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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
181

Exploring Chondrocyte Integrin Regulation of Growth Factor IGF-I Expression from a Transient pAAV Vector

Ratley, Samantha Kay 20 August 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Insulin-like Growth Factor I (IGF-I) is a growth factor that stimulates both mitogenic and anabolic responses in articular chondrocytes. While it has been shown that exogenous IGF-I can regulate chondrocyte integrins, little is known regarding regulatory effects of IGF-I produced from a transiently expressed plasmid based adeno-associated virus (pAAV) vector. Because chondrocytes are using cellular machinery to overexpress IGF-I, it is of interest to see whether or not pAAV IGF-I will significantly upregulate or downregulate chondrocyte integrins. Additionally, it is of interest to know whether chondrocyte adhesion through integrins will have any regulatory effects on the production of IGF-I from the transgene. Therefore, this study will ascertain if pAAV IGF-I will have similar effects that exogenous IGF-I has on integrin regulation and if integrin silencing mechanisms will affect the production of IGF-I from the transgene. To test these hypotheses, adult articular chondrocytes were doubly transfected with the pAAV vector for IGF-I and short interference ribonucleic acid (siRNA) for integrins beta 1 and alpha V. Gene products were monitored at the transcriptional levels using quantitative real time polymerase chain reactions (qPCR) and IGF-I protein production was monitored at the translational level using enzyme linked immunoabsorbant assays (ELISAs). Adult articular chondrocytes doubly transfected were encapsulated in a three dimensional hydrogel system to simulate an in vivo environment. Samples were collected for analysis at days 2, 4, and 6 post encapsulation. Results show that IGF-I treatment with the pAAV vector does not cause significant changes in the transcriptional regulation of the beta 1 integrin in a three dimensional hydrogel system. The pAAV IGF-I vector did not cause significant regulatory changes on integrin alpha V at any time point during the experiment. Additionally, by knocking down the expression levels of integrins by using siRNA, it was shown that integrin knockdown does not have a significant regulatory effect on transcriptional or translational expression levels of IGF-I from the pAAV vector.
182

Models of chromosome architecture and connection with the regulation of genetic expression / Modèles de l'architecture du chromosome et lien avec la régulation de l'expression génétique

Le Treut, Guillaume 29 November 2016 (has links)
Plusieurs indices suggèrent que le repliement du chromosome et la régulation de l’expression génétique sont étroitement liés. Par exemple, la co-expression d’un grand nombre de gènes est favorisée par leur rapprochement dans l’espace cellulaire. En outre, le repliement du chromosome permet de faire émerger des structures fonctionnelles. Celles-ci peuvent être des amas condensés et fibrillaires, interdisant l’accès à l’ADN, ou au contraire des configurations plus ouvertes de l’ADN avec quelques amas globulaires, comme c’est le cas avec les usines de transcription. Bien que dissemblables au premier abord, de telles structures sont rendues possibles par l’existence de protéines bivalentes, capable d’apparier des régions parfois très éloignées sur la séquence d’ADN. Le système physique ainsi constitué du chromosome et de protéines bivalentes peut être très complexe. C’est pourquoi les mécanismes régissant le repliement du chromosome sont restés majoritairement incompris.Nous avons étudié des modèles d’architecture du chromosome en utilisant le formalisme de la physique statistique. Notre point de départ est la représentation du chromosome sous la forme d’un polymère rigide, pouvant interagir avec une solution de protéines liantes. Les structures résultant de ces interactions ont été caractérisées à l’équilibre thermodynamique. De plus, nous avons utilisé des simulations de dynamique Brownienne en complément des méthodes théoriques, car elles permettent de prendre en considération une plus grande complexité dans les phénomènes biologiques étudiés.Les principaux aboutissements de cette thèse ont été : (i) de fournir un modèle pour l’existence des usines de transcriptions caractérisées in vivo à l’aide de microscopie par fluorescence ; (ii) de proposer une explication physique pour une conjecture portant sur un mécanisme de régulation de la transcription impliquant la formation de boucles d’ADN en tête d’épingle sous l’effet de la protéine H-NS, qui a été émise suite à l’observation de ces boucles au microscope à force atomique ; (iii) de proposer un modèle du chromosome qui reproduise les contacts mesurés à l’aide des techniques Hi-C. Les conséquences de ces mécanismes sur la régulation de la transcription ont été systématiquement discutées. / Increasing evidences suggest that chromosome folding and genetic expression are intimately connected. For example, the co-expression of a large number of genes can benefit from their spatial co-localization in the cellular space. Furthermore, functional structures can result from the particular folding of the chromosome. These can be rather compact bundle-like aggregates that prevent the access to DNA, or in contrast, open coil configurations with several (presumably) globular clusters like transcription factories. Such phenomena have in common to result from the binding of divalent proteins that can bridge regions sometimes far away on the DNA sequence. The physical system consisting of the chromosome interacting with divalent proteins can be very complex. As such, most of the mechanisms responsible for chromosome folding and for the formation of functional structures have remained elusive.Using methods from statistical physics, we investigated models of chromosome architecture. A common denominator of our approach has been to represent the chromosome as a polymer with bending rigidity and consider its interaction with a solution of DNA-binding proteins. Structures entailed by the binding of such proteins were then characterized at the thermodynamical equilibrium. Furthermore, we complemented theoretical results with Brownian dynamics simulations, allowing to reproduce more of the biological complexity.The main contributions of this thesis have been: (i) to provide a model for the existence of transcrip- tion factories characterized in vivo with fluorescence microscopy; (ii) to propose a physical basis for a conjectured regulatory mechanism of the transcription involving the formation of DNA hairpin loops by the H-NS protein as characterized with atomic-force microscopy experiments; (iii) to propose a physical model of the chromosome that reproduces contacts measured in chromosome conformation capture (CCC) experiments. Consequences on the regulation of transcription are discussed in each of these studies.

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