Global ETD Search

81	Regulation of the Transcription and Subcellular Localization of the Tumor Suppressor PTEN by ΔNp63α Leonard, Mary Kathryn January 2012 (has links) No description available. Biomedical Research Cellular Biology Molecular Biology Oncology p63 PTEN keratinocyte Akt NEDD4-1 non-melanoma skin cancer centrosome
82	Cytoplasmic dilution drives mitotic organelle scaling during cellular differentiation Kletter, Tobias 24 May 2024 (has links) Die mitotische Spindel ist ideal für die Erforschung der Selbstorganisation und Plastizität molekularer Kollektive im Zytoplasma. Die Geometrie der Spindel ist entscheidend für die korrekte Chromosomentrennung, muss sich aber an die Zellgröße anpassen. Es ist unbekannt, ob und wie Zellen während ihrer Differenzierung die Spindelarchitektur anpassen, was insbesondere während der Gehirnentwicklung relevant ist. Wir untersuchten dies mit Maus-Embryonalstammzellen, die in frühe neuronale Vorläuferzellen differenziert wurden. Wir entwickelten ein automatisiertes Mikroskopieprotokoll um einen umfassenden Datensatz von mitotischen Zellen zu generieren. Außerdem entwickelten wir Spindle3D, ein Werkzeug zur dreidimensionalen Analyse von Spindeln. Überraschenderweise waren die Spindelvolumina in differenzierenden Zellen bis zu 24% kleiner als in pluripotenten Zellen. Während die Wachstumsgeschwindigkeit der Mikrotubuli unverändert blieb, verschob sich in sich differenzierenden Zellen die Nukleation von Mikrotubuli zugunsten der astralen Population. Diese Veränderung der Spindelarchitektur basierte auf der differenzierungsbedingten Verdünnung des Zytoplasmas. Dies aktivierte CPAP, ein Protein, das die Zentrosomenreifung reguliert, was zur Superskalierung des perizentriolären Materials und verstärkte Rekrutierung von gamma-Tubulin an den Zentrosomen und somit zur Umlagerung von Mikrotubuli innerhalb der Spindel führte. Diese Veränderungen der mitotischen Architektur konnten durch externe osmotische Einwirkung in undifferenzierten Zellen nachgestellt werden. Insgesamt verbinden unsere Ergebnisse zelltypspezifische zytoplasmatische Materialeigenschaften mit der Spindelarchitektur. / The mitotic spindle provides an excellent system in which to study the plasticity of molecular collectives. To segregate chromosomes accurately, the spindle’s geometry must be adaptive to changes in cell size. It is unknown whether and how differentiating cells adjust spindle architecture, specifically during brain development when spindle defects have severe pathological consequences. Using murine embryonic stem cells, we recapitulated the transition from pluripotency to early neural cell identities in vitro. Aiming at a systematic exploration of spindle and cell morphology throughout this process, we developed an automated microscopy protocol and Spindle3D, a morphometric tool for the analysis of spindles in confocal images. Intriguingly, in cells with comparable cell volume, spindle volumes were up to 24% smaller in cells undergoing differentiation. While microtubule growth speed remained equal, we measured increased nucleation of astral microtubules at the expense of the spindle bulk in differentiating cells. The shift in spindle architecture was explained by the differentiation-driven cytoplasmic dilution. This activated the centrosomal regulator CPAP, causing the superscaling of the pericentriolar material and the concomitant increased recruitment of gamma-tubulin to the centrosomes, redistributing microtubule numbers within the spindle. Mimicking the dilution effect by osmotic challenge reproduced the same mitotic architecture in undifferentiated cells. Collectively, our results link cell state-specific cytoplasmic material properties to spindle architecture. Mitose Spindelapparat Zentrosom Zytoplasma Skalierung Bildanalyse Differenzierung Mitosis Spindle Centrosome Cytoplasm Scaling Image analysis Differentiation 570 Biologie ddc:570
83	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
