Global ETD Search

271	Regulation of vascular smooth muscle actin cytoskeleton by Hic-5 Pieri, Maria January 2016 (has links) Vascular smooth muscle cells (VSMC) constitute an important component of blood vessels and are primarily responsible for vessel contraction. In vascular disorders such as hypertension and atherosclerosis as well as pregnancy and exercise, VSMC demonstrate increased capacity to proliferate and migrate, resulting in vascular remodelling. The actin cytoskeleton is an important component of vascular contractility and is also essential for proliferation and migration of VSMC. Vasoactive agonists such as Endothelin-1 (ET-1) and Noradrenaline (NA), have been shown to mediate VSMC contraction through changes in actin cytoskeleton and focal adhesion (FA) remodelling, and have also been reported to cause VSMC migration in the appropriate setting. The aim of this study was to investigate the signalling mechanisms responsible for FA dependent actin cytoskeleton remodelling of VSMC in response to ET-1 and NA, with a special focus on Hydrogen peroxide-inducible clone 5 (Hic-5). The latter is a FA protein shown to regulate actin cytoskeleton dynamics in small arteries in response to Noradrenaline (NA) and the response of VSMC to arterial injury and abdominal aortic aneurysm. We have shown that Src-dependent tyrosine phosphorylation of Hic-5 regulated its subcellular localisation in mouse embryonic fibroblasts and VSMC, but was not responsible for the effects of ET-1 and NA on actin filament remodelling or Hic-5 redistribution in VSMC. ET-1 stimulation caused an increase in Hic-5 localisation at FAs concurrent with an increase in the density of actin filaments, whereas NA stimulation caused a decrease in Hic-5 localisation at FAs in VSMC concurrent with actin filament redistribution at the cell cortex. Hic-5 was the FA protein that demonstrated the most dramatic changes in subcellular localisation in response to ET-1 and NA, when compared to paxillin (Hic-5 homologue) or vinculin (classical FA marker). NA-mediated changes in Hic-5 localisation and actin filament distribution were more pronounced compared to ET-1-mediated changes. Further investigation into the NA-induced changes suggested that actin filament disassembly preceded Hic-5 relocalisation from FAs to the cytosol. These results show that vasoactive peptides cause Hic-5 relocalisation and actin filament rearrangement in VSMCs in an agonist-dependent manner. Given that VSMC FA remodelling and actin cytoskeleton reorganisation occur during contraction and arterial remodelling, our data identify Hic-5 as a key regulator of these processes in response to NA and ET-1. Furthermore, these data have implications in agonist- specific VSM function such as migration and contraction. 572.8
272	Fluorescence correlation spectroscopy for studying intermediate filament assembly Schroeder, Viktor 04 August 2017 (has links) No description available. 571.4 Fluorescence correlation spectroscopy FCS intermediate filaments IF vimentin microfluidics cytoskeleton Biologie (PPN619462639)
273	Etude de l'apoptose et de l'autophagie chez Leishmania major / Apoptosis and autophagy in Leishmania major Basmaciyan, Louise 15 December 2016 (has links) Leishmania est un protozoaire parasite de l’ordre de Kinétoplastida de la famille des Trypanosomatidés, agent pathogène des leishmanioses. Au cours de cette thèse nous nous sommes intéressés à l’apoptose chez L. major. Bien que ce processus soit phénotypiquement identique à l’apoptose des mammifères, les protéines clés et les voies métaboliques impliquées restent largement inconnues. L’autophagie étant paradoxalement étroitement liée à l’apoptose, nous nous sommes également intéressés à ce processus de survie cellulaire. La première partie de ce travail a permis de décrire le phénotype autophagique et de montrer qu’apoptose et autophagie sont deux processus distincts mais également en lien étroit. Dans la deuxième partie, nous nous sommes focalisés sur la métacaspase de L. major LmjMCA. Nous avons observé un rôle de LmjMCA similaire à celui des caspases humaines au cours de l’apoptose, en lien avec son domaine catalytique. Nous avons montré que la surexpression de LmjMCA induit l’entrée en autophagie des cellules. Enfin, la troisième partie de ce travail s’est concentrée sur l’étude du cytosquelette. Nous avons ainsi pu établir un lien entre (dé)glutamylation, apoptose et autophagie. Nous avons mis en évidence