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Novel roles of ADF/cofilins in maintenance of homeostasis in normal and malignant epithelial cellsKanellos, Georgios January 2017 (has links)
Actin cytoskeletal regulation is of critical importance for a number of diverse cellular functions, including cell motility, endocytosis, cell division and transcription. Tight regulation of actin is critical for many aspects of cancer biology and in particular invasion and metastasis. ADF/cofilins are among the most important actin regulatory proteins. Mammals have three highly conserved members, ADF, CFL1 and CFL2, which regulate actin dynamics by severing and depolymerizing actin filaments. Despite a huge literature on the roles of ADF/cofilins in actin treadmilling and cell migration in vitro and in cancer cell behavior during invasion, very little is known about their collective roles in tissue homeostasis. By employing genetic knock-outs of ADF, in conjunction with conditional depletion of CFL1 using a Cre-LoxP system under the control of the keratin 14 promoter, we were able to study the effects of ADF/CFL1 loss in vivo in the mouse epidermis. Furthermore, by generating ADF-null squamous cell carcinoma (SCC) cell lines and by transiently downregulating CFL1 with RNAi, we were able to investigate further the cellular responses after ADF/CFL1 depletion in vitro. Co-depletion of ADF and CFL1 from the mouse epidermis triggered loss of tissue homeostasis characterized by abnormal thickening of the tissue, actin filament accumulation and nuclear deformation. Loss of ADF/CFL1 in cultured malignant keratinocytes also led to aberrant cell morphology accompanied by unrestrained accumulation of actin stress fibers tethered to enlarged focal adhesions. Enhanced SRF/MAL-mediated transcription fuels this uncontrolled actin polymerization which is also mediated by Arp3. Furthermore, these actin filaments are decorated with phospho-myosin light chain, which indicates their contractile nature. As a consequence, the increased intracellular acto-myosin tension results in nuclear deformation, which is promoted by the deregulated actin filaments tethered to the nuclear envelope via the linker of nucleoskeleton and cytoskeleton (LINC) complex. Overall, we describe new conceptual insight into the cellular functions of ADF/cofilins. We show that their activities are essential for the dynamic regulation of contractile actin filaments that, if left unchecked, lead to loss of cellular homeostasis and cell death promoted by loss of nuclear integrity. Additionally, the critical roles of nuclear actin and actin-associated proteins have recently started being appreciated. Thus, for the first time we set out to investigate new functions of cofilins in the nucleus using proteomics, and identify new cofilin binding partners that implicate them in novel cellular pathways, expanding our knowledge on these small actin-binding proteins.
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Nuclear Rupture in Progeria Expressing CellsBathula, Kranthidhar 01 January 2018 (has links)
Cells regularly take on various types of force in the body. They have structures that are able to mediate, transfer and respond to the forces. A mutation in force regulating proteins such as lamin in the nucleus or the KASH domain which connects the nucleus to the cytoskeleton of the cell can cause catastrophic events to occur. The aims of this study were to better understand the response of the nucleus when structural proteins are mutated or are not present while under force. Progeria, a rare disease where an additional farnesyl group is attached to lamin was used in this study. Different types of forces were used to represent similar conditions in the body. Confinement of endothelial cell width showed an increase of surface defects. When restricting proteins such as actin was removed the nucleus appeared to rupture. This was shown to occur at a higher rate in the progeria groups. Endothelial cells under shear force showed high amount of nuclear rupture in progeria expressing group. prolonged exposure showed more rupture which eventually cased cell death and cells to come off the surface. Progeria expressing smooth muscle cells under cyclic stretch also showed similar results as endothelial cells. The amount and rate of deformation of the nucleus when the cytoskeleton is connected and not was looked at. When the connected the rate of deformation was higher. The high rate of nuclear defects and rupture while under force in progeria expressing cells shows that the nuclei have different structural properties and are weaker. It’s also been shown that the LINC complex contributes to nuclear deformation when stretching.
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TheRole of Emerin and Other Disease-Associated Genes in Myonuclear Movement and Muscle Development in Drosophila:Mandigo, Torrey January 2020 (has links)
Thesis advisor: Eric S. Folker / Thesis advisor: David R. Burgess / Skeletal muscle is a multinucleated cell type in which the many nuclei are precisely positioned to maximize the distance between adjacent nuclei. In order to reach this final positioning, nuclei undergo an elaborate set of movements during muscle development. The disruption of this process is evident throughout muscular dystrophies and myopathies. However, the contribution of aberrant nuclear positioning toward disease progression is unclear and the mechanisms regulating nuclear movement and positioning are poorly defined. The goal of this thesis is to determine the contribution of disease-linked genes to the regulation of nuclear movement and positioning and how these mechanisms are coordinated in skeletal muscle. In this thesis, we utilize Drosophila melanogaster skeletal muscle as an in vivo model system to investigate nuclear positioning throughout muscle development and correlate aberrant nuclear positioning with a decrease in muscle function. We provide the first evidence of distinct mechanisms that are independently regulated by genes that are associated with two different muscle diseases, Emery-Dreifuss muscular dystrophy and Centronuclear myopathy (Chapter 2). We also provide evidence that Emerin-dependent regulation of the LINC complex is a critical determinant of nuclear positioning and for the first time demonstrate a division of Emerin functions among the two Drosophila emerin homologs, bocksbeutel and otefin (Chapter 3). Finally, we conduct a proof-of-concept screen to identify novel regulators of muscle development and function (Chapter 4). Together, the work presented in this thesis provides a framework to further our understanding of the mechanisms regulating nuclear movement and positioning as well as muscle development as a whole. Using the tools and techniques developed throughout this thesis, we provide novel insight into the mechanisms regulating nuclear movement and positioning and strengthen Drosophila as an in vivo model for investigating muscle development and function. / Thesis (PhD) — Boston College, 2020. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.
