Global ETD Search

41	Paracrine factors and regulation of regional kidney perfusion Rajapakse, Niwanthi W. January 2004 (has links) Abstract not available Paracrine mechanisms Isolation perfusion (Physiology) Regional blood flow Blood pressure -- Regulation Kidneys -- Blood-vessels Kidneys -- Physiology Vasoconstrictors Nitric oxide -- Physiological effect Angiotensin II -- Physiological effect Cytochrome P-450 -- Physiological effect Cyclooxygenases -- Physiological effect Prostaglandins -- Physiological effect
42	Activité calcique et communication paracrine avant synaptogenèse dans le développement du néocortex murin Platel, Jean-Claude 28 October 2005 (has links) (PDF) Dans le néocortex murin, la division des cellules précurseurs a lieu dès le stade E11 et donne naissance aux premiers neurones pionniers dont les cellules de Cajal-Retzius. L'activité électrique spontanée, portée par les canaux ioniques, joue un rôle prépondérant dans le développement du système nerveux central. Comprendre la place des canaux ioniques et de la signalisation calcique dans les phases précoces de le neurogenèse était l'objectif principal de mon projet. Nous avons montré l'apparition précoce de canaux sodiques dépendants du voltage dans 55% des cellules neuronales à E13, dont les cellules de Cajal-Retzius. En parallèle, nous avons observé des activités calciques spontanées dans les cellules proliférantes et neuronales au même stade. La conception d'un logiciel d'imagerie nous a permis d'analyser statistiquement ces activités et d'identifier les canaux ioniques impliqués. Alors que les synapses ne sont pas encore formées, nous avons observé la mise en place d'activités synchrones au sein du néocortex et démontré l'existence de communications paracrines entre les cellules. De plus, nous avons identifié l'existence d'une cascade de signalisation où la dépolarisation des récepteurs glycinergiques active les canaux sodiques présents sur les neurones pionniers. Dans ces neurones, l'influx sodique entraîne une augmentation de calcium cytoplasmique via un échangeur Na+/Ca2+ puis une exocytose glutamatergique dont le libération paracrine induit l'activation d'autres cellules néocorticales. L'utilisation de la culture organotypique de cerveau nous a laissé entrevoir une implication physiologique majeure de cette cascade de signalisation dans la corticogenèse. activité spontanée cellules de Cajal-Retzius communication paracrine courants sodiques échangeur Na+/Ca2+ glutamate imagerie calcique néocortex patch-clamp préplaque reeline réseau neuronal RT-PCR sur cellule unique
43	Novel Therapeutic Strategies for the Treatment of Pulmonary Arterial Hypertension Suen, Colin January 2017 (has links) Pulmonary arterial hypertension (PAH) is a progressive disease that results in increased pulmonary vasculature resistance, causing right ventricular (RV) remodeling, which eventually progresses into right heart failure and mortality. New and emerging therapeutic strategies involve regenerative approaches to repair the underlying vascular pathology using regenerative cell therapy and methods to alleviate RV dysfunction in the setting of fixed RV afterload. In the first section of the thesis, we investigated the role of EPC paracrine mechanisms in the treatment of PAH. We characterized the paracrine function of EPCs by demonstrating that EPC conditioned medium enhances endothelial cell migration, survival and angiogenesis in vitro. We further examined the role of secreted extracellular vesicles in the paracrine function of EPCs, which played a minor role in promoting wound healing. However, using the monocrotaline rat model of PAH, we did not demonstrate a consistent benefit on RV pressures or remodeling with EPCs or EPC conditioned medium. The lack of effect may be related to the advanced phenotype observed in our model of PAH. Survival in severe pulmonary arterial hypertension (PAH) is related to the ability of the right ventricle (RV) to adapt to increased afterload. Therefore, we explored the effect of genetic background on right ventricular adaptation and survival in a rat model of severe (PAH). Compared to the conventional Sprague-Dawley rat strain, we observed high mortality in the Fischer SUHx model of severe PAH. This was related to a strain-dependent failure of RV adaptation, as evidenced by RV dilatation, RV contractile dysfunction, decreased cardiac ouptut and decreased exercise capacity. Further analysis by gene expression microarrays and fluorescence microangiography demonstrate that failure of RV adaptation is due at least in part due to lack of adequate microvascular angiogenesis in the hypertrophied RV. This work lays the foundation for the section on RV-specific therapy that follows. Using the Fischer model of maladaptive RV remodeling, we tested whether cardiotrophin-1 (CT-1), a pro-angiogenic and cardioprotective cytokine, could improve RV adaptation. We demonstrated that as a rescue treatment, CT-1 reduced RV dilatation and function without influencing RV afterload, which suggests improved RV adaptation. These changes were associated with an increase in RV capillary density. As an early-stage preventative treatment, in addition to improving RV remodeling, CT-1 also reduced pulmonary pressures. These hemodynamic changes suggest that CT-1 may also have a direct impact on vascular tone or the underlying pulmonary vascular pathology. Pulmonary hypertension Pulmonary arterial hypertension Stem cell Right ventricle Endothelial progenitor cell Endothelium Heart failure Sprague dawley rat Fischer rat Exosome Microvesicle Extracellular vesicles SU5416 Paracrine Angiogenesis SUHx Cardiotrophin CT-1
