Global ETD Search

31	Mécanismes de l’inflammation hépatique liée à l’obésité / Mechanisms of hepatic inflammation linked to obesity Boujedidi, Hédia 09 December 2011 (has links) Les lésions hépatiques observées au cours de l'obésité (NAFLD, stéatopathie non alcoolique) s'étendent de la stéatose isolée à la stéatohépatite (NASH, stéatohépatitie non alcoolique), la fibrose, la cirrhose et au carcinome hépatocellulaire. L'identification des mécanismes de recrutement des cellules immunitaires par le foie stéatosique est une étape clé dans la compréhension du déclenchement de l'inflammation hépatique et la recherche de nouvelles cibles thérapeutiques. Au cours de l’obésité, la stéatose sensibilise le foie au lipopolysaccharide (LPS), qui active la voie pro-inflammatoire NFκB. Nous avons récemment montré que: 1) la stéatose induisait une augmentation du recrutement lymphocytaire (TCD4+, TCD8+ et B) vers le foie mais également une augmentation de la réponse des lymphocytes TCD4+ à la chimiokine CXCL12 (SDF-1α), dont le récepteur est CXCR4 ; 2) GILZ (Glucocorticoid-Induced Leucine Zipper), une protéine induite par les glucocorticoïdes (GCs), inhibait la voie NFkB et jouait un rôle clé dans l’inflammation hépatique au cours de la consommation excessive d’alcool.Le but de ce travail était d’étudier les mécanismes de l’inflammation hépatique liée à l’obésité. Au cours de mon travail, nous avons montré que le chimiotactisme des lymphocytes TCD4+ à la chimiokine CXCL12 était augmenté non seulement chez les souris obèses mais également chez des patients ayant une NASH. L’augmentation de l’effet chimiotactique de CXCL12 était due à une augmentation de l’affinité de CXCL12 à son récepteur CXCR4. La migration anormale des lymphocytes T CD4+ vers le foie stéatosique était réversible pharmacologiquement en inhibant la liaison de CXCL12 à CXCR4 par AMD3100 (antagoniste deCXCR4). Le déficit d’expression et l’altération de l’induction du facteur anti-inflammatoire GILZ dans les cellules des Kupffer des souris obèses étaient responsables de la sensibilisation de ces cellules au LPS. Cette altération était liée à la diminution de l’expression du récepteur aux glucocorticoïdes (GR) dans les cellules de Kupffer des souris obèses. La surexpression de GILZ dans l’obésité en utilisant des souris trangéniques restaurait la tolérance hépatique au LPS. Ces anomalies des lymphocytes TCD4+ et de l’expression de GILZ dans les cellules de Kupffer participent au déclenchement d’une inflammation hépatique sur un foie stéatosique et pourraient représenter de nouvelles cibles thérapeutiques / Non alcoholic fatty liver disease (NAFLD) includes a spectrum ranging from simple steatosis to nonalcoholic steatohepatitis (NASH), fibrosis, cirrhosis, and hepatocellular carcinoma. The identification of the mechanisms involved in the recruitment of immunity cells by the fatty liver is a key in the comprehension of the onset of liver and the finding of new therapeutic targets. In obesity, steatosis sensitizes the liver to the lipopolysaccharide (LPS) from the gastrointestinal tract and the NFkB pro-inflammatory pathway is activated. We recently showed that: 1) the steatosis led to an increase recruitment of lymphocytes (TCD4+, TCD8+ and B) by the liver but also an hyperresponsive of CD4+T cells to CXCL12 (SDF-1"), the ligand of CXCR4; 2) GILZ(Glucocorticoid-Induced Leucine Zipper), a protein induced by glucocorticoids (GCs), inhibits the nuclear factor kB pathway and plays a key role in alcoholic hepatitis.This aim of my work was to study the mechanisms involved in obesity-related liver inflammation.I demonstrated that the chemotaxis of CD4+T cells to CXCL12 was increased not only in obese mice but also in patients with NASH. This increased chemotactisme of CXCL12 was due to an increase of the affinity ofCXCL12 to its receptor. The abnormal migration of CD4+T lymphocytes to the fatty liver was reversible by pharmacologically inhibiting the binding of CXCL12 to CXCR4 using AMD3100.The decreased expression and the impairment of the induction of the anti-inflammatory factor GILZ in Kupffer cells from obese mice was responsible for a sensitization of these cells to LPS. This impairment was due to a decrease of the glucocorticoid receptor (GR) expression in Kupffer cells from obese mice. The overexpression of GILZ level in obese transgenic mice restored the liver tolerance to LPS. These abnormalities of CD4+T lymphocytes and the GILZ expression in Kupffer cells contribute to the onset of liver inflammation in obesity and may represent new therapeutic targets. Stéatohépatite non alcoolique (NASH) GC GR CXCR4 CXCL12 Nonalcoholic steatohepatitis (NASH) Obesity Hepatic inflammation Kupffer cells LPS GC GR CD4+T lymphocytes, CXCR4 CXCL12
