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1	Centriole biogenesis in Drosophila melanogaster Yu, Quan Dawn January 2012 (has links) No description available. 576.5 Centrioles ; Drosophila melanogaster
2	The function of Drosophila CP110 in the centriole duplication cycle Franz, Anna January 2012 (has links) No description available. 576.5 Centrioles ; Drosophila
3	Characterisation of the Drosophila Pericentrin-Like Protein (D-PLP) and its role in centrosome and centriole function Martinez-Campos, Maruxa January 2004 (has links) No description available. 576.5
4	Studying centrosome formation and the consequences of centrosome loss in Drosophila melanogaster Baumbach, Janina January 2014 (has links) Centrioles are conserved microtubule-based structures that are required for the formation of two important cellular organelles, centrosomes and cilia. Centrosomes form the poles of the mitotic spindle and consist of a pair of centrioles surrounded by a matrix of pericentriolar material (PCM) that has the ability to nucleate and organise microtubules. Centrosome defects are implicated into a variety of human diseases including cancer, microcephaly, and ciliopathies. Therefore it is of great interest to understand the mechanisms that lead to centrosome formation and the consequences that centrosome defects have in cells. I have analysed the roles of several centrosomal proteins in centrosome assembly in Drosophila. My results indicate that Sak/PLK4 is only required for the initial step of centriole duplication, but has no further role in recruitment of PCM. I show that two proteins important for PCM recruitment, Asterless (Asl) and Spd-2, are preferentially phosphorylated when they are integrated into the centrosome and I identified these phosphorylation sites using a phosphoproteomic screen. A phosphorylation site in Asl is specifically phosphorylated in mitosis, and the phosphorylation state of Spd-2 regulates its maintenance at the centrosome, suggesting that phosphorylation of PCM proteins is an important mechanism to ensure PCM assembly specifically at the centrosome and in mitosis. I have performed a global transcriptional analysis of flies lacking centrosomes or having extra centrosomes to investigate the effects of centrosomal defects on a cellular level. Surprisingly, my results indicate that centrosome defects per se do not dramatically alter cellular physiology. Finally, I demonstrate that in the absence of centrioles acentrosomal microtubule-organising centres (aMTOCs) are formed in an Asl- and Cnn-dependent fashion, and I show that these aMTOCs can contribute to spindle focusing in acentrosomal cells. 572.8
5	Centrosomin self-assembly and centrosomal protein recruitment Bauer, Ruth Anne. January 2005 (has links) (PDF) Thesis (M.S.) -- University of Texas Southwestern Medical Center at Dallas, 2005. / Not embargoed Vita. Bibliography: 24-25.
6	Centriole amplification in brain multiciliated cells : high resolution spatiotemporal dynamics and identification of regulatory mechanisms / Amplification de centrioles dans les cellules multiciliées du cerveau : dynamique spatiotemporelle à haute résolution et identification des mécanismes régulateurs Al Jord, Adel 14 September 2016 (has links) Les cellules multiciliées jouent un rôle essentiel dans la propulsion des fluides physiologiques. Leur dysfonctionnement provoque des maladies chroniques. Contrairement à la plupart des cellules de mammifères qui possèdent un centrosome composé de deux centrioles, les cellules multiciliées possèdent une centaine de centrioles qui servent de base à la nucléation des cils motiles. Les mécanismes d'amplification de centrioles ou de régulation du nombre de centrioles dans ce type cellulaire étaient jusque-là inconnus. Les centrioles nouvellement formés étaient considérés comme apparaissant " de novo ". Une approche de vidéomicroscopie et de microscopie de super-résolution corrélative nous a d'abord permis de déterminer que tous les procentrioles sont générés à partir du centrosome préexistant. Nous démontrons que le centriole fils du centrosome est le site principal de nucléation de 95% de centrioles nouvellement formés dans les cellules multiciliées. Ces résultats réfutent par conséquent l'origine " de novo " des centrioles dans ce type cellulaire. Puis, nous montrons que la machinerie mitotique orchestre la progression spatio-temporelle de la dynamique centriolaire dans ces cellules post-mitotiques et en phase terminale de différentiation. L'amortissement de l'activité de Cdk1 empêche la rentrée en mitose tout en permettant la coordination du nombre de centrioles, leur