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61	A Tale of Two Projects: Basis for Centrosome Amplification after DNA Damage and Practical Assessment of Photodamage in Live-Cell Imaging: A Dissertation Douthwright, Stephen 02 April 2015 (has links) This thesis comprises two separate studies that focus on the consequences of cellular damage. The first investigates the effects of DNA damage on centriole behavior and the second characterizes phototoxicity during live-cell imaging. Cancer treatments such as ionizing radiation and/or chemotherapeutic DNA damaging agents are intended to kill tumor cells, but they also damage normal proliferating cells. Although centrosome amplification after DNA damage is a well-established phenomenon for transformed cells, it is not fully understood in untransformed cells. The presence of extra centrosomes in normal cell populations raises the chances of genomic instability, thus posing additional threats to patients undergoing these therapies. I characterized centriole behavior after DNA damage in synchronized untransformed (RPE1) human cells. Treatment with the radiomimetic drug, Doxorubicin, prolongs G2 phase by at least 72hrs, where 52% of cells display disengaged centrioles and 10% contain extra centrioles. This disengagement is mediated by Plk and APC/C activities both singly and in combination. Disengaged centrioles are associated with maturation markers suggesting they are capable of organizing spindle poles. Despite the high incidence of centriole disengagement, only a small percentage of centrioles reduplicate due to p53/p21 dependent inhibition of Cdk2 activity. Although all cells become prolonged in G2 phase, 14% eventually go through mitosis, of which 26% contain disengaged or extra centrioles. In addition to cancer treatments, cellular damage can be acquired from various external conditions. Short wavelengths of light are known to be toxic to living cells, but are commonly used during live-cell microscopy to excite fluorescent proteins. I characterized the phototoxic effects of blue (488nm) and green (546nm) light on cell cycle progression in RPE1. For unlabeled cells, I found that exposure to green light is far less toxic than blue light, but is not benign. However, the presence of fluorescent proteins led to increased sensitivity to both blue and green light. For 488nm irradiations, spreading the total irradiation durations out into a series of 10s pulses or conducting single longer, but lower intensity, exposures made no significant changes in phototoxicity. However, reducing oxidative stress by culturing cells at physiological (~3%) oxygen, or treatment with a water-soluble antioxidant, Trolox, greatly improved the cells tolerance to blue light. Collectively, my work offers an explanation for centrosome amplification after DNA damage and demonstrates the importance of proper centriole regulation in untransformed human cells. Further, it provides a practical assessment of photodamage during live-cell imaging. DNA Damage Centrioles Centrosome Molecular Imaging Dissertations, UMMS Cell Biology Cellular and Molecular Physiology
62	Examining the Regulation and Functions of Centrosomal Mps1 Marquardt, Joseph R. 11 August 2017 (has links) No description available. Molecular Biology Cellular Biology Genetics Biology Mps1 cell cycle centrosome centriole kinetochore primary cilium cell biology
63	The role of [Beta]1-integrins in centrosomal stability / Ong, Yen May. January 2008 (has links) No description available. Centrosomes. Centrosome -- physiology. Microtubules -- metabolism. Microtubules. Antigens, CD29 -- physiology. CD antigens.
64	Discerning the Role of LMO4 as a Global Modulator of G2/M Cell Cycle Progression and Centrosome Cycle in Breast Cancer Cells Montanez-Wiscovich, Marjorie E. 23 January 2010 (has links) No description available. Molecular Biology Oncology Pharmacology LMO4 gene expression ErbB2/HER2/Neu centrosome
65	Mps1 and Plk4 Cooperate to Regulate Centriole Assembly Bliemeister, Amanda Nichole 30 December 2014 (has links) No description available. Molecular Biology Cellular Biology
66	NPM/B23:THE EFFECTOR OF CDK2 IN THE CONTROL OF CENTROSOME DUPLICATION AND mRNA PROCESSING TOKUYAMA, YUKARI January 2004 (has links) No description available. Biology, Cell CDK2 centrosome duplication genomic instability pre-mRNA splicing nuclear speckles
67	LXRα interacts with the Centrosome-Associated Protein 350 (CAP350) Hassani, Omar 07 1900 (has links) <p> The Liver X receptor (LXR) is a type II nuclear receptor that is known to be a master regulator of cholesterol levels in the body through its transcriptional control of target genes involved in the handling of cholesterol. The regulation of LXR occurs at multiple levels including ligand and protein availability, post-translational modifications, protein-protein interactions with various cofactors and/or chaperones and a new concept of regulation that involves compartmentalization. This involves the establishment of regions where proteins can be active or inactive. Type II nuclear receptors have recently been found to shuttle between the cytoplasm and the nucleus, thus a compartmentalization component is likely to be involved. It was recently implicated that the centrosome-associated protein 350 (CAP350) can sequester PPARa. into nuclear bodies, and to regions in the cytoplasm. The significance of this appears to be the control of PPAR