Global ETD Search

481	Role of Phospholipase D in Vascular Calcification / Le rôle de la phospholipase D dans la calcification vasculaire Skafi, Najwa 20 December 2017 (has links) La calcification vasculaire est l’accumulation de cristaux de calcium dans les vaisseaux sanguins à travers un processus pathologique qui ressemble à la formation de l’os ou du cartilage. Elle apparaît notamment chez les patients diabétiques ou atteints d’une insuffisance rénale chronique. La conséquence principale de la calcification vasculaire est la perte de l’élasticité qui est indispensable pour la fonction des larges artères, elle est de plus associée à la mortalité des patients hémodialysés. Les traitements contre la calcification vasculaire sont généralement limités à ceux qui corrigent les facteurs causatifs des problèmes de santé mais aucune intervention efficace, spécifique et ciblée n’est disponible. Par conséquence, une compréhension profonde des mécanismes moléculaires impliqués dans la calcification vasculaire est nécessaire dans le but de trouver de nouvelles cibles thérapeutiques. La phospholipase D catalyse l’hydrolyse des phospholipides en acide phosphatidique et une tête polaire, elle est aussi impliquée dans différentes fonctions cellulaires et maladies. Il a été démontré qu’elle peut être activée par des facteurs impliqués dans l’ostéogenèse et par d’autres impliqués dans la calcification vasculaire. Ainsi, nous avons étudié le rôle de la phospholipase D dans la calcification vasculaire dans 3 modèles différents. Le premier est un modèle in-vitro de cellules musculaires lisses murines (lignée cellulaire MOVAS), elles sont cultivées en présence d’acide ascorbique et de β-glycérophosphate. Le deuxième est un modèle ex-vivo d’explants d’aortes cultivés en présence de fortes concentrations de phosphate et le troisième est un modèle in-vivo d’insuffisance rénale chronique produite chez des rats. Dans ce dernier modèle, la calcification vasculaire est induite par un régime riche en phosphore et en calcium et par des injections de vitamine D active. La calcification dans ces trois modèles a été suivie par l’analyse de la minéralisation en dosant les dépôts de calcium, de l’activité phosphatase alcaline, et de l’expression de différents marqueurs ostéo-chondrocytaires. Une augmentation de l’expression génique de Pld1 a été observée dans les trois modèles, en particulier au cours des premières étapes de la calcification, et a été accompagnée d'une activité accrue de la phospholipase D dans les modèles in vitro et ex-vivo. L’inhibition de l’activité phospholipase D dans ces deux modèles ou de la phospholipase D1 dans le modèle MOVAS a bloqué complètement la calcification. Par contre, l’inhibition spécifique de la phospholipase D2 n’a pas montré des effets significatifs. Deux voies par lesquelles la phospholipase D peut être activée ont été testées, la voie de la protéine kinase C et la voie de la sphingosine-1-phosphate. Ces deux voies métaboliques se sont révélées être impliquées dans le processus de calcification mais pas forcément dans l’activation de la phospholipase D au cours de ce processus. Des résultats préliminaires ont montré que la phospholipase D pourrait agir après activation de la sphingosine kinase 2 dont l’activité s’est avérée nécessaire pour la calcification dans le modèle MOVAS. Des études supplémentaires sont nécessaires pour comprendre par quels mécanismes la phospholipase D est activée et comment elle agit. La phospholipase D pourrait être une nouvelle cible thérapeutique pour le traitement de la calcification vasculaire vu que son inhibition ne semble pas avoir des effets secondaires chez les patients / Vascular calcification is the accumulation of calcium phosphate crystals in blood vessels via a pathological process that resembles physiological bone or cartilage formation. Calcification in the medial layer is mainly seen in diabetic and chronic kidney disease patients. Its main consequence is the loss of elasticity which is indispensable for the function of large arteries. Accordingly, vascular medial calcification was significantly associated with mortality in hemodialysis patients. Vascular calcification treatments are limited to those that correct its causative health problems, but no efficient, specific and targeted interventions are available. Therefore, a deep understanding of its molecular mechanisms is needed to find novel therapeutic targets. Phospholipase D catalyses the hydrolysis of phospholipids into