Global ETD Search

91	The ABC's of Cell Division: Regulation of Peptidoglycan Amidase Activity during Cytokinesis in Escherichia coli Yang, Desiree Choy 21 June 2013 (has links) The bacterial cell wall, composed of peptidoglycan (PG), is an essential component of the cell envelope. This macromolecular structure fortifies the cell membrane, determines cell shape, and helps prevent osmotic lysis. The synthesis and remodeling/recycling of this polymer is mediated by PG synthases and hydrolases, respectively. Proper control of the PG hydrolases is particularly important since misregulation of these enzymes can lead to lethal breaches in the cell wall. Surprisingly, however, the precise molecular mechanisms governing the activities of these enzymes remain poorly understood. To help understand how PG hydrolases are regulated, I examined how their activity is controlled during cytokinesis in Escherichia coli. One important class of PG hydrolases necessary for cell division is the LytC-type amidases (AmiA, AmiB and AmiC). These enzymes require activation by the LytM factors EnvC and NlpD. My work focused on elucidating the mechanism by which the LytM factors activate the amidases. Using a genetic enrichment strategy, I isolated amiB misregulation mutants. Interestingly, the mutations mapped to a region of AmiB found only in cell separation amidases. Structural analysis of an AmiB ortholog indicates that this region corresponds to an alpha-helical domain that appears to occlude the active site. Thus, activation of the amidases by the LytM factors likely occurs via a conformational change that displaces the regulatory helix from the active site. In addition to amidase regulation, I also investigated how the LytM activators are recruited to, and regulated at the site of division. Using genetic and biochemical approaches, I showed that EnvC is directly recruited to the division site by FtsEX, an ATP-binding transporter- like complex. Interestingly, ATPase-defective FtsEX derivatives can still recruit EnvC to the divisome, but fail to promote cytokinesis. These results support a model where conformational changes induced by the ATPase activity of FtsE are directly and specifically transmitted to the amidases via FtsX and EnvC. This model is attractive because it provides a mechanism for converting the potentially dangerous activity of septal PG splitting into a discrete process which can be cycled on and off in coordination with the division process. amidase cell division cell envelope cytokinesis morphogenesis peptidoglycan microbiology molecular biology genetics
92	Progression through the cell cycle is regulated by dynamic chloride dependent changes in cell volumes Habela, Christa Whelan. January 2008 (has links) (PDF) Thesis (Ph.D.)--University of Alabama at Birmingham, 2008. / Title from first page of PDF file (viewed on June 24, 2009). Includes bibliographical references.
93	Endosomes and mitosis : FIP3-associated vesicle delivery during cytokinesis / Simon, Glenn C. January 2008 (has links) Thesis (Ph.D. in Cell Biology, Stem Cells, and Development) -- University of Colorado Denver, 2008. / Typescript. Includes bibliographical references (leaves 105-116).
94	Centrosomes in Cytokinesis, Cell Cycle Progression and Ciliogenesis: a Dissertation Jurczyk, Agata 08 September 2004 (has links) The work presented here describes novel functions for centrosome proteins, specifically for pericentrin and centriolin. The first chapter describes the involvement of pericentrin in ciliogenesis. Cells with reduced pericentrin levels were unable to form primary cilia in response to serum starvation. In addition we showed novel interactions between pericentrin, intraflagellar transport (IFT) proteins and polycystin 2 (PC2). Pericentrin was co-localized with IFT proteins and PC2 to the base of primary cilia and motile cilia. Ciliary function defects have been shown to be involved in many human diseases and IFT proteins and PC2 have been implicated in these diseases. We conclude that pericentrin is required for assembly of primary cilia possibly as an anchor for other proteins involved in primary cilia assembly. The second chapter describes identification of centriolin, a novel centriolar protein that localizes to subdistal appendages and is involved in cytokinesis and cell cycle progression. Depletion of centriolin leads to defects in the final stages of cytokinesis, where cells remain connected