Global ETD Search

41	Roles of Planar Cell Polarity Proteins in CoPA Axon Pathfinding Purdy, Ashley Morgan 01 January 2016 (has links) In zebrafish, CoPA (Commissural Primary Ascending) is the first among ascending commissural axons to pathfind anteriorly and form the spinal commissure. One pathway that guides their anterior growth is the planar cell polarity (PCP) signaling pathway, but it is not fully known how PCP signaling regulates anterior guidance. We examined CoPA pathfinding in various PCP mutants to determine if anterior-posterior (A-P) guidance of CoPAs is dependent on PCP signaling. We found that certain PCP mutants exhibited anterior pathfinding defects, with approximately half of all affected CoPAs migrating incorrectly posteriorly. By using a translation-blocking DCC (Deleted in Colorectal Cancer) morpholino to prevent CoPA midline crossing, we discovered that CoPA axons in Fzd3a and Scribble mutants show severe defects in A-P guidance, which suggest that PCP influences A-P guidance of CoPAs prior to and after midline crossing. planar cell polarity axon guidance commissural neurons Biology Developmental Biology Developmental Neuroscience
42	Régulation par la phosphorylation d’un module Rho GTPase dans la levure Saccharomyces cerevisiae / Regulation of a Rho GTPase module by phosphorylation in Saccharomyces cerevisiae Mitteau, Romain 06 December 2013 (has links) Le cycle cellulaire eucaryote est caractérisé par des changements abrupts et dynamiques de la polarité cellulaire lorsque les chromosomes sont dupliqués et ségrégés. Ces évènements nécessitent une coordination entre la machinerie du cycle cellulaire et les régulateurs de la polarité. Les mécanismes qui contrôlent cette coordination ne sont pas totalement compris. Dans la levure S. cerevisiae, comme dans d’autres organismes eucaryotes, la GTPase Cdc42 joue un rôle important dans la régulation de la polarité cellulaire. En effet ses régulateurs constituent un module GTPase qui subit une phosphorylation dynamique, au cours du cycle cellulaire, par des kinases évolutivement conservées dont la Cycline-Dependent Kinase 1 (Cdk1) et la p21-Activated Kinase (PAK). Ces kinases et substrats pourraient relier la polarité et la progression dans le cycle cellulaire. En utilisant une approche in vitro, nous avons reconstitué la phospho-régulation du Guanine nucléotide Exchange Factor (GEF) de Cdc42, la protéine Cdc24. Nous avons identifié un possible mécanisme de régulation de la phosphorylation impliquant une protéine d’échafaudage qui augmente la phosphorylation de Cdc24 par la PAK et Cdk1. Cette phosphorylation accroit modérément l’affinité de Cdc24 pour cette même protéine d’échafaudage, Bem1. De plus, en testant les effets d’autres composants du module GTPase sur la phosphorylation de Cdc24, nous avons identifié un effet antagoniste pour une GTPase Activating Protein (GAP), Rga2. Cette protéine est présente dans le même complexe que Cdc24 et Bem1, les membres de ce complexe sont tous phosphorylés par Cdk1. Des mutants rga2 suggèrent que la phosphorylation que subie Rga2 inhibe son activité GAP. Nous proposons un modèle provisoire pour expliquer la présence de Rga2 dans ce complexe et l’inhibition qu’elle oppose à la phosphorylation de Cdc24. La présence de la protéine GAP dans le complexe pourrait être un mécanisme de contrôle de la phosphorylation de Cdc24 dans le but de déstabiliser son intéraction avec la protéine Bem1 en cas de mauvaise localisation du complexe. Par ailleurs, la PAK est activée par l’activité de Cdc42, nos résultats sont consistants avec un modèle dans lequel des signaux du cycle cellulaire engendreraient une auto-amplification de l’activation du module GTPase. Chez S. pombe, la croissance polarisée nécessite un gradient d’activation de Cdc42 dû à une ségrégation de GEF et de GAP. Dans ces travaux nous montrons que toutes les protéines GAPs de Cdc42 localisent aux sites de croissance au cours du cycle cellulaire. Ces localisations sont consistantes avec le besoin de cyclage de Cdc42 pour maintenir sa polarisation. Ces résultats suggèrent que la localisation des protéines GAP régulant Cdc42 chez S. cerevisiae semble différente de ce qui est connu chez S. pombe. / The eukaryotic cell cycle is characterized by abrupt and dynamic changes in cellular polarity as chromosomes are duplicated and segregated. Those dramatic cellular events require coordination between the cell cycle machinery and polarity regulators. The mechanisms underlying this coordination are not well understood. In the yeast S. cerevisiae, as in other eukaryotes, the GTPase Cdc42 plays an important role in the regulation of cell polarity. Cdc42 regulators constitute a GTPase module that undergoes dynamic phosphorylation during the cell