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Mechanotransduction at the nuclear envelope : the role of forces in facilitating embryonic stem cell fate decisionsWylde, George William January 2017 (has links)
While a large body of work has focused on the transcriptional regulation of cellular identity, the role of the mechanical properties of cells and the importance of their physical interactions with the local environment remains less well understood. In this project, we explored the impact of cytoskeleton-generated forces exerted on the nucleus in the context of early embryonic stem (ES) cell fate decisions. We chose to perturb force generating components in the cytoskeleton – notably the molecular motor non-muscle myosin II - and key structural and chromatin binding proteins in the nuclear envelope, notably, the lamins (LMNA), Lamin B receptor (LBR) and components of the LINC complex (nesprins/KASH). The structural proteins in the nuclear envelope regulate both the mechanical response of the nucleus to force and the stabilization of peripheral heterochromatin (repressed genes). Our hypothesis is that reducing forces transmitted directly to chromatin or increasing tethering of peripheral heterochromatin to the nuclear envelope would restrict access to lineage specific genes sequestered at the nuclear lamina and thereby either impair, or delay, differentiation. We found phenotypes in the capacity of mouse ES cells to specify to the neural lineage following our perturbations: overexpression of LMNA, LBR and KASH proteins resulted in a significant fraction of cells that did not express the neuroectoderm marker Sox1 after four days of differentiation, while inhibiting non-muscle myosin II delayed Sox1 expression in the entire population. Overexpression of LMNA and LBR did not affect the ability of the cells to exit the naive pluripotent state, which raises the possibility that the perturbations are halting the cells in a formative phase prior to lineage specification. Future work will focus on looking at genome-wide transcriptional changes accompanying differentiation combined with an analysis of spatial information of differentially regulated genes.
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Development and Validation of a Novel Resonant Energy Transfer (FRET) Biosensor to Measure Tensile Forces at the LINC Complex in Live CellsArsenovic, Paul 01 January 2017 (has links)
There is a large body of evidence supporting the theory that cell physiology largely depends on the mechanical properties of its surroundings or micro-environment. More recently studies have shown that changes to intra-cellular mechanical properties can also have a meaningful impact on cell function and in some cases lead to the progression of ailments or disease. For example, small changes to the protein sequence of a structural nuclear envelope protein called lamin-A is known to cause a variety of neurological and musculoskeletal diseases referred to as laminopathies. Currently, there is little incite into how these mutations lead to disease progression due in part to an inability to measure protein-specific mechanical changes and how these alterations may relate to disruptions in intra-cellular signaling or function. \par To improve upon the ability to measure mechanical properties inside living cells, a previously validated, genetically-encoded resonant energy transfer (FRET)-force biosensor was modified to localize to the nuclear envelope. This biosensor integrated into the nuclear envelope protein Nesprin-2G and senses small deformations that are resolved by indirect measurements of spectroscopic fluctuations in the fluorescent emission of the sensor. To accurately measure these changes, a new spectral-imaging technique named SensorFRET was developed which can resolve small changes in the FRET sensor under varying levels of fluorescent intensity and with known absolute precision. Using SensorFRET, the Nesprin-2G biosensor (Nesprin-TS) reported changes in actomyosin contractility, nuclear shape, and nuclear deformation. Using Nesprin-TS, fibroblasts derived from patients with Hutchinson-Gilford progeria syndrome (HGPS) reported less force on Nesprin-2G molecules relative to healthy fibroblasts on average.\par To demonstrate how intra-cellular forces on the nucleus may impact normal cell physiology, bone-marrow derived mesenchymal stem cells (MSCs) were genetically modified such that the cytoskeleton was decoupled from the nucleus by saturating KASH binding proteins with a non-functional truncated protein called DN-KASH. MSCs treated with DN-KASH preferentially differentiated into osteocytes (bone cells) at a higher rate than MSCs exposed to osteogenic growth factors. This osteogenic preference after DN-KASH treatment was independent of the cell substrate topology and did not significantly alter integrin expression. However, this tendency to differentiate into osteocytes was dependent on substrate stiffness. Overall, the data imply that an intra-cellular force-dependent mechanism connected to the cell nucleus strongly influences MSC differentiation.