44	Thérapie cellulaire pour le glaucome : régénération tissulaire grâce aux cellules souches mésenchymateuses Manuguerra-Gagné, Renaud 03 1900 (has links) Les cellules souches ont été présentées comme la clé d’une médecine régénératrice, où la réparation d’un organe, la guérison de maladies dégénératives et la création de nouveaux tissus seraient des objectifs réalisables à court ou moyen terme. Les cellules souches isolées chez un adulte ont un certain degré de spécialisation limitant leur potentiel à leur organe d’origine. Mais l’une d’elles, la cellule souche mésenchymateuse (MSC), possède une versatilité qui en fait une candidate idéale pour plusieurs traitements. Il est communément accepté que les MSC exercent leur effet grâce à la production de facteurs solubles. Toutefois, leur mécanisme d’action reste jusqu’à maintenant imprécis. Ces facteurs ayant le potentiel d’agir dans plusieurs maladies dégénératives, nous avons voulu évaluer leur effet régénératif dans l’une des maladies oculaires les plus répandues, le glaucome à angle ouvert. Cette maladie est caractérisée par une destruction des cellules ganglionnaires de la rétine suite à une élévation de la pression intraoculaire. Cette hausse de pression est souvent engendrée par une dysfonction du trabéculum, le tissu régulant la sortie de l’humeur aqueuse de l’œil. Actuellement, la progression du glaucome peut être contrôlée, mais la maladie ne peut pas être guérie. Or la régénération du trabéculum pourrait arrêter la progression de la maladie et même renverser le processus. Ainsi, l’objectif de cette thèse était de vérifier si les MSC ont le potentiel de favoriser la régénération oculaire dans des cas de glaucome et de comprendre les mécanismes sous-jacents. Pour ce faire, nous avons injecté des MSC ou leurs facteurs sécrétés dans un modèle de glaucome induit par trabéculoplastie laser. Nous avons démontré que les MSC peuvent régénérer le trabéculum endommagé et abaisser la pression oculaire en réactivant des cellules progénitrices dans le corps ciliaire. Ces cellules prolifèrent et s’implantent dans le trabéculum une semaine après le traitement. Nous avons aussi démontré que les facteurs produits par les MSC cultivées en conditions hypoxiques induisent l’activation des cellules progénitrices. Par contre, les MSC cultivées dans un environnement normoxique n’induisent pas cet effet. Nous avons aussi observé que les facteurs produits dans des conditions hypoxiques sont incapables de réactiver les cellules progénitrices ex vivo. Nous avons donc voulu vérifier si d’autres facteurs régénératifs sont engendrés in situ suite à l’injection des MSC. Nous avons ainsi découvert qu’un facteur produit par les macrophages migrant dans la zone endommagée permet de réguler l’activation des cellules progénitrices. Cette production requiert cependant une exposition des macrophages aux facteurs paracrines des MSC. Nous avons aussi observé que l’effet régénératif des MSC était inhibé suite à l’élimination des macrophages de l’organisme. Ceci positionne les macrophages comme un intermédiaire essentiel de l’effet régénératif exercé par les MSC. Les résultats présentés dans cette thèse constituent une avancée importante pour l’utilisation des MSC en médecine régénératrice. Ils ont permis d’établir les bases d’un traitement potentiel pour le glaucome à angle ouvert et d’ajouter une pièce importante à la compréhension des mécanismes régénératifs des MSC. Ces connaissances devraient avoir un impact significatif sur la régénération du tissu oculaire et de plusieurs autres organes. / Stem cells have been presented as the key to regenerative medicine, where organ repair, cures for degenerative diseases and even the creation of new tissue could be achieved. Adult stem cells already possess a certain level of differentiation, which limits their potential effect to the organ where they were isolated. But one subtype, mesenchymal stem cells (MSC), possess a versatility which makes them ideal candidates for many treatments. It is commonly accepted that MSCs exert their effect through paracrine factors, but their precise mechanism of action remains uncertain. As such factors could have a positive effect in many degenerative diseases, we wanted to study their regenerative potential in one of the most widespread ocular disease, open angle glaucoma. This disease is characterised by the destruction of retinal ganglion cells following a rise in intraocular pressure. This pressure rise is mostly caused by a dysfunction of the trabecular meshwork, the tissue regulating the outflow of aqueous humor from the eye. Glaucoma progression