32	Production of prostaglandin E2 and thromboxane A2 by rat liver macrophages and involvement of nitric oxide and cytokines in mediator pathways under inflammatory conditions Bezugla, Yevgeniya 08 January 2008 (has links) The pathogenesis of inflammatory liver diseases and development of liver fibrosis involves hepatocytes as well as non-parenchymal liver cells like resident liver macrophages (Kupffer cells (KC)), Stellate cells and endothelial cells. Kupffer cells play a critical role in liver (patho)physiology and in the defense of the liver during inflammation. They constitute about 50% of non-parenchymal cells and are the largest population of tissues macrophages in the body. Infections, toxins (lipopolysacharide (LPS)), parenchymal damage and stresses stimulate the inflammatory response of Kupffer cells with the following secretion of bioactive factors, cytotoxicity, antigen processing, etc. Resident liver macrophages are the main producers of inflammatory mediators in the liver. Among them there are prostanoids (prostaglandin (PG) E2 and thromboxane (Tx) A2), cytokines (e.g. interleukin (IL)-1,-6, -10, tumor necrosis factor (TNF) α) and inorganic mediators like nitric oxide (NO). Macrophages-derived products play opposing roles in the development of liver fibrogenesis: IL-1β, TNFα, IL-6, transforming growth factor (TGF)-β and TxA2 (pro-fibrogenic mediators) promote whereas PGE2, IL-10 and nitric oxide (anti-fibrogenic mediators) suppress liver fibrogenesis. The present study shows the production of PGE2 and TxA2 by resident liver macrophages upon prolonged activation by LPS and the characterization of biosynthesis pathways. The production of PGE2 and TxA2 is followed during 24 h after stimulation of macrophages with LPS. The involvement of enzymes is measured on the RNA level (RT-PCR), protein level (Western blot analysis) and activity (activity assays), respectively. The amounts of released prostanoids are measured at time points 2, 4, 8 and 24 h after LPS stimulation. The production of PGE2 is very low without stimulation, shows a delay within the first few hours after stimulation with LPS, and thereafter linearly increases up to 24 h. TxA2 production is very low without stimulation, and increases without a time-delay after the addition of LPS. Prostanoid biosynthesis is inhibited by dexamethasone. The present study shows the involvement and regulation of the AA cascade by the following enzymes: cPLA2: is expressed in resting Kupffer cells; cPLA2 expression and phosphorylation is increased by LPS, dexamethasone suppresses the LPS effect, localization in membrane fraction. COX-1: is expressed in resting Kupffer cells; COX-1 expression is not influenced by LPS and dexamethasone. The COX-1 inhibitor SC560 suppresses the LPS-induced production of PGE2 and TxA2 (8h and 24h), localization predominantly in membrane fraction. COX-2: is almost not expressed in resting Kupffer cells; COX-2 expression is highly increased by LPS, dexamethasone suppresses the LPS effect. The COX-2 inhibitor SC236 inhibits the production of PGE2 and TxA2 at 8h by about 77% and 20%, and at 24h by about 42% and 34%, respectively, localization predominantly in membrane fraction. mPGES-1: is almost not expressed in resting cells; mPGES-1 expression is highly increased by LPS, dexamethasone suppresses the LPS effect, localization in membrane fraction. mPGES-2: is expressed in resting Kupffer cells; mPGES-2 expression is slightly increased by LPS, localization predominantly in membrane fraction. cPGES: is expressed in resting Kupffer cells; LPS has no effect, localization predominantly in soluble fraction. TxA2 synthase: is expressed in resting Kupffer cells; LPS and dexamethasone have no effect, localization