84	Time-Resolved Quantification of Centrosomes by Automated Image Analysis Suggests Limiting Component to Set Centrosome Size in C. Elegans Embryos Jaensch, Steffen 22 December 2010 (has links) (PDF) The centrosome is a dynamic organelle found in all animal cells that serves as a microtubule organizing center during cell division. Most of the centrosome components have been identified by genetic screens over the last decade, but little is known about how these components interact with each other to form a functional centrosome. Towards a better understanding of the molecular organization of the centrosome, we investigated the mechanism that regulates the size of the centrosome in the early C. elegans embryo. For this, we monitored fluorescently labeled centrosomes in living embryos and developed a suite of image analysis algorithms to quantify the centrosomes in the resulting 3D time-lapse images. In particular, we developed a novel algorithm involving a two-stage linking process for tracking entrosomes, which is a multi-object tracking task. This fully automated analysis pipeline enabled us to acquire time-resolved data of centrosome growth in a large number of embryos and could detect subtle phenotypes that were missed by previous assays based on manual image analysis. In a first set of experiments, we quantified centrosome size over development in wild-type embryos and made three essential observations. First, centrosome volume scales proportionately with cell volume. Second, beginning at the 4-cell stage, when cells are small, centrosome size plateaus during the cell cycle. Third, the total centrosome volume the embryo gives rise to in any one cell stage is approximately constant. Based on our observations, we propose a ‘limiting component’ model in which centrosome size is limited by the amounts of maternally derived centrosome components. In a second set of experiments, we tested our hypothesis by varying cell size, centrosome number and microtubule-mediated pulling forces. We then manipulated the amounts of several centrosomal proteins and found that the conserved centriolar and pericentriolar material protein SPD-2 is one such component that determines centrosome size. Zentrosom Tracking Bildanalyse C. elegans Quantifikation Image Analysis Tracking Centrosome Size Regulation C. elegans Quantification ddc:610 rvk:WE 3800 rvk:XC 4004
85	Aurora A kinase function during anaphase Lioutas, Antonio, 1980- 09 November 2012 (has links) Aurora A (AurA) is an important mitotic kinase mainly studied for its involvement in cell cycle progression, centrosome maturation, mitotic spindle pole organization and bipolar spindle formation. It localizes to duplicated centrosomes and spindle microtubules (MTs) during mitosis where it regulates various factors participating in metaphase spindle formation. AurA is degraded late in mitosis suggesting that it might also have a function in anaphase. In this study we focused in understanding AurA function during anaphase in two different experimental systems. First, we kept AurA active in cycled Xenopus egg extracts and found that MTs maintained their mitotic organization longer throughout mitotic exit. We also observed chromosome segregation defects and problematic nuclear envelope formation. These observations indicate that AurA activity needs to be down-regulated for the transition from metaphase back to interphase. To get insights into the role of AurA during metaphase-anaphase transition we initially asked whether its kinase activity is still necessary for the maintenance of the metaphase spindle. We saw that the inhibition of AurA kinase activity in metaphase resulted to a collapse of the established metaphase spindle in HeLa cells. Indicating that AurA activity is necessary for the metaphase spindle maintenance. Then, we looked whether AurA kinase activity is still necessary during anaphase. We inhibited AurA at the onset of anaphase in Hela cells and found that anaphase spindles were smaller. We also observed that the MT structure responsible for anaphase spindle elongation, the central spindle, was defectively assembled and organized. Moreover, in cells where AurA was inhibited segregation of chromosomes was defective. These results indicate that AurA kinase activity is necessary for anaphase spindle elongation, central spindle assembly and organization and chromosome segregation. To understand further how AurA regulates anaphase spindle formation we looked known AurA substrates. We depleted TACC3, a known AurA substrate involved in MT formation earlier in mitosis and observed that TACC3 depletion phenocopied AurA inhibition. This indicates that TACC3 has a function in MT organization and chromosome segregation during anaphase and this function could possibly be regulated by AurA. In this study we have demonstrated that AurA activity is essential for metaphase spindle maintenance. We also found that during anaphase when AurA is either maintained