action. CAP350 is a large protein that has the ability to interact with nuclear receptors via an LXXLL motif, and with the cytoskeleton via a CAP-Giy motif. CAP350 is suggested to play a role in the organization of nuclear receptors in the nucleus, and their retention in compartments. In this report, LXRa. was confirmed to interact with CAP350 in vitro, using a GST-binding assay. Utilizing fluorescent protein chimeras with both nuclear receptors and CAP350 allowed the monitoring of this interaction in vivo. CAP350 was observed to form nuclear bodies that were capable of recruiting LXRa.. This recruitment was dependant on the integrity of the LXXLL motif. The mutated LXXLL motif of CAP350 was not able to colocalize with LXRa.. The significance of this interaction remains unknown. It is likely to be similar to that observed with PPARa., since the nuclear bodies formed by CAP350 seem to correspond to transcriptionally silent regions in the nucleus. </p> / Thesis / Master of Science (MSc) Centrosome-Associated Protein CAP350 Liver X receptor type II nuclear receptor
68	Etudes in vivo des malformations du développement cortical associées à des mutations dans le gène TUBG1 / In-vivo studies of malformations of cortical development associated with mutations in TUBG1 Ivanova, Ekaterina 14 September 2018 (has links) Des mutations hétérozygotes faux-sens dans le gène de la tubuline gamma TUBG1, ont été identifiées dans le contexte des malformations du développement cortical, associées à une déficience intellectuelle et à l'épilepsie. Ici, nous avons étudié par la technique d’électroporation in-utero et par des études in vivo, l’effet de quatre de ces variantes sur le développement cortical. Nous montrons que les mutations dans TUBG1 affectent le positionnement neuronal dans la plaque corticale, en perturbant la locomotion des neurones nouvellement nés, mais sans affecter la neurogenèse. Nous proposons que la γ-tubuline mutante affecte le fonctionnement global de ses complexes, et en particulier leur rôle dans la régulation de la dynamique des microtubules. De plus, nous avons développé un modèle de souris knock-in Tubg1Y92C/+ et évalué les conséquences de la mutation sur le développement cortical, les caractéristiques neuroanatomiques et le comportement. Les souris mutantes présentent une microcéphalie globale, des anomalies du néocortex et de l'hippocampe, des altérations du comportement et une susceptibilité épileptique. Ainsi, nous montrons que les souris Tubg1Y92C/+ miment au moins partiellement le phénotype humain et représentent donc un modèle pertinent pour d'autres investigations de la physiopathologie des malformations du développement cortical. / Missense heterozygous variants in the gamma tubulin gene TUBG1 have been linked to malformations of cortical development, associated with intellectual disability and epilepsy. Here, we investigated through in-utero electroporation and in-vivo studies, how four of these variants affect cortical development. We show that TUBG1 mutants affect neuronal positioning within the cortical wall, by a disrupting the locomotion of newly born neurons but without affecting neurogenesis. We propose that mutant γ-tubulin affects overall functioning of γ-tubulin complexes, and in particular their role in the regulation of microtubule dynamics. Additionally, we developed a knock-in Tubg1Y92C/+ model and assessed consequences of the mutation on cortical development, neuroanatomical features and behaviour. Mutant mice present with global microcephaly, neocortical and hippocampal abnormalities, behavioural alterations and epileptic susceptibility. Thus, we show that Tubg1Y92C/+ mice partially mimic the human phenotype and therefore represent a relevant model for further investigations of the physiopathology of malformations of cortical development. Dynamique des microtubules, γ-tubuline Centrosome Knock-in Modèle murin Malformations du développement cortical Cortex Hippocampe Électroporation in-utero Microtubule dynamics, γ-tubulin Centrosome Knock-in Mouse model Malformations of cortical development Cortex Hippocampus In-utero electroporation 571.8 573.8
69	The role of a trimeric coiled coil protein in WASH complex assembly / Rôle d’une protéine trimérique à superhélice dans l’assemblage du complexe WASH Visweshwaran, Sai Prasanna 22 September 2017 (has links) Le complexe Arp2/3 génère des réseaux d’actine branchés, qui produisent une forcée de poussée permettant à la cellule de remodeler ses membranes. Le complexe WASH active le complexe Arp2/3 à la surface des endosomes et facilite ainsi la scission membranaire des intermédiaires de transports contenants des récepteurs internalisés tels que les intégrines α5β1. De ce fait, le complexe WASH en favorisant le recyclage des intégrines, joue un rôle crucial dans l’invasion des cellules tumorales durant la progression tumorale. Cependant, le mécanisme d’assemblage du complexe WASH est inconnu. Dans cette étude, nous rapportons l’identification du premier facteur d’assemblage du complexe WASH. Nous avons identifié la protéine HSBP1 grâce à un crible des protéines qui se lient aux formes précurseurs des sous-unités mais plus au complexe une fois assemblé. La reconstitution biochimique et la modélisation moléculaire nous a permis de montrer que HSBP1 est associé avec le précurseur trimérique CCDC53, le dissocie et forme un hétérotrimère qui va éventuellement libérer une forme