by thin intercellular bridges and are unable to complete abscission. The cytokinesis defects seemed to precede the G0/G1 p53 dependant cell cycle arrest. Finally, the third chapter is a continuation of the cytokinesis study and it identifies pericentrin as an interacting partner for centriolin. Like centriolin, pericentrin knockdown induces defects in the final stages of cytokinesis and leads to G0/G1 arrest. Moreover, pericentrin and centriolin interact biochemically and show codependency in their centrosome localization. We conclude that pericentrin and centriolin are members of the same pathway and are necessary for the final stages of cytokinesis. Cell Cycle Proteins Cell Division Centrosome Cilia Cytokinesis Microtubule-Associated Proteins Amino Acids, Peptides, and Proteins Cells
95	Studying the formation of tricellular junction upon epithelial cell division in Drosophila / Etude de la formation de la jonction tricellulaire au cours de la division épithéliale chez la drosophile Wang, Zhimin 15 December 2017 (has links) Pour maintenir l'organisation et la polarité du tissu épithélial, de nouvelles jonctions cellulaires ont besoin de se former lors de la division cellulaire. Pour comprendre les mécanismes de formation de la jonction durant la cytokinèse, nous avons exploré dans les tissus épithéliaux de la Drosophile, la formation des jonctions septées tricellulaires (TCJs), critique à la fois dans la fonction de barrière tissulaire, dans l'homéostasie des cellules souches, ainsi que dans l'orientation du fuseau mitotique. Durant les dernières étapes de la constriction de l'anneau contractile, les membranes des deux cellules filles et des cellules voisines localisées sous la jonction adhérente (JA) restent enchevêtrées dans une structure à 4 cellules apposée au corps intermédiaire. Les constituants protéiques de la jonction septée, Discs-large (Dlg) et Neuroglian (Nrg), ainsi que les composants de la TCJ, Gliotactin (Gli) et Anakonda (Aka), s'accumulent dans cette structure à 4 cellules. Par la suite, la descente basale du corps intermédiaire est corrélée au détachement des membranes des cellules voisines, au désengagement des cellules filles de leurs voisines, et à la formation de TCJs matures. Le détachement des cellules voisines du corps intermédiaire est indépendant de l'abscision. Au contraire, la perte de la fonction Gli ou Aka empêche le détachement entre les cellules filles-voisines et le mouvement du corps intermédiaire. Ainsi, nous proposons que les protéines de la TCJ contrôlent une étape additionnelle de la cytokinèse, nécessaire au désengagement des cellules filles et de leurs voisines durant la cytokinèse épithéliale. / To maintain epithelial tissue organisation and polarity, new cell-cell junctions need to be formed upon cell division. To understand the mechanisms of junction formation during cytokinesis, we explored in Drosophila epithelial tissues, the de novo formation of tricellular septate junctions (TCJs), which are critical to tissue barrier function, stem cell homeostasis and mitotic spindle orientation. During the final stages of cytokinetic ring constriction, the membranes of the two daughter cells and of the neighbouring cells located below the adherens junction (AJ) remain entangled in a 4-cell structure apposed to the midbody. Protein constituents of the septate junction Discs-large (Dlg) and Neuroglian (Nrg) and the components of the TCJ Gliotactin (Gli) and Anakonda (Aka) accumulate in this 4-cell structure. Subsequently, a basal descent of the midbody correlates with the detachment of the neighbouring cell membranes, disengagement of the daughter cells from their neighbours and the formation of mature TCJs. The detachment of the neighbouring cells from the midbody is independent of abscission. On the contrary, the loss of Gli or Aka function prevents the resolution of the connection between the daughter-neighbour cells and the midbody movement. Altogether, we propose that TCJ proteins control an additional step of cytokinesis necessary for the disentanglement of the daughter cells and their neighbours during epithelial cytokinesis. Cytokinèse Jonction septée Jonction tricellulaire Abscission Gli Aka Cytokinesis Septate junction Abscission 571.6