predominantly in membrane fraction. Treatment of Kupffer cells with IL-1ß and TNF-α leads to an enhanced release of PGE2 and TxA2 and upregulate the expression of cPLA2, COX-2 and mPGES-1. IL-6 has no effect on prostanoid production. In contrast, IL-10 suppresses the LPS-induced production of PGE2 and TxA2 and expression of cPLA2, COX-2 and mPGES-1. Resting Kupffer cells release very low amounts of NO and do not express iNOS, nNOS and eNOS. LPS, TNF-α and IL-1ß upregulate NO release and the expression of iNOS whereas dexamethasone and IL-10 downregulate NO release and the expression of iNOS. PGE2 suppresses the LPS-induced release of NO but enhances the cytokine-induced release of NO. NO induces a release of PGE2. Thus, the study demonstrates a crosstalk between prostanoids, nitric oxide and cytokines in Kupffer cells under inflammatory conditions and demonstrates a possible anti-fibrogenic effect of PGE2 in the process of liver fibrogenesis. info:eu-repo/classification/ddc/540 ddc:540
33	Einfluss von freien Fettsäuren und Triglyceriden auf die Expression von proinflammatorischen Mediatoren und Adhäsionsmolekülen in Hepatozyten und Kupffer-Zellen (der Ratte) / Effect of free fatty acids and triglycerides on the expression of proinflammatory mediators and adhesion molecules in hepatocytes and Kupffer cells (of the rat) Demuth, Julia Elisabeth 01 December 2009 (has links) No description available. 610 Medizin, Gesundheit Medicine Julia Demuth NASH Fettleber Steatosis Hepatis Leberentzündung Two-Hit-Hypothese Hepatozyten Kupffer-Zellen Hep G2 Linolsäure Palmitinsäure Triglyceride Lipofundin iNOS CINC1 CINC2 MIP IL-6 TNFa ICAM PECAM Julia Demuth Non Alcoholic Fatty Liver Disease NASH fatty liver Steatosis Hepatis hepatitis Two-Hit-Hypothese hepatocytes Kupffer cells Hep G2 linoleic acid palmatic acid triglyceride Lipofundin iNOS CINC1 CINC2 MIP IL-6 TNFa ICAM PECAM 44.87 MED 415: Hepatologie
34	The spatial and temporal characterization of hepatic macrophages during acute liver injury Flores Molina, Manuel 08 1900 (has links) La réponse immunitaire est régulée spatialement et temporellement. Les cellules immunitaires font partie d’une plus grande communauté de populations cellulaires interconnectées qui coordonnent leurs actions par la signalisation intercellulaire. Suivant une blessure hépatique, la distribution et la composition du compartiment immunitaire évoluent rapidement au fil du temps. Par conséquent, l’information sur la position des cellules immunitaires dans le tissu hépatique est essentielle à la bonne compréhension de leurs fonctions dans la santé et la maladie. Cependant, l’organisation spatiale des cellules immunitaires en réponse à une atteinte hépatique aiguë, ainsi que les conséquences fonctionnelles de leur distribution topographique spécifique, restent mal comprises. Les macrophages hépatiques sont des cellules effectrices clés pendant l’homéostasie et en réponse à des blessures, et sont impliqués dans la pathogenèse de plusieurs maladies du foie. L’hétérogénéité et plasticité des macrophages dans le foie a été exposée avec l’émergence du séquençage de l’ARN, la cytométrie en flux et la cytométrie de masse. Ces techniques ont sensiblement contribué à la compréhension de l’origine, et fonctions des macrophages dans le foie. Cependant, ces technologies impliquent la destruction du tissu pour la préparation de suspension cellulaires ce qui entraîne une perte d’information spatiale et de contexte tissulaire. Par conséquent, la caractérisation spatiale et temporelle des macrophages dans le tissu hépatique pendant l’homéostasie tissulaire, et en réponse à une blessure, fournit une nouvelle information sur la façon dont les macrophages se rapportent aux cellules voisines et leur comportement pendant les réponses immunitaires. Dans la première partie de cette étude, nous avons conçu une stratégie pour le phénotypage spatial des cellules immunitaires hépatiques dans des échantillons de tissus. Cette stratégie combine techniques d'imagerie et l’alignement numérique des images pour surmonter les limitations actuelles du nombre de marqueurs pouvant être visualisés simultanément. En outre, nous avons généré des protocoles pour la quantification automatisée des