croissance, et leur désengagement par des transitions phasiques nécessaires à la nucléation de cils motiles. Cette thèse aide à mieux comprendre la différentiation des cellules multiciliées, les ciliopathies, ainsi que l'amplification centriolaire pathologique associée avec le cancer et la microcéphalie. / Multiciliated mammalian cells play a crucial role in the propulsion of physiological fluids. Their dysfunction causes severe chronic diseases. In contrast to the strict centriole number control in cycling cells, multiciliated cell differentiation is marked by the production of up to several hundred centrioles, each nucleating a motile cilium. The mechanisms of centriole amplification or centriole number control in these cells were unknown and new centrioles were thought to appear de novo in the cytoplasm. First, videomicroscopy combined with correlative super-resolution and electron microscopy has enabled us to determine that all procentrioles are generated via runs of nucleation from the pre-existing progenitor cell centrosome. We show that the daughter centriole of the centrosome is the primary nucleation site for 95% of the new centrioles in multiciliated cells and thus refute the de novo hypothesis. Then, we provide evidence of an activation of the mitosis regulatory network during the centriole dynamic. With single cell live imaging and pharmacological modulation of mitosis regulators, we show that the mitosis machinery orchestrates the spatiotemporal progression of centriole amplification in terminally differentiating multiciliated cell progenitors. The fine-tuning of Cdk1 activity prevents mitosis while allowing the timely coordination of centriole number, growth, and disengagement through checkpoint-like phase transitions necessary for subsequent functional motile ciliation. This PhD provides a new paradigm for studying multiciliated cell differentiation, cilia-related diseases and pathological centriole amplification associated with cancer and microcephaly. Centrioles Centriole fils Centrosome Cellules multiciliées Amplification des centrioles Régulateurs de mitose Centriole amplification Multiciliated cells Mitosis regulators 612.8
7	Caractérisation fonctionnelle des protéines des appendices du corps basal et de la zone de transition / Functional caracterisation of basal body appendages and transition zone proteins of cilia Augière, Céline 29 September 2017 (has links) Les cils et les flagelles sont des organites conservés chez les eucaryotes où ils jouent des rôles essentiels et variés comme la motilité et la signalisation cellulaire. La zone de transition est une structure complexe, localisée à la base des cils, indispensable à l'assemblage du cil et pour la sélection des constituants ciliaires. Chez l'Homme, de nombreuses pathologies appelées ciliopathies sont associées à des défauts d'assemblage ou de fonctionnement des cils. Les plus sévères sont liées à des défauts de protéines de la zone de transition. La zone de transition comprend les fibres de transition qui font le lien entre le centriole et la membrane plasmique, puis les liens Y avec une composition protéique complexe organisé en 3 complexes, MKS, NPHP et CEP290 interagissant étroitement entre eux. D'autres protéines, dont CBY conservée des mammifères à la drosophile, s'ajoutent à ces modules mais leur interconnections ne sont pas connues.Au cours de ma thèse, j'ai caractérisé fonctionnellement les orthologues des protéines des fibres de transition et analysé la fonction de nouvelles protéines de la zone de transition en utilisant le modèle de la drosophile. J'ai également caractérisé une protéine impliquée dans la spermatogenèse qui est essentielle pour l'individualisation des spermatides et la fertilité des males.En conclusion, ce travail apporte de nouvelles connaissances sur l'assemblage de la zone de transition et sur le rôle de CBY dans les mécanismes qui contrôlent la ciliogenèse. De plus l'étude de Salto amène à une meilleure compréhension de la spermatogenèse chez la drosophile / Cilia and flagella are highly conserved organelles among eukaryotes species. They are composed of a microtubular cytoskeleton and play essential functions during development and in numerous physiological processes. As a result, in humans, cilia dysfunction leads to a wide range of pathologies, called ciliopathies Cil Spermatogenèse Drosophile Centrioles Appendices distaux Zone de transition Individualisation Cilia Spermatogenesis Drosophila Centrioles Distal appendages Transition zone Individualization 570
8	The sperm centrioles have unique structures and require poc1 for proper formation in Drosophila melanogaster Jo, Kyoung Ha, Jo January 2018 (has links) No description available. Biology