can currently be controlled, but the disease cannot be cured. Meanwhile, trabecular regeneration could halt and even reverse disease progression. Thus, the objective of this thesis is to evaluate MSC potential in the regeneration of the trabecular meshwork and to understand any underlying mechanisms. To this end, we injected MSC or their secreted factors in a model of trabeculoplasty induced glaucoma. We demonstrated that MSC can regenerate the damaged trabeculum and lower ocular pressure by reactivating progenitor cells located in the ciliary body. These cells proliferate and restore the trabeculum within one week after the initial treatment. We also demonstrated that MSC factors produced under hypoxic conditions induce progenitor cell activation. Such activation does not occur with MSC factors produced under normoxic conditions. We have also observed that factors produced under hypoxic conditions are incapable of reactivating progenitor cells in an ex vivo setting. Thus, we wanted to verify if any other regenerative factors are produced in vivo after MSC injection. We have discovered that macrophages produce one such factor after their migration in the area of damage. Production of the macrophage factor requires contact with MSC paracrine factors. We have also observed that MSC regeneration was completely blocked following macrophage elimination from the organism. This positions macrophages as an essential intermediate in MSC-mediated tissue regeneration. The results presented in this thesis represent an important step forward for the use of MSC in regenerative medicine. They have established a basis for an open angle glaucoma treatment and added an important element for the comprehension of MSC regenerative mechanisms. This knowledge should have a significant impact for the treatment of ocular diseases and other illnesses in many different organs. Cellules souches mésenchymateuses Glaucome à angle ouvert régénération oculaire trabéculum macrophages facteurs paracrines Mesenchymal stem cells Open angle glaucoma ocular regeneration trabeculum paracrine factors macrophages
45	Engineering the Micro-Environment Niche of Human Bone Marrow-Derived Mesenchymal Stem Cells for Enhanced Cardiac Tissue Regeneration Joshi, Jyotsna 05 December 2018 (has links) No description available. Biomedical Engineering Myocardial infarction MSC spheroids 5-azacytidine Collagen hydrogels Collagen nanofibers Wnt signaling MSC paracrine signaling TNF-alpha Human cardiomyocytes Cocultures of MSC and cardiomyocytes
46	Development of a Microfluidic Platform for Cell-Cell Communication Watson, Craig 23 May 2022 (has links) No description available. Biomedical Engineering Electrical Engineering Computer Engineering Microfluidics cell culture co-culture coculture paracrine signaling multiplexing PDMS soft lithography photolithography computational modeling open source open hardware instrumentation automation Qt Arduino
47	An IL-4-dependent macrophage-iNKT cell circuit resolves sterile inflammation and is defective in mice with chronic granulomatous disease Zeng, Melody Yue 03 February 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The immune system initiates tissue repair following injury. In response to sterile tissue injury, neutrophils infiltrate the tissue to remove tissue debris and subsequently undergo apoptosis. Proper clearance of apoptotic neutrophils in the tissue by recruited macrophages, in a process termed efferocytosis, is critical to facilitate the resolution of inflammation and tissue repair. However, the events leading to suppression of sterile inflammation following efferocytosis, and the contribution of other innate cell types are not clearly defined in an in vivo setting. Using a sterile mouse peritonitis model, we identified IL-4 production from efferocytosing macrophages in the peritoneum that activate invariant NKT cells to produce cytokines including IL-4 and IL-13. Importantly, IL-4 from macrophages functions in autocrine and paracrine circuits to promote alternative activation of peritoneal exudate macrophages and augment type-2 cytokine production from NKT cells to suppress inflammation. The increased peritonitis in mice deficient in IL-4, NKT cells, or IL-4Ra expression on myeloid cells suggested that each is a key component for resolution of sterile inflammation. The phagocyte NADPH oxidase, a multi-subunit enzyme complex we demonstrated to require a physical interaction between the Rac GTPase and the oxidase subunit gp91phox for generation of reactive oxygen species (ROS), is required for production of ROS within macrophage phagosomes containing ingested apoptotic cells. In mice with X-linked chronic granulomatous disease (X-CGD) that lack gp91phox, efferocytosing macrophages were unable to produce ROS and were defective in activating iNKT during sterile peritonitis, resulting in enhanced and prolonged inflammation. Thus, efferocytosis-induced IL-4 production and activation of IL-4-producing iNKT cells by macrophages are immunomodulatory events in an innate immune circuit required to resolve sterile inflammation and promote tissue repair. Immune system -- Research -- Methodology Tissues -- Research Guanosine triphosphatase Killer cells Neutrophils -- Immunology Inflammation -- Research -- Evaluation Apoptosis Cellular signal transduction -- Research Macrophages -- Activation Phagocytes Autocrine mechanisms Paracrine mechanisms Cytokines Active oxygen -- Physiological effect Mice as laboratory animals -- Research
