Global ETD Search

1	MULTIPLE  DANGER  SIGNALS  AND  THEIR  EFFECT  ON  MONOCYTE  DERIVED DENDRITIC  CELL  PHENOTYPE  AND  FUNCTION Paustian, Christopher Charles 07 July 2010 (has links) No description available. Immunology dendritic cell monocyte tlr atp danger signal
2	Serine proteases and serine protease homologs : genetic analysis of their involvement in immune response activation in Drosophila / Protéases et protéases-homologues : analyse génétique de leur implication dans l'activation de la réponse immunitaire de la drosophile Patrnogic, Jelena 26 September 2014 (has links) Lors de la réponse immunitaire de la drosophile, la voie Toll est activée lors d'un challenge immunitaire par des bactéries à Gram positif ou des champignons. Ce mécanisme est initié soit par la reconnaissance de motifs moléculaires associés aux pathogènes (PAMPs) qui activent la voie de reconnaissance, soit par des facteurs de virulence et des protéases produits par les agents pathogènes qui activent la voie des signaux de danger. Le travail que j'ai effectué a pour but de caractériser les différentes molécules impliquées dans ces cascades protéolytiques en amont de Toll. Cela permettra de reconstituer ces cascades in vitro et de comprendre comment elles sont organisées, comment et où des complexes peuvent être formés. La première partie concerne les approches génétiques utilisées pour générer des mutants des gènes pouvant être impliqués dans l'activation de la voie Toll par la voie des PAMPs. La deuxième partie se concentre sur un homologue inactif de protéase à sérine appelé spheroide et sur son implication dans la voie de reconnaissance des signaux de danger. Pour la première fois, nous avons pu démontrer qu'une protéase inactive est requise dans la cascade protéolytique, et plus particulièrement dans la détection des signaux de danger après un challenge immunitaire par des bactéries pathogènes à Gram positif. / The Toll pathway in Drosophila immune response is activated upon immune challenge with Gram positive bacteria and fungi. This can be achieved either through recognition of Pathogen Associated Molecular Patterns (PAMPs), which triggers the recognition cascade; or by virulence factors and proteases produced by the pathogens, which triggers the danger signal cascade. The work I have done aimed to characterize the various molecules involved in proteolytic cascade supstream of Toll. This will help to reconstitute these cascades in vitro and understand how they are organized, how and where complexes could be formed. The first part focuses on genetic approaches used to generate mutants for genes suggested to be involved in the activation of Toll pathway via the recognition cascade. The second part focuses on an inactive serine protease, aserine protease homolog spheroide and its involvement in the danger signal cascade. For the first time, we could demonstrate that an inactive protease is required in the proteolytic cascade,involved in the sensing of danger signais upon immune challenge with pathogenic Gram-positive bacteria. Immunité innée Drosophila Protéase à sérine Signal de danger Innate immunity Drosophila Serine proteases Danger signal 571.96 579.3
3	Rôle du récepteur purinergique P2Y11 dans la modulation du phénotype des cellules dendritiques et la survie des cardiomyocytes en situation d'hypoxie/réoxygénation / The role of P2Y11 receptor in the modulation of dendritic cell phenotype and cardiomyocyte survival during hypoxia/reoxygenation Chadet, Stéphanie 22 September 2015 (has links) Les cellules dendritiques (DCs) possèdent des rôles clés dans la modulation de la réponse inflammatoire. Leur implication dans la réponse inflammatoire post-ischémie/reperfusion semble claire. Cependant, leurs rôles spécifiques restent encore à élucider. Nous avons émis l’hypothèse selon laquelle la modulation de la réponse des cellules dendritiques suite à la séquence d’ischémie/reperfusion pourrait diminuer les lésions du greffon cardiaque. L’objectif de ce travail a donc consisté en l’exploration et l’identification d’un mécanisme immunomodulateur dans la DC. Un modèle cellulaire d’hypoxie/réoxygénation (H/R) et un modèle de co-culture DCs / cardiomyocytes ont été utilisés. / Dendritic cells (DCs) play key roles during the inflammatory process. Although their involvement in ischemia/reperfusion (I/R)-related inflammation is known, their specific role in such a context remain to be elucidated.We hypothesized that the modulation of DC phenotype during I/R might decrease cardiac graft injuries. In this study, we aimed to explore and identify an immunomodulatory mechanism in DCs. An in vitro model of hypoxia/reoxygenation (H/R) and a co-culture model were used. Our results highlight that the purinergic receptor P2Y11 (P2Y11R) exhibits an immunosuppressive role in DCs. This effect was lost when cells were subjected to a H/R insult, due to P2Y11R downregulation during hypoxia. Cellule dendritique Cardiomyocyte Récepteur P2Y11 Immunomodulation Signaux de danger Dendritic cell Cardiomyocyte P2Y11 receptor Immunomodulation Danger signal