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Fonction des protéines de l'enveloppe et de la périphérie nucléaire sur l'organisation du noyau chez Arabidopsis thaliana / Function of envelope and nuclear periphery proteins on the organization of Arabidopsis thaliana nucleiVoisin, Maxime 07 December 2017 (has links)
Le noyau est une innovation évolutive majeure caractéristique des organismes eucaryotes. Ces dernières années de nombreux travaux se sont intéressés à l’organisation de la chromatine dans l’espace nucléaire lors de l’interphase. Les protéines associées à la périphérie nucléaire ou ancrées dans la membrane nucléaire interne ont suscité un intérêt majeur due à leur contribution dans l’organisation spatiale de la chromatine. Chez les animaux, les lamines qui forment des filaments à la périphérie nucléaire et le complexe LINC, un complexe protéique reliant la membrane externe et interne du noyau sont connues pour interagir avec la chromatine, influencer l’organisation de cette dernière et moduler la régulation transcriptionnelle. Chez la plante modèle Arabidopsis thaliana utilisée dans ce travail, le complexe LINC est conservé, par contre les lamines ne le sont pas et seraient remplacées par d’autres acteurs spécifiques du règne végétal. Le travail détaillé dans ce manuscrit porte sur la mise en évidence d’un nouveau réseau d’interaction protéique localisé à la périphérie nucléaire et sur l’impact de ces protéines dans la morphologie du noyau et l’organisation de la chromatine. Mes travaux se sont concentrés sur les protéines à domaine SUN, l’une des composantes du complexe LINC et sur les protéines CRWN et KAKU4 présentes à la périphérie du noyau. Des cribles double hybride chez la levure m’ont permis d’identifier 24 partenaires protéiques potentiels dont plus d’un tiers sont des facteurs de transcription L’étude plus précise du facteur de transcription MaMYB pour lequel nous avons créé un allèle nul par la méthode CRISPR montre qu’il joue un rôle plus spécifique dans la formation des racines. L’étude de mutants combinatoires pour les gènes SUN, CRWN et KAKU4 montre des anomalies développementales notamment des tissus reproductifs. Enfin, une étude plus détaillée de la protéine KAKU4 suggère sa participation au maintien de la morphologie du noyau et au rapprochement de l’hétérochromatine vers la périphérie nucléaire. En résumé, mes travaux ont mis en évidence l’existence d’un réseau de facteurs de transcription recrutés à la périphérie nucléaire par les protéines SUN, CRWN et KAKU4. Ce réseau d’interaction protéine-protéine participerait à un mécanisme de séquestration de certains facteurs de transcription et/ou d'un rapprochement à la périphérie nucléaire de certains domaines de chromatine afin d’activer ou de réprimer leur transcription. / The nucleus is a major evolutionary innovation characteristic of eukaryotic organisms. In recent years, numerous studies have focused on the organization of chromatin in nuclear space during interphase. Proteins associated with the nuclear periphery or anchored in the inner nuclear membrane have been particularly studied for their contribution to the spatial organization of chromatin. In animals, the lamina that forms filaments at the nuclear periphery and the LINC complex, a protein complex linking the outer and inner membrane of the nucleus, are known to interact with chromatin, to influence its organization and to modulate transcriptional regulation. In the model plant Arabidopsis thaliana used in this work, the LINC complex is conserved, but not the lamina constituents, which are replaced by other specific actors of the plant kingdom. The work detailed in this manuscript identified a new protein interaction network located on the nuclear periphery and studied the impact of these proteins on nuclear morphology and chromatin organization. My work focused on SUN-domain proteins, one of the components of the LINC complex, and on the CRWN and KAKU4 proteins at the periphery of the nucleus. Double hybrid screens in yeast allowed me to identify 24 potential protein partners, more than a third of which are transcription factors. The more precise study of the transcription factor MaMYB for which we created a null allele using the CRISPR method, shows that it plays a more specific role in root formation. The study of mutant combinations for SUN, CRWN and KAKU4 genes reveals developmental abnormalities, particularly in reproductive tissue. Finally, a more detailed study of the role of the KAKU4 protein suggests that it contributes to the morphology of the nucleus in maintaining heterochromatin at the nuclear periphery. In summary, we propose the existence of a transcription factor network recruited to the nuclear periphery by SUN, CRWN and KAKU4 proteins. This protein-protein interaction network would participate in the sequestration of certain transcription factors and/or the localization of certain chromatin domains to the nuclear periphery in order to activate or suppress their transcription.
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Plant nuclear envelope-associated proteins function in development and symbiosis.Anna, Newman-Griffis Hare January 2018 (has links)
No description available.
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Establishing the role of SINE proteins in regulating stomatal dynamics in Arabidopsis thalianaBiel, Alecia Marie 01 October 2021 (has links)
No description available.
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