active or inhibited MT organization is greatly affected and chromosome segregation is defective. Suggesting that AurA activity needs to be tightly controlled during anaphase for a correct completion of mitosis. / Aurora A (AurA) es una quinasa mitótica importante que se ha estudiado principalmente en su papel durante la progresión del ciclo celular, la maduración del centrosoma, la organización y la formación del polo y del huso mitótico. Durante la mitosis, AurA se localiza en los centrosomas duplicados y en los microtúbulos (MTs) del huso y se ha observado que regula varios factores que participan en la formación del huso mitótico. AurA se degrada al final de la mitosis indicando que pueda tener una función durante la anafase. En este estudio nos hemos centrado en la comprensión de la función de AurA durante la anafase en dos sistemas experimentales diferentes. En primer lugar, utilizando extractos de huevos de Xenopus hemos mantenido AurA activa durante la transición de metafase a anafase y hemos visto que los MTs del huso mitótico mantienen su organización durante más tiempo. También hemos observado que cuando AurA se mantiene activa existen defectos en la segregación cromosómica y la formación de la membrana nuclear. Esto indica que la actividad de AurA tiene un papel regulador sobre los MTs y la chromatina durante la transición de la metafase a la interfase. Para entender cual es la función de AurA durante la transición de metafase a anafase primero hemos estudiado si la actividad de la quinasa es necesaria para el mantenimiento del huso mitótico. Hemos visto que la inhibición de la actividad quinasa AurA resultó en el colapso del huso durante la metafase en células HeLa. Esto indica que la actividad de AurA es necesaria para el mantenimiento del huso mitótico de metafase. A continuación hemos analizamos si la actividad quinasa de AurA sigue siendo necesaria para la anafase. Para ello hemos inhibido AurA en células Hela al inicio de la anafase. En estas condiciones los husos de la anafase son más pequeños y la estructura de los MTs responsable del alargamiento del huso mitótico durante la anafase, el huso central, se organiza defectuosamente. Además, se encontraron errores durante la segregación de los cromosomas. Estos resultados indican que la actividad quinasa de AurA es necesaria para el alargamiento del huso durante la anafase y la organización y segregación cromosómica. Para entender el mecanismo de la función de AurA durante la anafase hemos estudiado a sustratos de AurA. Al estudiar TACC3 , un sustrato conocido de AurA que participa en la formación de MTs en las fase iniciales de la mitosis hemos encontrado que su eliminación de células HeLa produce el mismo fenotipo que la inhibición de AurA. Esto indica que TACC3 tiene una función en la organización de MT y la segregación de cromosomas durante la anafase y que esta función podría estar regulada por la quinasa AurA. En este estudio hemos demostrado que la actividad quinasa de AurA es esencial para el mantenimiento del huso mitótico. También hemos encontrado que durante la anafase cuando la quinasa AurA se mantiene activa o se inhibe la organización de los MTs del huso mitótico se ve muy afectada y los cromosomas se segregan defectuosamente. Por tanto los resultados de este estudio indican que la actividad quinasa de AurA está estrechamente controlada durante la anafase para el correcto cumplimiento de la mitosis. Fus mitòtic Xenopus laevis Embriologia Centrosomes Mitosi HeLa cells Xenopus egg extract Cell cycle Mitotis Mitotic spindle Centrosome Kinase Anaphase Central spindle Microtubules Aurora A TPX2 TACC3 Augmin 576
86	Perturbation and Modulation of Microtubule Cytoskeletal Elements in Response to the Potentially Oncogenic Molecules, Survivin and P53, and Cytokinesis: A Dissertation Rosa, Jack 17 July 2006 (has links) A complex network of protein filaments collectively known as the cytoskeleton carries out several crucial cellular processes. These functions include, but are not limited to, motility, cell shape, mitosis and organelle trafficking. The cytoskeleton is also highly responsive, allowing the cell to alter its shape in response to its immediate needs and environment. One of the major components of the cytoskeleton is the microtubule network. To refer to the array of micro tubules in the cell as a skeleton is a misnomer. Microtubules, by virtue of their structure and nature, are highly dynamic, continuously growing and