96	Rab35 GTPase and initiation of apico-basal polarity in 3D renal cysts / Rab35 GTPase et initiation de la polarité apico-basal dans un modèle cellulaire 3D Klinkert, Kerstin 22 September 2016 (has links) L'établissement de la polarité apico-basale dans les tissus épithéliaux est étroitement lié à la division cellulaire, mais les mécanismes moléculaires sous-jacents n'ont pas encore été établis. A l'aide d'un modèle de culture en 3 dimensions de cellules rénales (MDCK), j'ai montré que lors du développement d'un cyst, la GTPase Rab35 joue un rôle majeur dans l'établissement de la polarité et le positionnement du lumen pendant la première division cellulaire. Au niveau moléculaire, Rab35 permet de coupler l'initiation de la polarité apico-basale avec la cytocinèse via l'attachement au sillon de clivage de vésicules intracellulaires contenant des déterminants clé de l'établissement de la polarité. Ces vésicules transportent notamment les protéines aPKC, Cdc42, Crumbs3 ainsi que le facteur d'ouverture de la lumière Podocalyxin. De plus, l'attachement de ces vésicules au sillon de clivage dépend de l'interaction directe entre Rab35 et la queue cytoplasmique de Podocalyxin. Par conséquence, l'inactivation de Rab35 entraine une inversion complète de la polarité apico-basale des kystes 3D. J'ai mis en évidence un nouveau mécanisme de ciblage des vésicules intracellulaire au site de clivage dépendant de la protéine Rab35 impliqué à la fois dans l'initiation de la polarité apico-basale et dans l'ouverture de la lumière au centre du cyst. / Establishment and maintenance of apico-basal polarity in epithelial organs must be tightly coupled with cell division, but the underlying molecular mechanisms are largely unknown. Using 3D cultures of renal MDCK cells (cysts), I found that the Rab35 GTPase plays a crucial role in polarity initiation and apical lumen positioning during the first cell division of cyst development. At the molecular level, Rab35 physically couples cytokinesis with the initiation of apico-basal polarity by tethering intracellular vesicles containing key apical determinants at the cleavage site. These vesicles transport aPKC, Cdc42, Crumbs3 and the lumen promoting factor Podocalyxin, and are tethered through a direct interaction between Rab35 and the cytoplasmic tail of Podocalyxin. Consequently, Rab35 inactivation leads to complete inversion of apico-basal polarity in 3D cysts. This novel and unconventional mode of Rab-dependent vesicle targeting provides a simple mechanism for triggering both initiation of apico-basal polarity and lumen opening at the centre of cysts. Polarité epithéliale Cytocinèse Podocalyxin Rab35 GTPase 3D MDCK cysts Traffic membranaire Epithelial polarity Cytokinesis Podocalyxin 572.8
97	Generating Molecular Biology Tools to Investigate the Ca2+ Binding Ability of Arabidopsis TON2 Shao, Danyang 08 1900 (has links) The position of the cell division plane in plants is determined by the position of the preprophase band. The pre prophase band (PPB) is a ring of microtubules centered around the nucleus on the inner side of plasma membrane that establishes the cortical division site. The PPB forms at the end of G2 and breaks down at the end of prophase leaving behind protein markers of its position that are collectively called the cortical division site. During cytokinesis the phragmoplast expands towards the cortical division site and mediates the fusion of the new cell plate with the mother cell at that position. Several proteins necessary for PPB formation in plants have been identified, including maize DCD1 and ADD1 and Arabidopsis TON2, which are all type 2A protein phosphatase (PP2A)B" regulatory subunits. DCD1, ADD1, and TON2 localize to the PPB and the cortical division site through metaphase. The PP2A subunits each have two EF-hand domains, which are predicted to bind calcium ions. Since calcium ions are important for some aspects of cell division, we designed a series of constructs to test if TON2 binds calcium. TON2 protein was cloned into expression vectors, pET42a, and expression of TON2 protein was confirmed via Western blotting and immunodetection using a GST antibody. Site directed mutagenesis was used to mutate the TON2 EF-hand domains and mutated cDNAs were also cloned into expression vectors. These were then expressed in bacterial systems. Finally, the GST tagged proteins were purified. In the future, wild-type and mutated proteins TON2 proteins will used in calcium binding assays to determine if TON2 binds calcium. PPB TONNEAU2 mutations calcium binding EF-hand Cytokinesis. Arabidopsis. Calcium. Plant cell walls.