9	Cell Cycle-Dependent Regulation of Centriole Duplication Brownlee, Christopher William January 2013 (has links) Centrosomes are organelles that promote microtubule growth. Normally, a single centrosome duplicates once each cell cycle to guide assembly of a bipolar mitotic spindle, ensuring that each daughter cell inherits an equal complement of the genome and a single centrosome. Centrosomes are composed of a pair of ‘mother-daughter’ centrioles and, during duplication, each mother centriole assembles one daughter at a single site. However, mother centrioles can inappropriately assemble multiple daughters, thereby generating centriole amplification (or overduplication), resulting in multipolar spindle assembly and, consequently, chromosome missegration - a driving force for chromosomal instability/aneuploidy which induces birth defects, miscarriage, and tumorigenesis. We have elucidated how the cell cycle control program regulates the centriole duplication machinery to limit centriole duplication to one event per cell cycle via the cell cycle-dependent regulation of Ana2/STIL and PLK4 degradation. In the case of the centrosome licensing factor Plk4, we found that autophosphorylation promotes its own destruction during interphase, which is then counteracted by the Protein Phosphatase 2A (PP2A) in complex with its Twins (tws) regulatory subunit during mitosis. This promotes stabilization of Plk4 and thus allows for the licensing of the mother centriole, making it competent to duplicate during the proceeding S-phase. While PP2Atws plays a positive role in regulating Plk4 to promote centriole duplication, we found that PP2A complexed with the Well-rounded (wrd) and Widerborst (wdb) regulatory subunits negatively regulates Ana2 by promoting its degradation to limit centriole duplication. PP2Awrd/wdb dephosphorylates numerous serine/threonine residues residing in Ana2, including several CDK phosphorylation consensus motifs. We found that CDK1/cycA and CDK2/cycE phosphorylate these residues to promote Ana2 stabilization from S-phase, the start of centriole duplication, to M-phase, the start of centriole duplication licensing. Interestingly, we found that the tumorigenic SV40 virus protein Small Tumor Antigen (ST) amplifies centrioles by targeting the PP2A complex to stabilize Plk4 as well as Ana2, underscoring the oncogenic importance of these newly discovered centriole duplication pathways. Finally, we shed insight into the mechanism for centriole amplification upon Ana2 stabilization by showing that Ana2 associates with Plk4 to promote Plk4 kinase activity as well as Plk4 stabilization. Centriole Duplication Centrioles Plk4 PP2A STIL Cell Biology & Anatomy Ana2
10	Midbody Anchoring of SNARE and Exocyst Complexes by Centriolin is Required for Completion of Cytokinesis: A Dissertation Gromley, Adam Scott 17 June 2004 (has links) Although much progress has been made in understanding the events that lead to successful cell division, many details of this process remain a mystery. This dissertation presents findings which help to explain events that occur in the latest stages of cytokinesis, with an emphasis on the role of centrosome proteins. The first chapter introduces the novel centrosome protein centriolin. We show that this protein is localized specifically to the subdistal appendages of the maternal centriole in interphase, and it localizes to the midbody during cytokinesis. Disruption of this protein results in a unique cytokinesis defect in which cleavage furrow formation and ingression appear normal, but the cells remain connected by a thin intracellular bridge for extended periods of time. These results lead us to the conclusion that centriolin has an important function in cytokinesis. The second chapter describes our attempt to identify centriolin interacting partners. A yeast two hybrid screen was performed, and the results of this screen revealed an interaction between centriolin and proteins involved in vesicle target specificity and fusion. Further studies of these proteins revealed a novel localization to the midbody in cycling cells and a novel function in the final stages of cytokinesis, similar to centriolin. The third chapter discusses my attempts to clone and characterize a novel GTPase Activating Protein (GAP), which was also discovered in the screen for centriolin interacting proteins. SNARE Proteins Cell Division Cell Cycle Proteins Centrioles GTPase-Activating Proteins Amino Acids, Peptides, and Proteins Cells

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