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Modification du phénotype des chondrocytes dans la plaque de croissance et le cartilage articulaire : de la physiologie à la pathologie / Modification of chondrocyte phenotype in growth plate and articular cartilage : from physiology to pathologyDeng, Chaohua 28 June 2017 (has links)
Cartilage est un tissu unique, caractérisé par la matrice extracellulaire abondante et un seul type de cellule, le chondrocytes. Les modifications du phénotype chondrocytes, tels que la prolifération et de l'hypertrophie, sont des événements physiologiques survenant au cours du développement squelettique et cartilage articulaire adulte. Dans la plaque de croissance, la division active et l'expansion des chondrocytes est le mécanisme principal lors du processus de l’ossification endochondrale. Les chondrocytes jouent un rôle essentiel dans ce processus. Le comportement et les caractéristiques cellulaires des chondrocytes de la plaque de croissance sont régulées à tous les stades de l'ossification endochondrale par un réseau complexe d'interactions entre les hormones circulantes, les facteurs de croissance produits localement et la matrice extracellulaire sécrétée par les chondrocytes. Dans le cartilage articulaire, les chondrocytes forment des régions morphologiquement distinctes et maintiennent l'équilibre entre production et dégradation des composants de la matrice extracellulaire. Cependant, l'altération pathologique du phénotype des chondrocytes pourrait entraîner de nombreuses maladies squelettiques et articulaires humaines, y compris les chondrodysplasies et l'arthrose. Dans ce contexte, mon projet de doctorat a été conçu pour étudier I) les modifications des phénotypes chondrocytaires déclenchés par les déterminants génétiques et le stress métabolique et par conséquent II) la participation des deux conditions pathologiques au développement de la maladie et/ou à la progression / Cartilage is a unique tissue characterized by abundant extracellular matrix and a single cell type, the chondrocyte. Modifications of chondrocyte phenotype, such as proliferation and hypertrophy, are physiological events occuring during skeletal development and in adult articular cartilage. In growth plate cartilage, the active division and expansion of chondrocytes is the primary mechanism during the process of endochondral bone formation. Chondrocytes play a central role in this process, through a combination of proliferation, extracellular matrix secretion and hypertrophy. The behaviour and cellular features of growth plate chondrocytes are regulated at all stages of endochondral ossification by a complex network of interactions between circulating hormones, locally produced growth factors and the extracellular matrix secreted by the chondrocytes. In articular cartilage, the chondrocytes form morphologically distinct regions, including a superficial region of flattened cells, a sparsely populated middle layer, and a deep zone of hypertrophic chondrocytes. In mature articular cartilage, these chondrocytes maintain the balance of production and degradation of extracellular matrix components. However, pathological alteration of chondrocyte phenotype could lead to numerous human skeletal and articular diseases, including chondrodysplasias and osteoarthritis. In this context, my PhD project was designed to study I) the modifications of chondrocyte phenotypes triggered by genetic determinants and metabolic stress and consequently II) the participation of both pathologic conditions to disease development and/or progression
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Responses of fibroblasts and chondrosarcoma cells to mechanical and chemical stimuliPiltti, Juha January 2017 (has links)
Osteoarthritis is an inflammation-related disease that progressively destroys joint cartilage. This disease causes pain and stiffness of the joints, and at advanced stages, limitations to the movement or bending of injured joints. Therefore, it often restricts daily activities and the ability to work. Currently, there is no cure to prevent its progression, although certain damaged joints, such as fingers, knees and hips, can be treated with joint replacement surgeries. However, joint replacement surgeries of larger joints are very invasive operations and the joint replacements have a limited lifetime. Cell-based therapies could offer a way to treat cartilage injuries before the ultimate damage of osteoarthritis on articular cartilage. The development of novel treatments needs both a good knowledge of articular cartilage biology and tissue engineering methods. This thesis primarily investigates the effects of mechanical cyclic stretching, a 5% low oxygen atmosphere and the Rho-kinase inhibitor, Y-27632, on protein responses in chondrocytic human chondrosarcoma (HCS-2/8) cells. Special focus is placed on Rho-kinase inhibition, relating to its potential to promote and support extracellular matrix production in cultured chondrocytes and its role in fibroblast cells as a part of direct chemical cellular differentiation. The means to enhance the production of cartilage-specific extracellular matrix is needed for cell-based tissue engineering applications, since cultured chondrocytes quickly lose their cartilage-specific phenotype. A mechanical 8% cyclic cell stretching at a 1 Hz frequency was used to model a stretching rhythm similar to walking. The cellular stretching relates to stresses, which are directed to chondrocytes during the mechanical load. The stretch induced changes in proteins related, e.g., to certain cytoskeletal proteins, but also in enzymes associated with protein synthesis, such as eukaryotic elongation factors 1-beta and 1-delta. Hypoxic conditions were used to model the oxygen tension present in healthy cartilage tissue. Long-term hypoxia changed relative amounts in a total of 44 proteins and induced gene expressions of aggrecan and type II collagen, in addition to chondrocyte differentiation markers S100A1 and S100B. A short-term inhibition of Rho-kinase failed to induce extracellular matrix production in fibroblasts or in HCS-2/8 cells, while its long-term exposure increased the expressions of chondrocyte-specific genes and differentiation markers, and also promoted the synthesis of sulfated glycosaminoglycans by chondrocytic cells. Interestingly, Rho kinase inhibition under hypoxic conditions produced a more effective increase in chondrocyte-specific gene expression and synthesis of extracellular matrix components by HCS-2/8 cells. The treatment induced changes in the synthesis of 101 proteins and ELISA analysis revealed a sixfold higher secretion of type II collagen compared to control cells. The secretion of sulfated glycosaminoglycans was simultaneously increased by 65.8%. Thus, Rho-kinase inhibition at low oxygen tension can be regarded as a potential way to enhance extracellular matrix production and maintain a chondrocyte phenotype in cell-based tissue engineering applications.
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