cycle by conserved kinases including Cyclin-Dependent Kinase 1 (Cdk1) and p21-activated kinase (PAK). These kinases and substrates may link cell polarity to the cell cycle progression. Using in vitro approaches, we have reconstituted the phospho-regulation of the Cdc42 Guanine Nucleotide Exchange Factor (GEF), Cdc24. We have identified a possible mechanism of Cdc24 regulation involving a scaffold-dependent increase in Cdc24 phosphorylation by Pak and Cdk1. This phosphorylation moderately increases the affinity of Cdc24 for another GTPase module component, the scaffold Bem1. Moreover, by testing the effect of other GTPase module components on the phosphorylation of Cdc24, and thus on its interaction with the scaffold, we identified an antagonistic function for the GTPase Activating Protein (GAP) Rga2. Our in vivo data of rga2 mutants suggest that Rga2 phosphorylation by Cdk1 inhibits its GAP activity. We propose a tentative model to explain the inhibition of Cla4 by Rga2 and its presence in a complex containing Cdc24 and Bem1. The presence of the GAP protein in the complex may be a mechanism that reduces Cdc24 phosphorylation in case of a mistargetting of the complex in order to downregulate the GEF/Scaffold dimer. Since the PAK component of the GTPase module is itself activated by Cdc42 activity, our results are consistent with a model in which inputs from the cell cycle lead to auto-amplification of the Cdc42 GTPase module. In S. pombe, polarised growth requires a gradient of activation of Cdc42 due to GEF and GAP segregation. Here we show that all Cdc42 GAPs localise to the polarised site during the cell cycle. Those localisations are consistent with a requirement of Cdc42 cycling to maintain a polarity cap. Our results may suggest that Cdc42 GAPs localisations in S. cerevisiae are different from current knowledge in S. pombe. Polarité cellulaire Cycle cellulaire Kinase GTPase Cell polarity Cell cycle Kinase GTPase
43	Interaction of centrosomal component SPD-5 with Wnt signals in the control of cell polarity in Caenorhabditis elegans Han, Suhao January 1900 (has links) Doctor of Philosophy / Department of Biology / Michael A. Herman / All multicellular organisms consist of a variety of cell types. One of the mechanisms to generate this cellular diversity is the asymmetric cell division, which requires the establishment of cell polarity. In Caenorhabditis elegans hermaphrodites, 807 of 949 somatic cell divisions are asymmetric. The centrosome and the Wnt signaling pathway both have been shown to regulate cell polarity and subsequently asymmetric divisions in many model organisms. However, it is not clear whether the Wnt signaling pathway manipulates the cell polarity through specific cellular organelles, such as the centrosome. To address this question, we examined a centrosomal component, SPD-5, to see whether it cooperates with the Wnt signaling pathway to regulate certain asymmetric cell divisions. We showed that SPD-5, which was originally found to be critical for the embryonic development, also played a role during certain post-embryonic cell divisions in C. elegans. Specifically the asymmetric divisions of seam cells that required SPD-5 function were also known to be regulated by the Wnt signaling pathway. Thus the stem-cell like seam cell divisions could be an intriguing system to study the interaction of centrosomes and the Wnt pathway. We found that SPD-5 was required for a successful cell division, similar to other centrosomal components. This suggests that SPD-5 still functions as a centrosomal component during C. elegans post-embryonic development. It has been shown that establishment of seam cell polarity relies on the asymmetric localization of certain Wnt pathway components. Interestingly, we found that SPD-5 was required for the proper localization of several Wnt components in a way that was independent of a key MTOC (microtubule-organizing center) member γ-tubulin. In addition, SPD-5 genetically interacted with the Wnt pathway components APR-1/APC and POP-1/Tcf to regulate asymmetric divisions of seam cells. These data suggest that SPD-5 interacts with the Wnt signaling pathway in controlling the polarity of seam cells. Overall, our results suggest a novel role of SPD-5 in cooperating with the Wnt signaling pathway to regulate cell polarity and asymmetric cell division, in addition to its function as a centrosomal component. Asymmetric cell division Cell polarity Centrosome Wnt pathway Biology (0306) Molecular Biology (0307)