phosphatidic acid and a head group. It is implicated in different cellular functions and diseases. It was found to be activated by factors involved in osteogenesis and others involved in vascular calcification. Thus, we investigated its role in vascular calcification in 3 models: an in-vitro model of murine smooth muscle cell line MOVAS cultured with ascorbic acid and β-glycerophosphate, an ex-vivo model of rat aortas cultured in high phosphate medium, and an in-vivo model of adenine-induced kidney disease in rats in which vascular calcification is induced by further administration of high phosphorus/calcium diet and active vitamin D injections. Calcification was detected in these models using different approaches including alkaline phosphatase activity, calcium dosage, and/or evaluation of osteo-chondrocytic markers expression. Pld1 expression was seen upregulated in all the three models, especially during early stages of calcification, and was accompanied with increased phospholipase D activity in the in-vitro and ex-vivo model. The inhibition of total phospholipase D activity in these two models, or that of phospholipase D1 in case of MOVAS model, abolished calcification. Phospholipase D2-specific inhibition did not induce significant effects. Two pathways by which phospholipase D can be activated were tested, protein kinase C and sphingosine 1-phosphate pathways, but they were found to be involved in calcification but not necessary for phospholipase D activation during this process. Alternatively, the preliminary results showed that PLD may be acting by activation of sphingosine kinase 2 whose activity was found necessary for calcification in the MOVAS model. Further investigations are needed to understand the mechanisms by which phospholipase D is activated and by which it is acting. Phospholipase D could be a novel target for vascular calcification especially that its inhibition in patients did not induce adverse health effects Phospholipase D Calcification vasculaire Phosphatase alcaline Cellules musculaires lisses Insuffisance rénale chronique Aorte Phospholipase D Vascular calcification Alkaline phosphatase Smooth muscle cells Chronic kidney disease Aorta 571.6
482	The role of PPAR-α ligands (fibrates) in the regulation of vascular smooth muscle proteoglycan synthesis and structure as a contributor to reduced lipoprotein binding and the development of atherosclerosis Nigro, Julie January 2004 (has links) Abstract not available Atherosclerosis -- Pathogenesis Atherosclerosis -- Pathophysiology Extracellular matrix Vascular smooth muscle Proteoglycans Proteoglycans -- Synthesis Glycosaminoglycans Fenofibrate Low density lipoproteins
483	The origin and early development of the intrinsic innervation in the foetal mouse lung Tollet, Cecilia Jenny January 2003 (has links) In this study, the origin and development of the intrinsic innervation in the foetal mouse lung is described and experimental evidence is provided to support the involvement of glial cell line-derived neurotrophic factor (GDNF) in the guidance of nerves and neuronal precursors in the developing lung. Antibodies were used to stain for neuronal precursors, neurones, nerve fibres, primordial epithelium and smooth muscle. These structures were revealed in whole mounts of foetal mouse lungs by immunofluorescence and confocal microscopy, and their spatial and temporal distribution was mapped from the onset of lung development and through the pseudoglandular period. The results showed that neuronal precursors, positive for neural crest cell markers, were present in the vagal tract of the foregut at embryonic day 10 (E10), the time of the evagination of the lung buds. These neural crest-derived cells (NCC) migrated into the lung at E11, along nerve processes directed from the vagus to the smooth musclecovered trachea and emerging lobar bronchi. During E11-E14, a network of nerves and ganglia became established along the dorsal trachea, and large ganglia formed a plexus at the ventral hilum. Nerve trunks issued from these ganglia, travelled along the smooth muscle-covered bronchi, providing a pathway for migrating NCC. To investigate the role of GDNF in the innervation of the lung, an in vitro model of left lung lobes was established. Lung growth and tubule branching was comparable to that in vivo, and neural tissue and smooth muscle continued to grow and thrive. A significant increase in nerve growth occurred when explants were cultured with GDNF compared to controls. Nerves