shrinking. They also bind a variety of accessory molecules that aid in regulating and directing their dynamic activity. In this way they provide a structural basis for integral cell functions that require rapid assembly and disassembly. In some cases, perturbations of the microtubule network results in structural anomalies that lead to undesirable outcomes for the cell, namely chromosomal missegregation events and instability. The accumulation of these events may induce aneuploidy, which has been a fundamental component of tumorigenesis. This dissertation examines the role of the microtubule cytoskeleton within three distinct contexts. The first chapter investigates the association of the anti-apoptotic protein survivin with the microtubule network and its potential impact upon the cell from interphase to cytokinesis. The second chapter of this dissertation explores a little-studied, microtubule-dense organelle, referred to as the midbody, and the highly orchestrated events that take place within it during cytokinesis. The third and final chapter describes a unique experimental condition that may further our understanding of the interaction between the tumor suppressor p53 and the centrosome in cell cycle regulation and tumorigenesis. Microtubules Cytoskeleton Microtubule-Associated Proteins Cell Cycle Proteins Neoplasm Proteins Tumor Suppressor Protein p53 Protein-Serine-Threonine Kinases Cytokinesisl Centrosome Amino Acids, Peptides, and Proteins Cells Neoplasms
87	Time-Resolved Quantification of Centrosomes by Automated Image Analysis Suggests Limiting Component to Set Centrosome Size in C. Elegans Embryos Jaensch, Steffen 12 February 2010 (has links) The centrosome is a dynamic organelle found in all animal cells that serves as a microtubule organizing center during cell division. Most of the centrosome components have been identified by genetic screens over the last decade, but little is known about how these components interact with each other to form a functional centrosome. Towards a better understanding of the molecular organization of the centrosome, we investigated the mechanism that regulates the size of the centrosome in the early C. elegans embryo. For this, we monitored fluorescently labeled centrosomes in living embryos and developed a suite of image analysis algorithms to quantify the centrosomes in the resulting 3D time-lapse images. In particular, we developed a novel algorithm involving a two-stage linking process for tracking entrosomes, which is a multi-object tracking task. This fully automated analysis pipeline enabled us to acquire time-resolved data of centrosome growth in a large number of embryos and could detect subtle phenotypes that were missed by previous assays based on manual image analysis. In a first set of experiments, we quantified centrosome size over development in wild-type embryos and made three essential observations. First, centrosome volume scales proportionately with cell volume. Second, beginning at the 4-cell stage, when cells are small, centrosome size plateaus during the cell cycle. Third, the total centrosome volume the embryo gives rise to in any one cell stage is approximately constant. Based on our observations, we propose a ‘limiting component’ model in which centrosome size is limited by the amounts of maternally derived centrosome components. In a second set of experiments, we tested our hypothesis by varying cell size, centrosome number and microtubule-mediated pulling forces. We then manipulated the amounts of several centrosomal proteins and found that the conserved centriolar and pericentriolar material protein SPD-2 is one such component that determines centrosome size. info:eu-repo/classification/ddc/610 ddc:610
88	From the centrosome to the nuclear envelope and beyond: insights into the role of CRM1 in adenoviral genome delivery Lagadec, Floriane 31 May 2021 (has links) Les adénovirus (AdV) sont des virus à ADN se répliquant dans le noyau de la cellule hôte. Pour pouvoir se répliquer, ils détournent la machinerie cellulaire à leur profit. Au cours de l’entrée dans la cellule, les particules virales utilisent la machinerie de transport des microtubules pour rejoindre le noyau. Les AdV interagissent avec la dynéine, moteur moléculaire associé aux microtubules, pour être transportés vers le compartiment nucléaire. Ils se lient alors aux pores nucléaires, structures ancrées dans l’enveloppe nucléaire (EN). Une fois aux pores nucléaires, les