44	Investigating the role of Wnt/Planar cell polarity (PCP) in Neuromesodermal Progenitors (NMPs) Watson, Julia Alice January 2018 (has links) Neuromesodermal progenitors (NMPs) are bipotent progenitors, located at the caudal end of the embryo and are essential for axis formation. These stem cell-like progenitors possess the ability to self-renew and differentiate to both mesodermal and neural lineages, such as skeletal muscle and spinal cord derivatives. These progenitors arise at E8.5 and are localised in the caudal lateral epiblast (CLE), a posterior region of the embryo near the primitive streak. Later in development, they reside in the tail bud until cessation of axial elongation at E13.5. Throughout these stages NMPs are characteristically marked by co-expression of T(Bra) (Brachyury) and Sox2. This characteristic is also present in in vitro NMPs, which can be derived from Epiblast Stem Cells (EpiSCs) through treatment with Wnt/β-catenin signalling agonists and Fgf2, which simulates their in vivo environment. Protein and mRNA profiling of NMPs and mutant phenotypes in vivo supports the hypothesis that a non-canonical Wnt pathway, the Wnt/Planar Cell Polarity pathway (PCP) could be involved in NMP fate decision and/or maintenance. This thesis focuses on understanding more about the role of PCP by aiming to identify the spatio-temporal profile of Wnt/PCP pathway components in NMP regions during axial elongation, as well as determining its role in NMP behaviour through manipulation of this pathway via in vivo and in vitro assays Employing in situ hybridisation and immunohistochemistry techniques, key Wnt/PCP components, including Pk1, Vangl2 and Ptk7, were confirmed to be present in in vivo and in vitro NMPs, thus, providing strong evidence that Wnt/PCP may be involved regulating NMP behaviour. Disruption of Wnt/PCP signalling through overexpression of Wnt/PCP components was tested in refined in vivo and in vitro assays. Overexpression of Vangl2 and Ptk7, but not Pk1 in NMPs regions in vivo resulted in loss of contribution to neural lineages, as well as lower contribution to NMP regions themselves. Similarly, Wnt/PCP components were disrupted in vitro through generation of dox-inducible overexpression cells lines for Wnt/PCP components. These lines were used to generate NMPs from an optimised novel alternative source Epiblast-Like Cells (EpiLCs), however no clear affect to lineage was observed. Overall this work has successfully advanced our knowledge of Wnt/PCP mediated control of NMP differentiation and maintenance, and provided a finer grained description of the relationships between them.
45	Regulation of fission yeast cell polarity by stress-response pathways Mutavchiev, Delyan Rumenov January 2017 (has links) Cell polarisation is a key biological process crucial for the functioning of essentially all cells. Regulation of cell polarity is achieved through various processes determined by both internal and external factors. An example of the latter is that cell polarity can be disrupted or lost as a consequence of a variety of external stresses. When facing such stresses, cells adapt to unfavourable conditions by activating a range of molecular signalling pathways, collectively termed ‘stress response’. Despite the connections between external stress and cell polarity, whether stress-response signalling regulates cell polarisation and what the molecular basis for such regulation remains an open question. The fission yeast Schizosaccharomyces pombe presents an excellent biological platform to study the complexity of cell polarity regulation on a systematic level. This study is aimed at understanding the functional relationship between stress-response signalling and maintenance of cell polarity in this model organism. The findings presented in this thesis set the basis for establishing a functional link between the activation of the S.pombe stress-response pathway and the activity of the master regulator of cell polarity- the Rho GTPase Cdc42. Here, I describe experiments that identify an active involvement of the stress-response mitogen-activated kinase (MAPK) Sty1 in the dispersal of active Cdc42 from the sites of growth. This new role for Sty1 occurs independently from its involvement in transcription regulation and other previously identified signalling pathways involving Sty1. Furthermore, I also find that Sty1’s involvement in Cdc42 regulation has direct implications for fission yeast physiology as it is essential for the maintenance of cellular quiescence upon nitrogen starvation. This thesis also focuses on identifying the targets of Sty1 orchestrating the active Cdc42 disruption. Here, I describe a candidate-based approach, where I investigate the role of proteins from the Cdc42 regulatory network during Sty1 activation. Additionally, I present a global phospho-proteomics approach to identify novel targets of Sty1 and offer preliminary findings which might explain Sty1’s involvement in Cdc42 regulation.