cellules d’intérêt dans des sections de tissus pour réduire la subjectivité associée à la quantification par inspection visuelle, et pour augmenter la surface et la vitesse de l’analyse. Par conséquent, un plus grand nombre de populations de cellules immunitaires ont été visualisées, quantifiées et cartographiées, et leurs relations spatiales ont été déterminées. Dans la deuxième partie de l’étude, nous avons déterminé la cinétique et la dynamique spatiale des cellules de Kupffer (KCs) et des macrophages dérivés de monocytes (MoMFs) en réponse à une atteinte hépatique aiguë au CCl4, afin de mieux comprendre leurs rôles fonctionnels, et la répartition du travail entre eux. Nous avons constaté que les KC et les MoMFs présentent des différences au niveau de la distribution tissulaire, la morphologie, et la cinétique. En plus, seulement les KCs ont proliféré pour repeupler la population de macrophages résidents pendant la réparation tissulaire. Finalement, nous avons montré que le degré de colocalization de KCs et des MoMFs avec les cellules stellaires est différent. En plus, cette colocalisation varie avec la progression de la réponse immunitaire. Dans l’ensemble, nous avons montré que les KCs et les MoMFs ont des profils spatiaux et temporels différents en réponse à une atteinte hépatique aiguë. Dans l’ensemble, les observations faites dans cette étude suggèrent que le comportement spatial et temporel d’une sous-population donnée de cellules immunitaires est distinct et sous-tend sa capacité à remplir ses fonctions spécifiques pendant la réponse immunitaire. / The immune response is spatially and temporally regulated. Immune cells are part of a larger community of interconnected immune and non-immune cell populations that coordinate their actions mostly through cell-cell intercellular signaling. In the liver, the distribution pattern, and the composition of the immune compartment evolve during an immune response to injury influencing disease pathology, progression, and response to treatment. Hence, information on the location and interacting partners of immune cells in the hepatic tissue is critical for the proper understanding of their functions in health and disease. However, the spatial organization of hepatic resident and infiltrating immune cells in response to acute injury, and the functional consequences of their specific topographical distribution, remain poorly defined. Hepatic macrophages are key effector cells during homeostasis and in response to injury and are involved in the pathogenesis of several liver diseases. The heterogeneity and plasticity of the macrophage compartment in the liver have only recently started to be appreciated with the emergence of RNA sequencing, flow cytometry, and mass cytometry. Detailed transcriptomic and phenotypic profiling have deeply expanded our understanding of macrophage biology. However, these technologies involve tissue disruption with loss of spatial information and tissue context. Therefore, the spatial and temporal profiling of liver macrophages in tissue samples during the steady state, and in response to injury, provide novel information on how the macrophages relate to neighboring cells and their behavior during immune responses. In the first part of this study, we designed a strategy for the spatial phenotyping of hepatic immune cells in tissue samples. This strategy combined serial and sequential labeling, and digital tissue alignment to overcome current limitations in the number of markers that can be simultaneously visualized. In addition, we generated protocols for automated quantification of cells of interest in whole tissue sections which removed the subjectivity associated with quantification by visual inspection and greatly increased the area and the speed of the analysis. As a result, a larger number of immune cell populations were visualized, quantified, and mapped, and their spatial relations were determined in an unbiased manner. In the second part of this study, we monitored the kinetics, and spatial dynamics of resident Kupffer cells (KCs) and infiltrating monocyte-derived macrophages (MoMFs) in response to acute liver injury with CCl4, to gain insight into their functional roles, and the distribution of labor