extended, and NCC migrated towards GDNF-impregnated beads suggesting that GDNF may be the molecule guiding nerve fibres and NCC in the lung. The migrating NCC were negative for GDNF-family receptor α1 (GFRα1) during their migration into the lung while the nerves were positive. Since GDNF needs to be associated with its binding receptor, GFRα1, for cellular signalling, GDNF may induce the migration of the NCC if they migrate along the GFRα1-positive nerve fibres. It is concluded that neural tissue and smooth muscle become integral components of the lung shortly after the onset of lung development. The results show that the migration of neural crest-derived cells into the lung and the establishment of the innervation requires coordinated cross-talk between NCC, nerves and smooth muscle throughout development. Lungs -- Innervation Fetal nerve tissue Mice -- Nervous system Confocal microscopy Organ culture Lung development Foetal mouse Neural crest cells Neural development Airway smooth muscle GDNF
484	CXCL16 and CD137 in Atherosclerosis Wågsäter, Dick January 2005 (has links) <p>Atherosclerosis is a progressive inflammatory disease that is characterized by the accumulation of lipids, infiltrated cells and fibrous elements in large arteries.</p><p>This thesis focuses on the molecular mechanisms behind foam cell formation and inflammation, two central processes in the development of atherosclerosis. More specific, we studied the effects of proinflammatory cytokines on CXCL16 expression and its role as scavenger receptor on macrophages and smooth muscle cells in atherogenesis. CXCL16 is defined as a chemokine and a scavenger receptor, regulating adhesion and chemoattraction of CXCR6 expressing cells and uptake of oxLDL. We show that the expression of CXCL16 and its receptor CXCR6 are more pronounced in human atherosclerotic lesions compared with non-atherosclerotic vessels. Increased expression of CXCL16 was also seen in atherosclerotic aortas of apoE-/- mice compared with aortas of non-atherosclerotic, age-matched C57BL/6 mice. In vitro, IFN gamma induced CXCL16 expression in primary human monocytes and smooth muscle cells which resulted in an increased uptake of oxLDL. Treatment of mice with IFN gamma also induced CXCL16 expression in atherosclerotic lesions. Thus, we have demonstrated a role for IFN gamma in foam cell formation through upregulation of CXCL16. The expression of CXCR6 was defined to the same regions as for CXCL16 in the lesion, indicating the presence of cells able to respond to CXCL16. Consequently, CXCL16 could serve as a molecular link between lipid metabolism and immune activity in atherosclerotic lesion.</p><p>CD137 belongs to the TNF family and mediates several important processes in inflammation. CD137 is involved in the activation of T cells, NK cells, B cells and monocytes and regulate cytokine production, proliferation and apoptosis in these cells. A limited number of studies have demonstrated CD137 expression on smooth muscle cells and endothelial cells. Our results show that CD137 mRNA is higher expressed in human atherosclerotic lesions compared with unaffected vessels. We found that endothelial cells express CD137 in atherosclerotic lesions and that cultured endothelial cells and smooth muscle cells express CD137 and CD137 ligand in vitro. CD137 was regulated differentially by proinflammatory cytokines (i.e. IFN gamma, TNF alpha, IL-1 beta) and bacterial lipopolysaccharide depending on cell type. Furthermore, we investigated the effects of CD137 signalling, demonstrating that binding of the CD137 ligand to its receptor increases proliferation and migration of smooth muscle cells.</p><p>In summary, this thesis has focused on the expression, regulation and role of CXCL16 and CD137, two genes that have not been described earlier in the concept of atherosclerosis. The findings demonstrate some of the molecular mechanisms involved in vascular inflammation and may increase our knowledge about the development of atherosclerosis.</p> Medicine atherosclerosis chemokine cytokine endothelial cells inflammation low-density lipoprotein macrophages scavenger receptor smooth muscle cells Medicin
485	Myoplasmic calcium regulation and the function of nucleotide and endothelin receptors in models of coronary artery disease Hill, Brent J. F. January 2000 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 2000. / Typescript. Vita. Includes bibliographical references (leaves 186-210). Also available on the Internet.