monomérique de CCDC53 pour l’assemblage du complexe WASH. Le rôle de HSBP1 dans l’assemblage du complexe WASH est conservé. En effet, WASH est déstabilisé dans des cellules mammaires par le knock-down de HSBP1 et dans l’amibe Dictyostelium par le knock-out de HSBP1. La déstabilisation du complexe WASH par le knock-out de HSBP1 phénocopie la déplétion de WASH dans l’amibe Dictyostelium. Dans des cellules humaines de carcinomes mammaires l’inhibition de l’expression de HSBP1 altère le recyclage des intégrines à la membrane plasmidique. Il en résulte des adhésions focales défectueuses et des capacités invasives réduites. De plus, HSBP1 est localisé aux centrosomes et est requis pour la polarité des cellules lors de la migration. Enfin, nous avons trouvé que la surexpression de HSBP1 dans des tumeurs mammaires est associée à une augmentation des niveaux du complexe WASH et à un mauvais pronostic pour les patientes atteintes de cancer du sein. En conclusion, HSBP1 est un facteur d’assemblage conservé qui contrôle les niveaux du complexe WASH. / The Arp2/3 complex generates branched actin networks, which produces a pushing force that helps the cell to remodel its membranes. The WASH complex activates the Arp2/3 complex at the surface of endosomes and thereby, facilitates the membrane scission of the transport intermediates containing internalized receptors such as α5β1 integrins. Hence, by promoting integrin recycling, the WASH complex plays a crucial role in tumor cell invasion during cancer progression. However, how cells assemble the WASH complex at first is unknown. Here we report the identification of the first assembly factor of the WASH complex. We identified HSBP1 in a proteomics screen for proteins binding to precursor forms of subunits, but not to the fully assembled WASH complex. Through biochemical reconstitution and molecular modeling, we found that HSBP1 associates with the precursor CCDC53 trimer, dissociates it and forms a heterotrimer that will eventually contribute a single CCDC53 molecule to the assembling WASH complex. The role of HSBP1 in WASH complex assembly is well conserved since WASH is similarly destabilized upon HSBP1 knock-down in mammalian cells or upon HSBP1 knock-out in Dictyostelium amoeba. In line with the defective assembly of the WASH complex, the HSBP1 knock-out closely phenocopies WASH knock-out in amoeba. In human mammary carcinoma cells, HSBP1 depletion results in impaired integrin recycling to the plasma membrane leading to the defective development of focal adhesions and reduced invasion abilities. Moreover, HSBP1 was found to localize at the centrosome and was required for the polarization associated with the migration. On the other end, in mammary breast tumors, we found that HSBP1 was often overexpressed and that its overexpression was associated with increased levels of the WASH complex and with poor prognosis for breast cancer patients. Hence, HSBP1 is a conserved assembly factor that controls the levels of the WASH complex. Complexe WASH Cytosquelette d'actine Assemblage des complexes Migration des cellules Invasion des cellules Centrosome Complexe Arp2/3 WASH complex Actin cytoskeleton Multiprotein complex assembly Cell migration Cell invasion Centrosome Arp2/3 complex
70	Elucidating the pathway of centrosome formation Costa Vicente, Catarina January 2013 (has links) Centrosomes are cellular organelles present in most animal cells, and are formed of two main components: the centrioles and the pericentriolar material (PCM). Centrosomes perform a variety of functions: they are the main microtubule organising centre in the cell, and are important localisation hubs for kinases involved in regulating the cell cycle. Hundreds of proteins are thought to localise to centrosomes, but work in the last decade has narrowed down this list to a handful of proteins that are thought to be essential for centrosome structure and function in Drosophila. Asl, Ana2, DSas-4, DSas-6 and Sak have been identified as essential components for centriole duplication, while Cnn and DSpd-2 are thought to be important in establishing the PCM. However, the relative position of these 7 components in the pathway of centrosome assembly in Drosophila embryos remains elusive, as a genetics analysis of this process is hampered by the absence of centrioles in most mutant embryos for these proteins. In this thesis I elucidate the pathway of centrosome assembly in Drosophila by using SAPs (DSas-6/Ana2 particles that form in Drosophila unfertilised eggs upon moderate expression of DSas-6 and Ana2) as proxy models of centrosomes. I show SAPs are very similar to centrosomes in composition and dynamics but unlike centrosomes are able to form even in the absence of some of the essential centriolar components. SAP analysis in the absence of each of the main centrosome components reveals that: Sak is not required for the recruitment of downstream components; DSas-4 is necessary for Ana2 and DSas-6 to interact; Asl is the most upstream component of the PCM recruitment pathway, followed by DSpd-2; it is likely that there is an additional PCM recruitment pathway. I then take advantage of some of these results to examine how centrosome formation is potentiated after egg activation. My work allows me to propose an improved description of the pathway of centrosome formation in Drosophila. 571.6

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