capsides virales se désassemblent pour libérer et importer leur génome. Les mécanismes de détachement des microtubules, de translocation nucléaire et d’import du génome des AdV impliquent des facteurs de la machinerie de transport nucléocytoplasmique. Cependant, le mécanisme exact utilisé par les virus pour atteindre les pores nucléaires n’est pas clairement défini. Le transport nucléocytoplasmique est composé de différents facteurs et est hautement régulé dans les cellules. Le transport actif de cargos est dû à des facteurs d’import et d’export interagissant avec RanGTP. Le principal facteur d’export est CRM1 et il est connu pour être essentiel dans la translocation des AdV vers l’EN. L’inhibition de CRM1 par la Leptomycine B conduit à l’accumulation des AdV au centrosome, le principal Centre Organisateur des Microtubules (COMT) des cellules de mammifères. Nous avons donc étudié le rôle de CRM1 dans la libération du génome adénoviral. Nous avons analysé l’interaction des AdVs avec le COMT et nous avons observé que l’absence de facteurs cytoplasmiques ainsi que la perte d’intégrité des microtubules n’affectaient pas leur accumulation au COMT. En revanche, nous avons identifié et caractérisé un mutant de CRM1, qui reste fonctionnel pour l’export physiologique de cargo mais qui induit un retard important dans la translocation des AdV vers l’EN. Nous avons utilisé l’imagerie sur cellules vivantes pour analyser l’infection de l’AdV dans des cellules mitotiques et ceci a permis de révéler le rôle de CRM1 dans la libération du génome de ce virus. Nous avons également identifié un partenaire viral potentiel pour CRM1 parmi les protéines associées au génome viral, la Terminal Protein (TP). Cette protéine possède un signal d’export nucléaire et est un substrat de CRM1. Nos données soulignent le rôle de CRM1 comme un médiateur essentiel au désassemblage total de la capside adénovirale, qui favorise la libération du génome et son import. 610 Adenovirus CRM1 Centrosome Nucleocytoplasmic transport
89	Roles of the Mother Centriole Appendage Protein Cenexin in Microtubule Organization during Cell Migration and Cell Division: A Dissertation Hung, Hui-Fang 03 August 2016 (has links) Epithelial cells are necessary building blocks of the organs they line. Their apicalbasolateral polarity, characterized by an asymmetric distribution of cell components along their apical-basal axis, is a requirement for normal organ function. Although the centrosome, also known as the microtubule organizing center, is important in establishing cell polarity the mechanisms through which it achieves this remain unclear. It has been suggested that the centrosome influences cell polarity through microtubule cytoskeleton organization and endosome trafficking. In the first chapter of this thesis, I summarize the current understanding of the mechanisms regulating cell polarity and review evidence for the role of centrosomes in this process. In the second chapter, I examine the roles of the mother centriole appendages in cell polarity during cell migration and cell division. Interestingly, the subdistal appendages, but not the distal appendages, are essential in both processes, a role they achieve through organizing centrosomal microtubules. Depletion of subdistal appendages disrupts microtubule organization at the centrosome and hence, affects microtubule stability. These microtubule defects affect centrosome reorientation and spindle orientation during cell migration and division, respectively. In addition, depletion of subdistal appendages affects the localization and dynamics of apical polarity proteins in relation to microtubule stability and endosome recycling. Taken together, our results suggest the mother centriole subdistal appendages play an essential role in regulating cell polarity. A discussion of the significance of these results is included in chapter three. Heat-Shock Proteins Cell Division Cell Movement Cell Polarity Centrioles Centrosome Endosomes Epithelial Cells Microtubule-Organizing Center Microtubules Cenexin Dissertations, UMMS Cell Biology Cellular and Molecular Physiology
90	Sas4 N terminal as a potential binding probe for tubulin-GDP Yuan, Wenjue January 2014 (has links) No description available. Biochemistry Biology Biomedical Engineering Biomedical Research Cellular Biology Developmental Biology Health Sciences Molecular Biology Molecular Chemistry Molecules centrosome Sas4 tubulin GTP GDP GMPCPP

Search results