98	Investigating the Role of RNA-Binding Protein 5 in the Life Cycle Differentiation of Trypanosoma Brucei Anaguano Pillajo, David 25 October 2018 (has links) Trypanosomatid parasites such as Trypanosoma brucei have unusual mechanisms of gene expression including polycistronic transcription, mitochondrial RNA editing and trans-splicing. Additionally, these protists rely mainly on post-transcriptional regulation where RNA-binding proteins (RBP) have shown to play a major role. RBP6 and RBP10 are two examples of RBPs that play crucial roles in procyclic and bloodstream form parasites differentiation respectively, by post-transcriptional regulation. Over-expression of RBP6 is enough to promote differentiation into metacyclic trypomastigotes that are infective to mice. However, continuous expression is required, and this pattern does not reflect the natural expression in the tsetse fly or the influence of other RNA-binding proteins. RBP5 is a RBP with a single RNA-recognition motif similar to RBP6 and RBP10, whose expression is upregulated during the life stages within the salivary glands of tsetse flies. We hypothesize the RBP5 facilitates metacyclogenesis in the tsetse fly. To evaluate possible contributions to T. brucei differentiation, we will over-express RBP5 in procyclic cells alone and in combination with RBP6. Initial screening of cells over-expressing PTP-tagged RBP5 resulted in parasites with a moderate growing defect, and the scoring of nuclei and kinetoplasts in fixed cells showed a progressive accumulation of cells with 2 nuclei and 2 kinetoplasts (2N2K) and appearance of multinucleated cells. On the other hand, over-expression of non-tagged RBP5 generated a more severe growing defect, starting immediately after the first day of induction. The scoring of nuclei and kinetoplasts resulted in a drastic increase of 2N2K cells and a greater appearance of multinucleated cells, which suggests an irregular cell cycle progression. When developing the dual over-expression system, our cells over-expressing RBP6 were not able to differentiate into any stage, and when over-expressing RBP5 and RBP6 coordinately, no differentiation process was observed either. Together these data suggest that RBP5 might be a regulator of genes involved in the initiation of cytokinesis in T. brucei parasites, however a role in metacyclogenesis cannot be discarded since we were not able to obtain metacyclic parasites. This study helped us to get a better understanding of the post-transcriptional regulatory mechanisms that repress and regulate T. brucei cell cycle progression. RNA-binding protein RBP5 Trypanosoma brucei over-expression cell cycle cytokinesis Molecular Biology Parasitology
99	Etude fonctionnelle et structurale de la GTPase Rab35 et de ses effecteurs : vers le mécanisme de contrôle de la dynamique de l'actine dans l'endocytose et la cytocinèse / Structural and functional insights for Rab35 GTPase and its effectors : toward a mechanism for control of actin dynamics in endocytosis and cytokinesis Hammich, Hussein 07 December 2017 (has links) Rab35 est une petite GTPase de la superfamille des Ras protéines. Chez l’Homme, plus de 60 Rabs jouent un rôle clef « d’interrupteur moléculaire » dans la régulation du trafic membranaire. Des progrès significatifs ont été réalisé sur le rôle de certaines Rabs, cependant il reste encore un travail important de compréhension fonctionnelle et du mécanisme d’action de celles-ci au sein de la cellule. L’actuel projet a pour but d’étudier Rab35, un régulateur essentiel d’une voie de recyclage vésiculaire vers la membrane plasmique, aussi impliqué dans la régulation de l’actine lors de la dernière étape de la division cellulaire. Rab35 agit via le recrutement et la régulation de protéines spécifiques appelées effecteurs. Chez l’humain, des mutations chez les partenaires de Rab35 entrainent de rares maladies connues sous le nom du syndrome de Birt-Hogg-Dube et syndrome de Lowe. Ce projet en étroite collaboration avec le laboratoire d’Arnaud Echard (Institut Pasteur) consiste à mieux comprendre le rôle cellulaire et fonctionnel de deux nouveaux effecteurs de Rab35 : MICAL1 et MiniBAR. Lors de la division cellulaire, MICAL1 pourrait réduire le niveau d’actine avant l’abscission car il possède un domaine catalytique monooxygénase démontré comme étant un facteur de désassemblage de l’actine. MICAL1 agit directement sur les filaments d’actine et oxyde des résidus spécifiques permettant la dépolymérisation de ces derniers. Mais il est actuellement inconnue si MICAL1 joue un rôle dans la division cellulaire. Par ailleurs, nos collaborateurs ont découvert un nouvel effecteur de Rab35 appelé MiniBAR. Ils ont récemment décrit MiniBAR comme étant un partenaire spécifique de Rab35 et contenant un domaine BAR (connue pour lier et courber les membranes). Ce domaine, adjacent au domaine d’interaction de Rab35, lie spécifiquement Rac1 une autre GTPase bien connue pour son rôle dans la régulation de l’actine. De ce fait MiniBAR pourrait être un lien entre les deux GTPases coordonnant le processus de remodelage de l’actine dans la cellule.Le laboratoire