48	The Hypoxic Regulation and Function of Hypoxiainducible Factor 2α (HIF-2α) In an Adrenomedullary Chromaffin Cell Line Brown, Stephen T. 04 1900 (has links) <p> Exposure to chronic low oxygen (hypoxia) leads to a series of adaptive responses involving changes in gene expression that are critical for cell, tissue, and organismal survival. These changes are mediated by an important set of regulators belonging to the hypoxia inducible factor (HIF) family of transcription factors (e.g. HIF-lα, HIF-2α, HIF3α) which undergo rapid degradation during normal oxygen (normoxia) but are rapidly stabilized during hypoxia. While the role of HIF-1α has been extensively studied in many cell types, there have been relatively few studies on the role of HIF-2α, though recent evidence suggests its function maybe tissue specific. This thesis examined the hypothesis that HIF-2α plays a central role in the development and function of catecholaminergic cells of the sympathoadrenal (SA) lineage. The study was aided by use of an immortalized line of rat adrenomedullary chromaffin cells (i.e. MAH cells), derived from fetal SA progenitors, which express several hypoxia-sensitive properties characteristic of native cells in the adrenal gland. In Chapter 2, I investigated the potential contributions of mitochondrial reactive oxygen species (ROS) and 0 2 consumption to HIF-2α induction in MAH cells exposed to chronic hypoxia (2% O(2); 24 hr). In MAH cells, chronic hypoxia caused an increase in HIF-2α induction which was blocked by inhibition of any of the mitochondrial complexes using pharmacological agents, or by specific inhibition of complexes III and IV using RNAi techniques. It was found that in this 0 2-sensitive chromaffin cell line mitochondrial O(2) consumption, rather than changes in ROS, regulated HIF-2α induction during hypoxia. In Chapter 3, I investigated the hypothesized role of HIF-2α in the development of the catecholaminergic phenotype in cells of the SA lineage using the MAH cell line as a model. Mutant MAH cells, with depleted HIF-2α due to siRNA knock-down, showed dramatically lower levels of dopamine and noradrenaline compared to untransfected and scrambled control cells, regardless of whether the cells were cultured under normoxia or chronic hypoxia. This was correlated with a marked reduction in the expression of DOPA decarboxylase (DDC) and dopamine B hydroxylase (DBH), though the expression of tyrosine hydroxylase (TH) was unaffected. Moreover, HIF-2α was able to bind to a region of the DDC gene promoter which contains two putative hypoxia response elements (HREs). These data suggest that a basal level of HIF-2α function is required for the normal developmental expression of DDC and DBH in SA progenitor cells, and that loss of this function leads to impaired catecholamine (CA) biosynthesis. In Chapter 4, I investigated genes regulated by chronic hypoxia in MAH cells, with a focus on those involved in CA metabolism, storage, and secretion. Using microarray analysis combined with QPCR and RNAi knock-down methodology I uncovered several genes, involved in amine vesicular packaging, trafficking and secretion, which were upregulated during chronic hypoxia. One gene specifically, the adenosine A(2A) receptor (A(2A)R) gene, which appears to modulate CA secretion via autocrine or paracrine actions of extracellular adenosine, was dramatically upregulated in chronic hypoxia. Interestingly, this effect was completely abolished in HIF-2α knockdown MAH cells, suggesting a critical involvement of HIF-2α. Chromatin immunoprecipitation (ChIP) assays revealed that HIF-2α bound to the promoter region of the A(2A)R gene which contains a putative hypoxia response element (HRE) immediately upstream of exon 1. Ratiometric fluorescence measurements of intracellular Ca(2+) revealed that adenosine (50 μM) potentiated the high K(+)-evoked rise in [Ca(2+)]i in MAH cells. This effect of adenosine was further enhanced after chronic hypoxia, but was abolished in HIF-2α knock-down cells. In conclusion, these data suggest that HIF-2α is a key regulator of several genes involved in CA biosynthesis, and of others that mediate the facilitatory effects of chronic hypoxia on CA secretion in sympathoadrenal derivatives. / Thesis / Doctor of Philosophy (PhD) Biology Chronic low Oxygen hypoxia cell tissue organismal survival HIF Hypoxia Inducible Factor transcription factors rapid degradation normal oxygen normoxia SA sympathoadrenal rat adrenomedullary chromaffin cells MAH cells ROS Reactive Oxygen Species mitochondrial pharmacological agents RNAi catecholaminergic phenotype MAH siRNA DOPA DDC decarboxylase dopamine β hydroxylase Adenosine paracrine extracellular adenosine

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