486	Role of the CD40 receptor/CD154 ligand dyad in the control of smooth muscle cells phenotype / Rolle der CD40/CD154-Dyade bei der Phänotypregulation glatter Gefäßmuskelzellen Stojakovic, Milica 06 November 2003 (has links) No description available. Mathematics and Computer Science CD40 CD154 glatten Gefäßmuskelzellen microarray 570 Biowissenschaften Biologie CD40 CD154 smooth muscle cells microarray 42.15
487	Transcriptional regulation of the Human Zfm1/Sf1 Gene / Transkriptionelle Regulation des humanen Zfm1/ Sf1-Gens Nogoy, Nicole Alberta 05 July 2006 (has links) No description available. 570 Biowissenschaften, Biologie Medicine Gefäßmuskelzellen Proliferation Zfm1 Sp1 Egr1 arteriorsklerose Zfm1/Sf1 atheroscleoris smooth muscle cells proliferation Sp1 Egr1 42 Biologie
488	Remodelage du muscle lisse péribronchique dans l’inflammation respiratoire chronique Leclère, Mathilde 12 1900 (has links) Le souffle chez les chevaux et l’asthme chez l’humain sont des maladies respiratoires qui partagent plusieurs caractéristiques, notamment des épisodes de bronchospasme et de détresse respiratoire dus à une inflammation pulmonaire inappropriée en réponse à une inhalation de substances antigéniques. Les manifestations cliniques incluent des efforts respiratoires augmentés, des sifflements et de la toux. Au niveau des voies respiratoires, on observe une augmentation du muscle lisse péribronchique, une fibrose sous épithéliale, une métaplasie/hyperplasie épithéliale et du mucus en quantité augmentée. L’augmentation du muscle lisse est particulièrement importante car elle n’affecte pas seulement le calibre basal des voies respiratoires, mais elle accentue l’obstruction respiratoire lors de bronchoconstriction. Ces changements sont regroupés sous le terme de « remodelage » et sont associés à un déclin accéléré de la fonction respiratoire chez les patients asthmatiques. Alors que les traitements actuels contrôlent efficacement le bronchospasme et relativement bien l’inflammation, leurs effets sur le remodelage sont mal connus. Dans le cadre de thèse, la réversibilité du remodelage musculaire péribronchique a été investiguée chez des chevaux atteints du souffle dans deux études longitudinales. Ces études, faites principalement sur du tissu pulmonaire prélevé par thoracoscopie, sont difficilement réalisables chez l’humain pour des raisons éthiques, ou chez d’autres animaux, car ceux-ci présentent rarement une inflammation de type asthmatique de façon spontanée. Les résultats démontrent que les chevaux atteints du souffle ont approximativement deux fois plus de muscle péribronchique que les chevaux sains d’âge similaire gardés dans les mêmes conditions, et que la prolifération des myocytes contribue à cette augmentation. Ils démontrent aussi qu’une stimulation antigénique relativement brève chez des chevaux atteints du souffle depuis plusieurs années n’accentue pas le remodelage, ce qui suggère que l’augmentation du muscle lisse atteint un plateau. Nous avons également montré que le remodelage du muscle lisse chez des chevaux adultes est partiellement réversible et que cette réversibilité peut être accélérée par l’administration de corticostéroïdes par inhalation. Il semble toutefois qu’une portion du remodelage chronique est irréversible puisque les corticostéroïdes ont accéléré la diminution du muscle mais sans toutefois mener à une amélioration plus marquée au terme de l’étude qu’avec une modification environnementale stricte. La diminution de trente pourcent observée sur un an paraît modeste mais elle démontre clairement, et pour une première fois, que le remodelage du muscle lisse présent chez des chevaux adultes malades depuis plusieurs années est au moins partiellement réversible. / Equine heaves and asthma in people are two respiratory diseases that share many characteristics, including episodes of bronchospasm and respiratory distress due to an inappropriate airway inflammation in response to inhaled antigens. In both diseases, the main clinical manifestations are increased breathing efforts, wheezing and coughing. Changes in the airway wall include increased airway smooth