que la polyglutamylation du cytosquelette, entraîne l’entrée en apoptose des cellules tandis que la déglutamylation du cytosquelette est associée au processus de survie cellulaire. Ce travail a permis de mieux caractériser les processus d’autophagie et d’apoptose chez Leishmania. Ces résultats permettent d’ouvrir des perspectives dans le développement de nouveaux outils thérapeutiques. / Leishmania is a protozoan parasite of the Kinetoplastida order and the Trypansomatid family and is the causative agent of leishmaniasis. In this thesis we focused on apoptosis in L. major. Although this process is phenotypically similar to mammal apoptosis, key proteins and metabolic pathways involved remain largely unknown. Autophagy being paradoxically closely linked to apoptosis, we were also interested in this cell survival process and its relationship with programmed cell death. The first part of this thesis has described the phenotypical changes during autophagy and shown that apoptosis and autophagy are two separate processes, but there is also a close relationship between these two mechanisms. In the second part of this thesis, we have demonstrated that LmjMCA has a role similar to the one of human caspases during apoptosis, through its catalytic domain. In addition, we have shown that LmjMCA overexpression induces autophagy entry after nutrient deprivation via its C-terminal domain.The third part of this work has focused on the study of the cytoskeleton. We could establish a link between (de)glutamylation, apoptosis and autophagy. Indeed, we have shown that cytoskeleton polyglutamylation induces cell death while cytoskeleton deglutamylation is associated with the cell survival process autophagy. This thesis allowed us to better characterize the autophagy and apoptosis processes in Leishmania and to identify the metacaspase as involved in the corresponding pathways. These results open perspectives in the development of new therapeutic tools. Leishmania Apoptose Autophagie Cytosquelette Microtubules Modifications post-Traductionnelles Leishmania Apoptosis Autophagy Cytoskeleton Microtubules Post-Translationnal modification
274	Inter- and Intracellular Effects of Traumatic Axonal Injury Dabiri, Borna Esfahani 04 June 2016 (has links) Mild Traumatic Brain Injuries (mTBIs) are non-penetrating brain injuries that do not result in gross pathological lesions, yet they may cause a spectrum of cognitive and behavioral deficits. mTBI has been placed in the spotlight because of increased awareness of blast induced and sports-related concussions, but the underlying pathophysiological mechanisms are poorly understood. Several studies have implicated neuronal membrane poration and ion channel dysfunction as the primary mechanism of injury. We hypothesized that injury forces utilize mechanically-sensitive, transmembrane integrin proteins, which are coupled to the neuronal cytoskeleton (CSK) and distribute injury forces within the intracellular space, disrupting CSK organization and reducing intercellular neuronal functionality. To test this, magnetic beads were coated with adhesive protein, allowing them to bind to integrins in the neuronal membrane in vitro. To apply forces to the neurons via the bound beads, we built custom magnetic tweezers and demonstrated that focal adhesions (FACs) formed at the site of bead binding. We showed that the beads were coupled to the CSK via integrins by measuring the disparate adhesion of the soma and neurite to their underlying substrate. The soma also required more force to detach than neurites, correlating with the FAC density between each neuronal microcompartment and substrate. We then utilized the magnetic tweezers to test whether beads bound to integrins injured neurons more than beads that bound to neurons nonspecifically. Integrin-bound beads injured neurons more often and the injury was characterized by the formation of focal swellings along axons, reminiscent of Diffuse Axonal Injury. While integrin-bound beads initiated swellings throughout neurons, beads bound nonspecifically only caused local injury where beads were attached to neurons. To demonstrate the electrical dysfunction of integrin-mediated injury forces, we adapted Magnetic Twisting Cytometry to simultaneously apply injury forces to beads bound to multiple cells within neuronal networks in vitro. The formation of focal swellings resulted in reduced axonal electrical activity and decreased coordinated network activity. These data demonstrate that the mechanical insult associated with mTBI is propagated into neurons via integrins, initiating maladaptive CSK remodeling that is linked to impaired electrical function, providing novel insight into the underlying mechanisms of mTBI. / Engineering and Applied Sciences Biomedical engineering Cytoskeleton Integrin Magnetic Tweezers Magnetic Twisting Cytometry Traumatic Axonal Injury Traumatic Brain Injury