4	Autoimmune Regulator Deficient Mice, an Animal Model of Autoimmune Polyendocrine Syndrome Type I Hässler, Signe January 2006 (has links) <p>Autoimmune diseases develop when the immune system fails to distinguish self from non-self or when the immune system is hypersensitive to endogenous or exogenous danger signals, or when a tissue erroneously sends a danger signal to the immune system. The education of the immune system to distinguish self from non-self is mainly carried out in the thymus and gives rise to central tolerance, whereas the ability to sense a danger or a healthy tissue constitutes peripheral tolerance. In these studies we have investigated the peripheral tolerance mechanisms controlled by the autoimmune regulator <i>(Aire)</i> gene in Aire deficient mice, an animal model of the monogenic disease autoimmune polyendocrine syndrome type I (APS I).</p><p>Aire-/- mice displayed increased numbers of myeloid-derived antigen-presenting cells (APCs) in the spleen, lymph nodes and peritoneum as well as more blood monocytes and metallophilic macrophages in the spleen. Monocytes were also increased in the blood of APS I patients. Monocyte precursors displayed an accelerated development in the bone marrow of Aire-/- mice, and Aire-/- APCs had an altered phenotype that caused an increased immune response in several different contexts. Aire-/- splenic and lymph node dendritic cells had an increased ability to activate naive T cells, partly as a result of an upregulated expression of the costimulatory molecule VCAM-1. In Aire-/- mice increased activity of the metallophilic macrophages in the splenic marginal zone seems to be responsible both for the activated phenotype of marginal zone B cells and for the frequent development of marginal zone lymphoma with aging. In a TCR transgenic model Aire deficiency caused an increased superantigen-mediated TCR revision in the spleen, perhaps as a result of the altered phenotype of APCs in the spleen. Finally, Aire was shown to influence autoimmune disease development by a macrophage-dependent mechanism in diabetes induced with multiple low dose streptozotocin injections.</p><p>These results indicate that Aire has an important function in peripheral tolerance by controlling the phenotype of myeloid-derived APCs and thereby regulating the activation of T and B lymphocytes.</p> / <p>Autoimmune diseases develop when the immune system fails to distinguish self from non-self or when the immune system is hypersensitive to endogenous or exogenous danger signals, or when a tissue erroneously sends a danger signal to the immune system. The education of the immune system to distinguish self from non-self is mainly carried out in the thymus and gives rise to central tolerance, whereas the ability to sense a danger or a healthy tissue constitutes peripheral tolerance. In these studies we have investigated the peripheral tolerance mechanisms controlled by the autoimmune regulator <i>(Aire)</i> gene in Aire deficient mice, an animal model of the monogenic disease autoimmune polyendocrine syndrome type I (APS I).</p><p>Aire-/- mice displayed increased numbers of myeloid-derived antigen-presenting cells (APCs) in the spleen, lymph nodes and peritoneum as well as more blood monocytes and metallophilic macrophages in the spleen. Monocytes were also increased in the blood of APS I patients. Monocyte precursors displayed an accelerated development in the bone marrow of Aire-/- mice, and Aire-/- APCs had an altered phenotype that caused an increased immune response in several different contexts. Aire-/- splenic and lymph node dendritic cells had an increased ability to activate naive T cells, partly as a result of an upregulated expression of the costimulatory molecule VCAM-1. In Aire-/- mice increased activity of the metallophilic macrophages in the splenic marginal zone seems to be responsible both for the activated phenotype of marginal zone B cells and for the frequent development of marginal zone lymphoma with aging. In a TCR transgenic model Aire deficiency caused an increased superantigen-mediated TCR revision in the spleen, perhaps as a result of the altered phenotype of APCs in the spleen. Finally, Aire was shown to influence autoimmune disease development by a macrophage-dependent mechanism in diabetes induced with multiple low dose streptozotocin injections.