46	Investigating the mechanisms and the temporal regulation of the first cell polarity establishment in the mouse embryo Zhu, Meng January 2019 (has links) Embryonic cells of many species polarise and the cell polarity is often important for the normal developmental progression. In the mouse embryo, the prototype of epithelial cell polarity, namely apico-basal polarisation, become established at the 2.5 days' post-fertilisation, when the embryos are at the 8-cell stage. The formation of apical domain is necessary and sufficient for the first segregation of extra-embryonic and embryonic cell lineages, as well as the following up morphogenetic transitions, such as the blastocyst formation. This study aims to explore the molecular pathways triggering the first cell polarity establishment in the mouse embryo, and to reveal the mechanism that programmes the timing of this event in the mouse embryo. The results showed that cell polarity establishment during the 8-cell stage development can be divided into two major phases: in the first phase actomyosin complex became polarised to the cell-contact free surface; and in the second phase apical proteins recruited to the actomyosin enriched cell-contact free cortex, they further became centralised in the cell-contact free surface, excluding the local actomyosin meshwork, resulting in the formation of actomyosin ring. The activation and assembly of actomyosin meshwork during the first phase, but not its contractility, was essential for apical protein recruitment. Factors responsible for actin cytoskeleton reorganisation included Phospholipase C (PLC) - Protein Kinase C (PKC) pathway components, they directly activated actomyosin in the first phase through the Rho proteins such as RhoA. Further results showed that the apical protein centralisation step required a proximate transcriptional input that was induced by two transcription factors, Tfap2c and Tead4. RNAi and Genetic depletion of these two factors prevented apical protein centralisation and the final apical domain assembly. The protein expression profile indicated that Tfap2c and Tead4 expression, and therefore their activity, were induced by zygotic genome activation. Significantly, overexpression of Tfap2c, Tead4, together with constitutively activated Rho proteins were sufficient to advance the timing of apical domain formation, indicating that the timer of cell polarity establishment at the 8-cell stage is set by the Rho proteins activation, and the zygotic transcriptional accumulation of Tfap2c and Tead4. Together, these results characterised the molecular events during the cell polarity establishment at the 8-cell stage mouse embryo, and identified the timing regulation of this event.
47	Roles of mammalian Scribble in polarity signaling, virus offense and cell-fate determination Wigerius, Michael January 2010 (has links) Mammalian Scribble is a target for proteins encoded by human papilloma virus, retro- and flaviviruses. Tick-borne encephalitis virus (TBEV) is a flavivirus that have evolved distinct strategies to escape antiviral responses. Information of how flaviviruses intrude on cell integrity comes from understanding of the roles that host-factors play when they interfere with viruses. The first part of this thesis describes a novel interaction between the TBEVNS5 protein and Scribble. The importance of the interaction was demonstrated by RNAi-mediated depletion of Scribble, which prevented suppression of JAK-STAT signaling by NS5. Together, these results define Scribble as a novel target for NS5. TBEV is known to cause central nervous system disease TBE in humans that can lead to cognitive dysfunction. A unifying theme in CNS related diseases are defects in neuronal extensions. We therefore addressed the effects of TBEV expression in PC12 cell differentiation, which is characterized by extensive neurite growth. Our data show that TBEVNS5 suppresses neurite outgrowth through the Rho GTPase Rac1. These findings provide evidence that Rac1 is an indirect target of NS5 in neurite inhibition. Scribble was recently implicated in spine morphogenesis. Thus, we tested the role of Scribble in neurite elongation. Depletion of Scribble in PC12 cells, reduced neurite density but increased length of those remaining. Moreover, Scribble bound components in the Ras/ERK cascade in a growth factor dependent manner. Together, these results demonstrate that Scribble controls neurite elongation by scaffolding MAPK components. Moreover, as loss of dendritic spines, actin-rich protrusions on neurons, is a feature in cognitive dysfunction we speculate that cognitive dysfunction in TBE might involve disturbed Scribble expression by NS5. We also investigated the binding between NS1 of Influenza A virus and Scribble. The PDZ domains of Scribble are usually selective for specific C-terminal motifs in proteins. Because NS1 has a canonical PDZ motif we tested if binding to Scribble depends on this motif. We found that Scribble binds NS1; the association is dependent on the NS1 C-terminus that is recognized by PDZ3-4 of Scribble. Together, these results suggest that Scribble is a target for the H5N1 NS1 protein / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: In press. Paper 3: Manuscript. Paper 4: Manuscript. cell polarity scribble tbev RhoGTPase jak-stat mapk neurite outgrowth influenza a virus Biochemistry Biokemi