275	Positioning nuclei at the periphery of skeletal muscle cells / Positionnement des noyaux à la périphérie des cellules musculaires Roman, William 27 September 2016 (has links) Les mouvements nucléaires sont importants pour une multitude de fonctions cellulaires et sont induits par des forces produites par des protéines moteurs et le cytosquelette. Lors de la formation et régénération de myofibres, les noyaux migrent du centre à la périphérie de la cellule pour son bon fonctionnement. De plus, certaines maladies musculaires sont caractérisées par une accumulation de noyaux centraux. En utilisant une approche théorique et empirique, nous démontrons que le mouvement de noyaux vers la périphérie des myofibres est induit par des forces centripètes autour des noyaux ainsi que par des changements locaux de rigidité nucléaire. Ces forces centripètes sont générées par la contraction de myofibrilles et par leur réticulation autour des noyaux. Les changements de rigidité nucléaire relèvent d’une asymétrie de la distribution de la lamin A/C. En débutant par BIN1, gène muté dans les myopathies centro-nucléés (CNM), nous avons identifié la cascade moléculaire à l’origine du mouvement des noyaux. Nous montrons que l’Amphiphysin 2 (BIN1) est indispensable pour le recrutement de N-WASP, activateur du complexe Arp2/3 afin de promouvoir la polymérisation de l’actine. Cette cascade est nécessaire au mouvement des noyaux vers la périphérie et pour la formation de triades transversales. Cet enchainement est perturbé chez certains patients portant des mutations de BIN1 car cela affecte la bonne localisation de l’Amphiphysin 2. Bien que provenant de la même cascade, le mouvement des noyaux vers la périphérie et la formation transversale de triades sont des processus indépendants. Un complexe de Arp2/3 contenant Arpc5L avec la γ-actine organisent la desmine et donc la réticulation des myofibrilles important pour le mouvement nucléaire. En revanche, un complexe de Arp2/3 contenant Arpc5 avec la β-actine est nécessaires à la formation de triades transversales. / Nuclear movements are important for multiple cellular functions and are driven by forces originating from motor proteins and cytoskeleton. During skeletal myofiber formation or regeneration, nuclei move from the center to the periphery of the myofiber for proper muscle function. Furthermore, centrally located nuclei are found in different muscle disorders. Using theoretical and experimental approaches, we demonstrate that nuclear movement to the periphery of myofibers is mediated by centripetal forces around the nucleus in combination with local changes of nuclear stiffness. The centripetal forces are generated by myofibril contraction, cross-linking and zipping around the nucleus. Local changes of nuclear stiffness are achieved by asymmetric distribution of lamin A/C. Beginning with BIN1, gene mutated in centronuclear myopathies (CNMs); we identified the molecular cascade involved in nuclear movement to the periphery. We show that Amphipysin 2 (BIN1) is important for N-WASP recruitment which itself activates the Arp2/3 complex to induce actin polymerization. This cascade is important for nuclear movement to the periphery and transversal triad formation. This pathway is perturbed in certain patients harboring BIN1 mutations as it leads to mis-localized amphiphysin 2. Despite originating from the same pathway, peripheral nuclear movement and transversal triad formation are independent processes. An Arp2/3 complex containing Arpc5L together with γ-actin organize desmin to cross-link and zip myofibrils for nuclear movement whereas an Arp2/3 complex containing Arpc5 together with β-actin is required for transversal triad formation. Biologie cellulaire Mouvement nucléaire Myologie Cytosquelette Myopathies Centro-Nucléés Triades Cytoskeleton Nuclear movement Centronuclear myopathies 571.6