muscle, subepithelial fibrosis, epithelial changes, and increased mucus. The increase in smooth muscle is of particular importance as it not only affects baseline airway caliber, but also accentuates the effect of bronchoconstriction on airflow limitation. These structural changes are grouped under the term “remodeling” and are associated with the accelerated decline of respiratory function in asthmatics. While current treatments offer adequate control of bronchospasm and inflammation, their effects on remodeling are unknown. In this thesis, airway smooth muscle remodeling reversibility was investigated in heaves-affected horses. The longitudinal studies conducted here, mostly made on peripheral pulmonary tissue harvested under thoracoscopic guidance, can not be easily done in people for ethical reasons, or in other animal species, few of them having spontaneous asthma-like disease like horses. Results have shown that heaves-affected horses have twice as much airway smooth muscle than age-matched controls kept in the same environment, and that myocyte proliferation contributes to this increase. It was also shown that a relatively brief antigenic exposure in chronically affected horses does not further increase smooth muscle mass, which suggests that it may reach a plateau over time. It was also shown that airway smooth muscle is partially reversible and that this reversibility can be accelerated with inhaled corticosteroids. On the other hand, corticosteroids only accelerated the decrease in mass compared to strict environmental control, without affecting the total improvement observed at the end of the study, which suggests that some of this chronic remodeling is irreversible. The thirty percent decrease seems relatively modest but it is nevertheless the first demonstration that airway smooth muscle remodeling of adult horses affected by heaves for years is at least in part reversible. souffle asthme remodelage muscle lisse péribronchique corticostéroïdes heaves asthma remodeling airway smooth muscle corticosteroids
489	The Role of Chloride Channels in Regulation of Pulmonary Artery Smooth Muscle Cell Proliferation Liang, Wenbin 19 November 2013 (has links) Pulmonary arterial hypertension (PAH) is a rare but fatal disease with an annual mortality rate of 15% despite current therapies. Uncontrolled proliferation of pulmonary artery smooth muscle cells (PASMCs) results in adverse vascular remodeling contributing to PAH. Understanding the mechanisms of PASMC proliferation may identify new targets for treatment. Chloride currents/channels (ICl) are expressed in PASMCs and their roles in proliferation have been suggested based on their importance in resting membrane potential and cell volume regulation. The present study explored the role of ICl in proliferation in rat and human PASMCs. We found that either nonspecific ICl inhibitors (DIDS or NPPB) or a putative specific blocker of swelling-activated ICl (ICl,swell) reduced proliferation of PASMCs cultured in serum-containing media. Patch-clamp studies showed that proliferating PASMCs had increased baseline ICl and ICl,swell in association with depolarized membrane potentials. Quantitative real-time RT-PCR studies identified expressions of CLC-3, a candidate gene of ICl,swell, and several other CLC genes in proliferating PASMCs. While selective knockdown of CLC-3 with lentiviral shRNA reduced PASMC proliferation, it had no effect on ICl,swell. These findings are consistent with the conclusion that ICl regulate proliferation of PASMCs and suggest that selective ICl inhibition may be useful in treating pulmonary arterial hypertension. Pulmonary arterial hypertension Pulmonary artery smooth muscle cell Proliferation Chloride channel Cell volume Membrane potential RNA interference Lentivirus CLC channels CLC-3 DIDS DCPIB 0719