de Motilité Structurale dirigé par Anne Houdusse est spécialisé dans l’étude structurale des moteurs moléculaire et GTPases qui contribuent aux différentes fonctions dans la cellule par l’interaction avec leur différents cargos et effecteurs. L’élaboration de ce projet consiste à caractériser d’un point de vue structural et fonctionnel les complexes entre Rab35 et ses effecteurs. Laboratoire spécialisé dans la détermination de structure à haute résolution par cristallographie aux rayons X, ce travail mènera à la résolution de complexes macromoléculaires afin de désigner des mutants spécifiques pour des études fonctionnelles dans la cellule en étroite collaboration avec l’équipe d’Arnaud Echard, leader dans l’étude cellulaire de Rab35. / Rab35 is an essential regulator of a recycling pathway back to the plasma membrane, that is also required for the post-furrowing terminal steps during cytokinesis that are associated with F-actin depolymerisation [1]. Rab35 performs its role in the cell via recruitment and regulation of specific effector proteins. Recently the lab of our collaborator Arnaud Echard (Pasteur institute, Paris) has identified and is currently studying by cell biology approaches two novel Rab35 effectors - MICAL1 and MiniBAR proteins. MICAL1 may restrict actin levels before cytokinesis abscission, because it harbours a monooxygenase catalytical domain and has been shown to be an F-actin-disassembly factor [2]. But it is unknown whether MICAL1 has a function in cell division. Another effector of Rab35 currently uncharacterized was identified and named MiniBAR by our collaborators. They recently described that MiniBAR specifically binds to active Rab35, that it contains an unnoticed, putative BAR domain (known to sense membrane curvature) and that this domain, adjacent to the Rab35-binding domain, binds specifically to GTP-bound Rac1 - a well known actin remodelling regulator. So, MiniBAR may function as a linker between the two small GTPases coordinating actin-remodelling processes in the cell. The aim of the project is to perform extensive structural/functional characterization of complexes between the Rab35 GTPase and its interacting effector proteins.References:[1] - Dambournet and al, Nat Cell Biol, 2011. Rab35 GTPase and OCRL phosphatase remodel lipids and F-actin for successful cytokinesis.[2] - Giridharan SS and Caplan S, Antioxid Redox Signal, 2014. MICAL-family proteins: Complex regulators of the actin cytoskeleton. Rab35 Mical MiniBAR GTPase Endocytose Cytocinèse Rab35 Mical MiniBAR GTPase Endocytosis Cytokinesis 570
100	Spatial regulation of protein function in cell division and midbody assembly Hirsch, Sophia Madeleine January 2021 (has links) Cytokinesis is the physical division of one cell into two driven by an actomyosin contractile ring and positioned by signals from microtubules. This process is highly regulated spatially and temporally to ensure accurate division into two daughter cells. Here, I present work that builds upon our understanding of cytokinesis, focusing on the spatial requirements for protein function during cell division and midbody assembly. In Chapter 1, I present an introduction to cytokinesis and the cell and molecular mechanisms that govern the process. In Chapter 2, I present work I contributed to on the use of Upconverting nanoparticles for co-alignment of visible and infrared light on a light microscope. In Chapter 3, I present work developing a new microscopy technology called FLIRT (Fast Local Infrared Thermogenetics) that uses infrared light to inactivate fast-acting temperature sensitive protein function with subcellular precision and validate its use to study cytokinesis and cell fate signaling in the nematode Caenorhabditis elegans. In Chapter 4, I improve upon FLIRT technology by increasing its precision and demonstrate its use in studying the spatial regulation of key cytokinesis proteins including the actomyosin cytoskeleton in contractile ring constriction. The central spindle is an array of antiparallel overlapping microtubules that forms between the separating chromosomes in anaphase and is thought to serve as a signaling hub for cytokinesis. The central spindle is thought to become compacted during contractile ring constriction to form the dense midbody at the end of cell division. In Chapter 5, I investigate the requirements for central spindle microtubules in assembling midbodies in the C. elegans one-cell embryo. I present evidence that the CENP-F-like protein HCP-1 plays a primary role relative to its paralog HCP-2 in assembling the central spindle, and that the midbody can form independently of central spindle assembly. In Chapter 6, I discuss future directions for my work on both technology development and the mechanisms of cytokinesis. Through this work, I develop new technologies and hypotheses for how cytokinesis is spatially regulated within a cell, adding new complexity to our understanding of cell division. Cytology Genetics Cytokinesis Cell division Spindle (Cell division) Caenorhabditis elegans--Genetics Nematodes--Genetics

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