276	Nuclear and Cytoskeletal Prestress Govern the Anisotropic Mechanical Properties of the Nucleus Macadangdang, Joan Karla January 2012 (has links) Physical forces in the cellular microenvironment play an important role in governing cell function. Forces transmitted through the cell cause distinct deformation of the nucleus, and possibly play a role in force-mediated gene expression. The work presented in this thesis drew upon innovative strategies employing simultaneous atomic force and laser-scanning confocal microscopy, as well as parallel optical stretching experiments, to gain unique insights into the response of eukaryotic cell nuclei to external force. Non-destructive approaches confirmed the existence of a clear anisotropy in nuclear mechanical properties, and showed that the nucleus' mechanical response to extracellular forces is differentially governed by both nuclear and cytoskeletal prestress: nuclear prestress regulates shape and anisotropic deformation, whereas cytoskeletal prestress modulates the magnitude and degree of deformation. Importantly, the anisotropic mechanical response was conserved among diverse differentiated cell types from multiple species, suggesting that nuclear mechanical anisotropy plays an important role in cell function. nucleus eukaryotic cell atomic force microscopy confocal microscopy optical stretcher cytoskeleton force transduction anisotropy
277	Phosphorylation of Filamin A by Cdk1/cyclin B1 Regulates Filamin A Subcellular Localization and is Important for Daughter Cell Separation Szeto, Sandy January 2014 (has links) In cell culture, entry into mitosis of many adherent mammalian cells is accompanied by substantial changes in cellular architecture. Flat, spread-out interphase cells detach from the extracellular matrix and become more spherical. These changes in cell shape are mediated by rearrangements in the actin cytoskeleton, a dynamic network of actin filaments that are organized by actin-binding proteins. Filamin A (FLNa) is a 280 kD actin-binding protein that crosslinks actin filaments into parallel bundles or three-dimensional orthogonal networks. We previously identified FLNa as an in vitro substrate of cyclin-dependent kinase 1 (Cdk1), a kinase that regulates entry into mitosis, and hypothesized that Cdk1 phosphorylation of FLNa regulates mitotic actin remodelling. Using mass spectrometry and a p-FLNa antibody, we show that FLNa is phosphorylated in vivo in HeLa cells on multiple Cdk1 sites, including serines 1084, 1459 and 1533. All three sites match the phosphorylation consensus sequence of Cdk1. We further show that p-FLNa is almost fully dephosphorylated by anaphase, consistent with it being a cell cycle-regulated substrate. Using a phospho-specific antibody, we find that p-FLNa has decreased cortical actin localization compared to total FLNa in mitotic cells. To investigate the functional role of mitotic FLNa phosphorylation, we mutated serines 1084, 1459 and 1533 to nonphosphorylatable alanine and expressed this FLNa mutant (FLNa-S1084A, S1459A, S1533A, referred to as “FLNa-AAA GFP”) in FLNa-deficient human M2 melanoma cells. FLNa-AAA GFP-expressing cells have enhanced FLNa-AAA GFP localization at sites of contact between daughter cells and this correlates with defects in cell division and impaired cell migration. Therefore, mitotic delocalization of cortical FLNa is critical for successful cell division and interphase cell behaviour. Actin cytoskeleton remodeling Mitotic cell rounding Filamin A Cyclin-dependent kinase 1 Mitosis Phosphorylation
278	Mechanics and Mechanotransduction of Adherent Cells: A Compendium of Atomic Force Microscopy Studies Haase, Kristina M. January 2014 (has links) Mechanical cues have been recognized to be critically important in the regulation of cells. A myriad of cellular processes including differentiation, proliferation, and gene expression are all affected by physical forces from the extra- and intra-cellular microenvironments. Despite recent advances in nano-technologies, many questions still surround how cells sense and respond to forces. Through a series of studies, we demonstrate how both the structure and inherent mechanical properties of the cell affect their response to mechanical cues. We first develop a methodology to mechanically manipulate cells while simultaneously characterizing their deformations. Using combined atomic force and confocal microscopy techniques and through systematic examination we demonstrate the role of the cytoskeleton and nucleus in the deformability and shape change of epithelial cells. Mechanical properties have