between them. KCs and MoMFs exhibited different tissue distribution patterns and cell morphology, different kinetics, and occupied neighboring but unique microanatomical tissue locations. KCs and MoMFs displayed a different capacity to replenish the macrophage pool upon acute injury, and were differentially related to hepatic stellate cells. Different kinetics and spatial profiles revealed that KCs and MoMFs have distinct spatial signatures and suggest that they perform distinct functions during the wound-healing response to acute liver injury. In summary, we optimized techniques and put together a strategy for the spatial profiling of hepatic immune cells. Then, we used this methodology to profile resident and infiltrating macrophage subpopulations to gain insight into their biology and distinct contribution to healing in response to acute liver injury. Overall, the observations made in this study suggest that the spatial and temporal behavior of a given subpopulation of immune cells underlie its ability to perform its specific functions during the immune response. Tumor microenvironment Multiplex immunofluorescence FFPE Image analysis Tissue alignment Tissue heatmap VIS software Kupffer cells Monocyte-derived macrophages Hepatic stellate cells CCl4-induced acute liver injury Spatial phenotyping Wound healing response Microenvironnement tumoral Immunofluorescence multiparamétrique FFPE Analyse d'images Alignement tissulaire Carte de chaleur tissulaire Logiciel VIS Cellules de Kupffer Macrophages dérivés de monocytes Cellules stellaires Phénotypage spatial Réponse de cicatrisation Immunology / Immunologie (UMI : 0982)
35	Study of Physiologic and Immunologic Incompatibilities of Pig to Human Transplantation Chihara, Ray K. January 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Solid organ transplantation is limited by available donor allografts. Pig to human transplantation, xenotransplantation, could potentially solve this problem if physiologic and immunologic incompatibilities are overcome. Genetic modifications of pigs have proven valuable in the study of xenotransplantation by improving pig to human compatibility. More genetic targets must be identified for clinical success. First, this study examines platelet homeostasis incompatibilities leading to acute thrombocytopenia in liver xenotransplantation. Mechanisms for xenogeneic thrombocytopenia were evaluated using liver macrophages, Kupffer cells, leading to identification of CD18, beta-2 integrin, as a potential target for modification. When disruption of CD18 was accomplished, human platelet binding and clearance by pig Kupffer cells was inhibited. Further, human and pig platelet surface carbohydrates were examined demonstrating significant differences in carbohydrates known to be involved with platelet homeostasis. Carbohydrate recognition domains of receptors responsible for platelet clearance Macrophage antigen complex-1 (CD11b/CD18) and Asialoglycoprotein receptor 1 in pigs were found to be different from those in humans, further supporting the involvement of platelet surface carbohydrate differences in xenogeneic thrombocytopenia. Second, immunologic incompatibilities due to antibody recognition of antigens resulting in antibody-mediated rejection were studied. Identification of relevant targets was systematically approached through evaluation of a known xenoantigenic protein fibronectin from genetically modified pigs. N-Glycolylneuraminic acid, a sialic acid not found in humans, was expressed on pig fibronectin and was identified as an antigenic epitope recognized by human IgG. These studies have provided further insight into xenogeneic thrombocytopenia and antibody-mediated rejection, and have identified potential targets to improve pig to human transplant compatibility. Transplantation Xenotransplantation Thrombocytopenia Antibody-mediated rejection Medicine -- Research -- Animal models Transplantation immunology -- Research Graft rejection -- Research Swine -- Physiology -- Research Kupffer cells Compatibility testing (Hematology) Animal biotechnology -- Research Antigens -- Analysis Blood platelets -- Activation Homeostasis -- Research -- Analysis

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