490	Assessing the Activity of Agonistic Autoantibodies in Systemic Sclerosis and their Effects on Cultured Vascular Smooth Muscle Cells Chokr, Nidaa 05 1900 (has links) La sclérose systémique (ScS) est une maladie auto-immune dévastatrice d'étiologie inconnue. Le dysfonctionnement immunitaire, la fibrose et la vasculopathie sont les trois principales caractéristiques de cette maladie. Une récente étude a révélé un nouveau lien entre l'auto-immunité et la fibrose, par la présence d'auto-anticorps stimulant le récepteur du facteur de croissance dérivé des plaquettes (PDGFR) des fibroblastes. Ces auto-anticorps sont capables de stimuler les espèces réactives de l'oxygène et d’activer la kinase régulée par un signal extracellulaire (ERK1/2). L’hypothèse que nous formulons est que les cellules musculaires lisses vasculaires (VSMCs) exprimant conjointement les PDGFR, répondront elles aussi aux autoanticorps anti-PDGF-R. Le travail présenté ici vise à valider la présence d'auto-anticorps PDGFR dans les sérums de patients ScS, et à caractériser ensuite la réponse de VSMCs exposées à de l'immunoglobuline G (IgG) de ces sérums, en mesurant l’activation des cascades de signalisation spécifiques, ainsi que l'induction des gènes impliqués dans la réponse fibrotique. Nos résultats démontrent la présence d'une fraction IgG stimulant une réponse phénotypique dans les cultures de VSMCs. Notamment, d’importantes régulations positive et négative des gènes pro-fibrotiques tgfb1 et tgfb2 respectivement, ont été observées dans les VSMCs exposées à des fractions de ScS-IgG. Les fractions de IgG positives pour l'activation de ERK étaient présentes dans la plupart, mais pas dans tous les échantillons de SSc (68%, 19/28), et moins présentes dans les contrôles 27% (11/3). Bien que, les fractions de SSc-IgG ont pu considérablement immunoprécipiter le PDGFR, l'utilisation d'un inhibiteur spécifique des récepteurs au PDGF (AG1296), n'a pas inhibé l'activation de ERK médiée par les fractions de SSc-IgG. Globalement, nos résultats indiquent la présence d'autoanticorps stimulants avec activité pro-fibrotique dans les sérums des patients ScS. Des travaux sont en cours pour identifier l'entité moléculaire responsable de la réponse d’IgG observée dans les cultures de VSMCs. / Systemic Sclerosis (SSc) is a devastating autoimmune disease of unknown etiology. Immune dysfunction, fibrosis and vasculopathy are the three major features of the disease; however, the interactions between these components are poorly understood. A novel link between autoimmunity and fibrosis has been proposed by the presence of stimulatory autoantibodies to the platelet-derived growth factor receptor (PDGFR) on fibroblasts. These autoantibodies were capable of stimulating reactive oxygen species and subsequent activation of ERK1/2. If the anti-PDGFR autoantibodies are present in the systemic circulation of SSc patients, they will most certainly encounter vascular smooth muscle cells (VSMCs). The latter are known to express the PDGFR and response to PDGF, which is a known phenotypic modulator of VSMCs. The work presented here seeks to readdress the presence of stimulatory anti-PDGFR autoantibodies in serum derived from SSc-patients and to characterize the effects of SSc-IgG on VSMCs by measuring the activation of specific signaling cascades and the induction of genes involved in fibrotic responses. Our results demonstrate the presence of an IgG fraction stimulating a phenotypic response in cultured VSMCs. Notably, a significant up-regulation of the pro-fibrotic gene tgfb1 and a significant down-regulation of the anti-fibrotic gene tgfb2 were observed in VSMC exposed to SSc-IgG fractions. Positive IgG fractions for ERK activation were present in most, but not all, SSc samples (68%, 19/28), and they were less present in controls (27%) (3/11). Although, the SSc-IgG fractions were able to significantly immunoprecipitate the PDGFR, the use of a selective PDGFR inhibitor, AG1296, did not inhibit the activation of ERK mediated by SSc-IgG fractions. Altogether, our findings suggest the presence of stimulatory autoantibodies with profibrotic activity in serum derived form SSc patients. Work is in progress to identify the molecular entity responsible for the IgG response observed in cultured VSMCs. Sclérose systémique CMLV PDGFR auto-anticorps Systemic Sclerosis vascular smooth muscle cells PDGFR autoantibodies

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