been used in recent years to identify diseased states, including cancer. With this in mind, we used HeLa cells as a model and characterized significant deformability of their plasma membrane and underlying cortex. Importantly, we demonstrate and characterize their ability to recover from large shape changes, which we also observed in other epithelial cells. Shape recovery is shown to be rapid and reliant upon the actin cytoskeleton and intracellular fluid flow. Although the nucleus does not contribute significantly to the deformation and recovery of HeLa cells, the importance of nuclear mechanics cannot be forgone. In vitro studies have shown that mechanical forces transmitted through the cell’s cytoskeleton critically affect nuclear mechanics and gene transcription processes. Many others have used simple models and isolated nuclei in an attempt to characterize nuclear properties. Thus, in a subsequent study, we examine the nucleus within intact cells. Nuclear shape change, in response to force, is shown to be complex and cannot be well-characterized by isotropic mechanical properties. Characterization of the mechanics of the cell, as demonstrated through our findings, is crucial in the field of biological physics. The aforementioned studies, written as scientific articles, are presented in the body of this thesis (Chapters 2-5). A review article that focuses on mechanotransduction and relevant examples using AFM as a tool for its examination acts as an introductory chapter. Cell mechanics Atomic Force Microscopy Mechanotransduction Nuclear mechanics Plasma membrane Cytoskeleton
279	Régulation de l’activité des GTPases de la famille Rho : implication dans la migration et l’invasion cellulaire / Regulation of RhoGTPases family : implication in cell migration and invasion Bidaud-Meynard, Pierre-Aurélien 21 December 2011 (has links) Les GTPases de la famille Rho sont les principaux régulateurs du remodelage du cytosquelette d’actine lors de la migration et l’invasion cellulaire. En particulier, deux membres de cette famille sont importants dans ce processus : les GTPases RhoA et Rac1. En effet, il existe une balance d’activité de ces GTPases, responsables respectivement de la contraction cellulaire et de la formation d’extensions cytoplasmiques, des étapes clefs de la migration. L’objectif de ce travail de thèse a été d’étudier la régulation de ces protéines dans la migration et l’invasion cellulaire. Pour cela, plusieurs stratégies ont été entreprises. Tout d’abord, une étude structure/fonction de la protéine p190RhoGAP-A (p190A), un des régulateurs majeurs de la GTPase RhoA, a été réalisée. Cette étude a permis de mettre en évidence un domaine, appelé PLS pour « protrusion localization sequence », permettant à cette protéine de se localiser au niveau des extensions membranaires appelées « replis membranaires » et « lamellipodes » où RhoA est régulée localement. D’autre part, un mutant délété de ce domaine, appelé PLSp190A, ne peux pas se localiser au niveau de ces structures et a un impact négatif sur leur formation et la migration cellulaire. De plus, l’analyse de ce mutant a révélé que le domaine PLS était impliqué dans la régulation négative de p190A. Ainsi, nous avons mis en évidence un nouveau domaine de p190A responsable de sa localisation intracellulaire et de sa fonction. La deuxième partie de ce travail de thèse a été consacrée à la mise en place d’un outil de mesure de l’activité des GTPases Rho par la technologie Alphascreen. Ce test a permis de mesurer l’activité de Rac1 in vitro et in cellulo mais a également été appliqué à un crible en vue d’identifier de nouvelles molécules régulatrices de Rac1. Ainsi, ce travail de thèse, en abordant par plusieurs angles la régulation des GTPases de la famille Rho, a permis d’apporter des informations et des outils pour la compréhension des mécanismes complexes régissant la capacité des cellules à se mouvoir dans leur environnement. / RhoGTPases are major regulators of the actin cytoskeleton during cell migration and invasion. Particularly, the two members of the RhoGTPase family, RhoA and Rac1 play important roles in these processes. Indeed, a reciprocal balance between these GTPases’activity that leads to cell contraction and cell protrusion formation, determines cell movement. The aim of this PhD thesis was to study the regulation of RhoA and Rac1 during cell migration and invasion. To this end, various strategies were undertaken.We first