</p><p>These results indicate that Aire has an important function in peripheral tolerance by controlling the phenotype of myeloid-derived APCs and thereby regulating the activation of T and B lymphocytes.</p> Molecular medicine autoimmune regulator autoimmune polyendocrine syndrome type I peripheral tolerance antigen presenting cells autoimmunity danger signal knockout mice Molekylärmedicin
5	Autoimmune Regulator Deficient Mice, an Animal Model of Autoimmune Polyendocrine Syndrome Type I Hässler, Signe January 2006 (has links) Autoimmune diseases develop when the immune system fails to distinguish self from non-self or when the immune system is hypersensitive to endogenous or exogenous danger signals, or when a tissue erroneously sends a danger signal to the immune system. The education of the immune system to distinguish self from non-self is mainly carried out in the thymus and gives rise to central tolerance, whereas the ability to sense a danger or a healthy tissue constitutes peripheral tolerance. In these studies we have investigated the peripheral tolerance mechanisms controlled by the autoimmune regulator (Aire) gene in Aire deficient mice, an animal model of the monogenic disease autoimmune polyendocrine syndrome type I (APS I). Aire-/- mice displayed increased numbers of myeloid-derived antigen-presenting cells (APCs) in the spleen, lymph nodes and peritoneum as well as more blood monocytes and metallophilic macrophages in the spleen. Monocytes were also increased in the blood of APS I patients. Monocyte precursors displayed an accelerated development in the bone marrow of Aire-/- mice, and Aire-/- APCs had an altered phenotype that caused an increased immune response in several different contexts. Aire-/- splenic and lymph node dendritic cells had an increased ability to activate naive T cells, partly as a result of an upregulated expression of the costimulatory molecule VCAM-1. In Aire-/- mice increased activity of the metallophilic macrophages in the splenic marginal zone seems to be responsible both for the activated phenotype of marginal zone B cells and for the frequent development of marginal zone lymphoma with aging. In a TCR transgenic model Aire deficiency caused an increased superantigen-mediated TCR revision in the spleen, perhaps as a result of the altered phenotype of APCs in the spleen. Finally, Aire was shown to influence autoimmune disease development by a macrophage-dependent mechanism in diabetes induced with multiple low dose streptozotocin injections. These results indicate that Aire has an important function in peripheral tolerance by controlling the phenotype of myeloid-derived APCs and thereby regulating the activation of T and B lymphocytes. / Autoimmune diseases develop when the immune system fails to distinguish self from non-self or when the immune system is hypersensitive to endogenous or exogenous danger signals, or when a tissue erroneously sends a danger signal to the immune system. The education of the immune system to distinguish self from non-self is mainly carried out in the thymus and gives rise to central tolerance, whereas the ability to sense a danger or a healthy tissue constitutes peripheral tolerance. In these studies we have investigated the peripheral tolerance mechanisms controlled by the autoimmune regulator (Aire) gene in Aire deficient mice, an animal model of the monogenic disease autoimmune polyendocrine syndrome type I (APS I). Aire-/- mice displayed increased numbers of myeloid-derived antigen-presenting cells (APCs) in the spleen, lymph nodes and peritoneum as well as more blood monocytes and metallophilic macrophages in the spleen. Monocytes were also increased in the blood of APS I patients. Monocyte precursors displayed an accelerated development in the bone marrow of Aire-/- mice, and Aire-/- APCs had an altered phenotype