48	The Role of Farnesyltransferase β-subunit in Neuronal Polarity in Caenorhabditis Elegans Carr, David, A. 07 February 2013 (has links) Little is known about the molecular components and interactions of the planar cell polarity pathway that regulate neuronal polarity. This study uses a prkl-1 induced backwards locomotion defect as an array to perform a prkl-1 suppressor screen in C. elegans looking for new components of the planar cell polarity pathway involved in the neuronal polarization of VC4 and VC5. The screen discovered twelve new alleles of vang-1, one new allele of fntb-1 and five new mutations in unknown polarity genes. fntb-1 encodes for the worm ortholog of Farnesyltransferase β-subunit and is important for neuronal polarization. Acting cell and non-cell autonomously, fntb-1 regulates the function and localization of prkl-1 through the recognition of a CAAX motif. Therefore, fntb-1 modifies prkl-1 to regulate the neuronal polarity of VC4 and VC5. fntb-1 prkl-1 farnesyltransferase prickle Planar Cell Polarity neuronal polarity C. elegans
49	A FRAP Assay to determine the influence of Crumbs in membrane protein dynamics Bronze Firmino, João Pedro 11 September 2012 (has links) (PDF) Apicobasal polarity is essential for epithelia formation and maintenance. Cell junctions, namely the zonula adherens in Drosophila melanogaster, are the morphological landmarks that define and distinguish the apical from the basal surface. This resulting compartmentalisation is key for the cell and consequently the epithelia. To maintain proper junctions, cells make use of several protein complexes and their interactions. Among these complexes, the Crumbs (Crb) network stands out. Mutations in Crumbs (crb11A22) lead to zonula adherens collapse, consequent loss of apical surface and disaggregation of the epithelia. However, the mechanisms behind this are not known and havenʼt been addressed using modern techniques such as live imaging. Several things came out of the dataset obtained from the FRAP experiments. Firstly, protein kinetics are better described when a double exponential fit curve is used, which raises the possibility that two cell processes might be involved in the recovery observed for the different markers. Another finding was the fact that the kinetics of some polarised protein markers is not the same in every region of the embryo. Distinct areas of the embryo with different morphogenetic activity levels show different kinetics for the same compartment marker. That was the case with SpiderGFP (whole plasma membrane marker) and SASVenus (apical plasma membrane marker) where τ2 was lower in the posterior region of the embryo which is characterised by intense cell movements resulting from convergence extension. DE-CadGFP (zonula adherens marker) and lacGFP (basolateral marker) behaved similarly in the whole embryo. This indicates that convergence extension shows different trafficking needs for the apical surface. In crb11A22, SpiderGFP kinetic spatial differences were not observed. τ2 in the anterior (low level of morphogenesis) is affected and similar to wild type τ2 levels in the posterior. This could pinpoint the fact that the epithelia disaggregation is a result of trafficking failure of apical components. Live imaging of DE-CadGFP in crb11A22 background revealed initial disaggregation in the anterior part of the embryo, which strengthens the idea that Crb is required for adherens junction stabilisation and maintenance. Apicobasal cell polarity FRAP Crumbs Drosophila melanogaster ddc:570 rvk:WD 5100
50	Control of intraflagellar transport : studies of the planar cell polarity effector Fuz, the small GTPase Rsg1, and the novel protein TTC29 Brooks, Eric Robert 19 June 2014 (has links) Cilia are small microtubule based protrusions found on most cells of the vertebrate body. In humans, defects in the structure or function of cilia results in a large class of developmental and homeostatic diseases known collectively as the ciliopathies. Ciliogenesis is accomplished by the concerted action of a number of molecular pathways including the intraflagellar transport (IFT) system. IFT is a group of ~20 highly conserved proteins that assemble into large macromolecular complexes known as trains. These trains act to carry cargo bi-directionally between the cell body and ciliary tip, via interaction with the microtubule motors kinesin and dynein. IFT train dynamics are required for both cilia structure and function, however the controls on these dynamics are still incompletely understood. Here, I present the first platform for study of IFT dynamics within vertebrate multiciliated cells, an understudied population with critical functions in development and homeostasis. Using this platform, I demonstrate that the planar cell polarity effector protein Fuz is required for IFT dynamics via its control of the cytoplasmic localization of a subset of IFT proteins. Subsequently, I find that a Fuz binding partner, the putative small GTPase Rsg1, is also required for IFT protein localization and dynamics. Additionally, I describe a role for Rsg1 in basal body docking, one of the earliest events of ciliogenesis. Finally, I show that the poorly studied protein TTC29 is required for a specific subset of IFT dynamic behaviors. These data reveal novel regulatory motifs for ciliogenesis and demonstrate, specifically, the complexities of IFT regulation in the cytoplasm and within the cilium itself. Finally, they suggest that multiciliated cells provide a tractable platform for generating robust datasets for the investigation ciliary dynamics. Such studies are critical for informing our understanding of the molecular etiology of human ciliopathic diseases. / text Cilia IFT Intraflgellar transport Planar cell polarity PCP Fuz Rsg1 TTC29 Multiciliated cells

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