performed a structure/function analysis of p190RhoGAP-A (p190A), a major negative regulator of RhoA. This led to the identification of a protrusion localization sequence (“PLS”) necessary and sufficient for p190A targeting to actin-based structures. A p190A mutant deleted of the PLS domain (PLS), does not localize to ruffles and lamellipodia, where RhoA is locally regulated during cell migration. This analysis also revealed that the PLS is required for the negative regulation of p190A activity. Finally, p190APLS expression has a dominant negative effect on the formation of actin protrusions and cell migration. Thus, we identified a novel functional domain of p190A required for its proper subcellular localization and functions. The second part of this PhD thesis was focused on the design of an Alphascreen technology-based assay to study GTPases activity. This assay allowed the measurement of Rac1 activity in vitro and in cellulo. Moreover, we used this assay to screen for new regulators of Rac1 activity. In conclusion, this work provides new insights and new tools for the understanding of RhoGTPase involvement in cell migration. Migration cellulaire Cytosquelette d’actine GTPases de la famille Rho Cell migration Actin cytoskeleton RhoGTPases
280	Estudo do significado biológico da multinucleação induzida por vincristina em células em cultura / The study of biological meaning of multinucleation induced by vincristine in cultured cells Elly Kayoko Nakagawa 23 October 2006 (has links) O estudo de agentes que interferem no funcionamento das proteínas relacionadas com o ciclo celular é importante para a compreensão dos processos de transformação e de morte celular. Alterações de ploidia, embora presentes na maioria dos tumores humanos, não têm ainda seu papel conhecido no processo de oncogênese. A alteração do número cromossômico é conseqüência primária de erros que envolvem o fuso mitótico e o cinetócoro. Dessa maneira, drogas que agem sobre os microtúbulos são consideradas aneugênicas potenciais. O presente trabalho enfocou o estudo do mecanismo pelo qual drogas que atuam sobre microtúbulos levam ao aparecimento de células multinucleadas e o significado biológico destas. Os resultados mostraram que a vincristina induziu bloqueio em mitose das células BBnt e MDCK, com conseqüente entrada em interfase no estado multinucleado. As células multinucleadas não apresentaram sinais de morte celular por apoptose, entretanto, quando em prófase apresentaram vários centrossomos, que poderiam originar divisões celulares com fusos multipolares. Estes resultados indicam que essas linhagens celulares possuem pontos de checagem mitótico funcionais e células multinucleadas são viáveis e capazes de prosseguir no ciclo celular. A presença de mitoses com fusos multipolares é indício de que as células multinucleadas passam por divisões anormais, que progrediriam para apoptose resultando na eliminação desta população. / The study of agents that interfere in the functionality of proteins related to cell cycle is important for the understanding of the transformation and cell death processes. Although ploidy alterations are presented in the majority of human tumors, their role in oncogenic process is not understood yet. The alteration on chromosomal number is the primary consequence of errors involving the mitotic spindle and kinetocore. Thus, drugs acting on the microtubules are considered as potentially aneugenic agents. The present work aimed to study the mechanism of multinucleated cells induction by action of antimicrotubule drug and biological meaning of these cells. The results showed that vincristine induced mitotic arrest of both BBnt and MDCK cells, with consequent entrance into interphasic-multinucleated status. Multinucleated cells did not present features of cell death by apoptosis; they were still viable and able to go further in cell-cycle progression. The presence of many structures suggested microtubule enucleation, centrosomes-like were detected on treated cells and could be responsible for the multi-spindle assembling that leads the multinucleated cells to abnormal divisions. Later on, when the multinucleated cells accumulated more abnormalities they were eliminated from the cell population by apoptosis. Aneuploidia Apoptose Citoesqueleto Cultura celular Multinucleação Vincristina Aneuploidy Apoptosis Cell culture Cytoskeleton Multinucleation Vincristine

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