species for oomycetes to characterize two types of domains that occur specifically in oomycete carbohydrate synthases: the Pleckstrin Homology (PH) domain of a cellulose synthase and the so-called ‘Microtubule Interacting and Trafficking’ (MIT) domain of chitin synthases. In addition, the chitin synthase activity of the oomycete phytopathogen Aphanomyces euteiches was characterized in vitro using biochemical approaches. The results from our in vitro investigations revealed that the PH domain of the oomycete cellulose synthase binds to phosphoinositides, microtubules and F-actin. In addition, cell biology approaches were used to demonstrate that the PH domain co-localize with F-actin in vivo. The structure of the MIT domain of chitin synthase (CHS) 1 was solved by NMR. In vitro binding assays performed on recombinant MIT domains from CHS 1 and CHS 2 demonstrated that both proteins strongly interact with phosphatidic acid in vitro. These results were further supported by in silico data where biomimetic membranes composed of different phospholipids were designed for interaction studies. The use of a yeast-two-hybrid approach suggested that the MIT domain of CHS 2 interacts with the delta subunit of Adaptor Protein 3, which is involved in protein trafficking. These data support a role of the MIT domains in the cellular targeting of CHS proteins. Our biochemical data on the characterization of the chitin synthase activity of A. euteiches suggest the existence of two distinct enzymes responsible for the formation of water soluble and insoluble chitosaccharides, which is consistent with the existence of two putative CHS genes in the genome of this species. Altogether our data support a role of the PH domain of cellulose synthase and MIT domains of CHS in membrane trafficking and cellular location. / <p>QC 20151014</p>
179	Regulation of tubulin heterodimer partitioning during interphase and mitosis / Holmfeldt, Per, January 2008 (has links) Diss. (sammanfattning) Umeå : Umeå universitet, 2008. / Härtill 4 uppsatser.
180	Survivin expression after traumatic brain injury potential roles in neuroprotection / Johnson, Erik Andrew. January 2004 (has links) Thesis (Ph.D.)--University of Florida, 2004. / Typescript. Title from title page of source document. Document formatted into pages; contains 87 pages. Includes Vita. Includes bibliographical references.

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