that caused an increased immune response in several different contexts. Aire-/- splenic and lymph node dendritic cells had an increased ability to activate naive T cells, partly as a result of an upregulated expression of the costimulatory molecule VCAM-1. In Aire-/- mice increased activity of the metallophilic macrophages in the splenic marginal zone seems to be responsible both for the activated phenotype of marginal zone B cells and for the frequent development of marginal zone lymphoma with aging. In a TCR transgenic model Aire deficiency caused an increased superantigen-mediated TCR revision in the spleen, perhaps as a result of the altered phenotype of APCs in the spleen. Finally, Aire was shown to influence autoimmune disease development by a macrophage-dependent mechanism in diabetes induced with multiple low dose streptozotocin injections. These results indicate that Aire has an important function in peripheral tolerance by controlling the phenotype of myeloid-derived APCs and thereby regulating the activation of T and B lymphocytes. Molecular medicine autoimmune regulator autoimmune polyendocrine syndrome type I peripheral tolerance antigen presenting cells autoimmunity danger signal knockout mice Molekylärmedicin
6	HOMOCYSTEINE-METHIONINE CYCLE IS A KEY METABOLIC SENSOR SYSTEM CONTROLLING METHYLATION-REGULATED PATHOLOGICAL SIGNALING - CD40 IS A PROTOTYPIC HOMOCYSTEINE-METHIONINE CYCLE REGULATED MASTER GENE Gao, Chao January 2019 (has links) Homocysteine-Methionine (HM) cycle produces a universal methyl group donor S-adenosylmethionine (SAM), a competitive methylation inhibitor S-adenosylhomocysteine (SAH), and an intermediate amino acid product homocysteine (Hcy). Elevated plasma levels of Hcy is termed as hyperhomocycteinemia (HHcy) which is an established risk factor for cardiovascular disease (CVD) and neural degenerative disease. We were the first to describe methylation inhibition as a mediating biochemical mechanism for endothelial injury and inflammatory monocyte differentiation in HHcy-related CVD and diabetes. We proposed metabolism-associated danger signal (MADS) recognition as a novel mechanism for metabolic risk factor-induced inflammatory responses, independent from pattern recognition receptor (PRR)-mediated pathogen-associated molecular pattern (PAMP)/danger-associated molecular pattern (DAMP) recognition. In this study, we examined the relationship of HM cycle gene expression with methylation regulation in human disease. We selected 115 genes in the extended HM cycle, including 31 metabolic enzymes and 84 methyltransferases (MT), examined their mRNA levels in 35 human disease conditions using a set of public databases. We discovered that: 1) HM cycle senses metabolic risk factor and controls SAM/SAH-dependent methylation. 2) Most of metabolic enzymes in HM cycle (8/11) are located in cytosol, while most of the SAM-dependent MTs (61/84) are located in the nucleus, and Hcy metabolism is absent in the nucleus. 3) 11 up-regulated, 3 down-regulated and 24 differentially regulated SAM/SAH-responsive signal pathways are involved in 7 human disease categories. 4) 8 SAM/SAH-responsive H3/H4 hypomethylation sites are identified in 8 disease conditions. We conclude that HM cycle is a key metabolic sensor system which mediates receptor-independent MADS recognition and modulates SAM/SAH-dependent methylation in human disease. We propose that HM metabolism takes place in cytosol and that nuclear methylation equilibration requires nuclear-cytosol transfer of SAM, SAH and Hcy. CD40 is a cell surface molecule which is expressed on antigen presenting cells such as monocyte, macrophage, dendritic cells and neutrophils. The costimulatory pair, CD40 and CD40L, enhances T cell activation and induce chronic inflammatory disease. Also, DNA hypomethylation on CD40 promotor induces inflammatory monocyte differentiation in chronic kidney disease. In order to figure out if CD40 is a prototypic HM cycle regulated master gene, RNA-seq analysis were performed for CD40+ and CD40- monocytes from mouse peripheral blood and 1,093 differentially expressed genes (DEGs) were selected from those two groups. All the DEGs modulate as much as 15 functional gene groups such as cytokines, enzymes and transcriptional factors. Furthermore, CD40+ monocytes activated trained immunity pathways especially in Acetyl-CoA generation and mevalonate pathway. In HM cycle, CD40 is a prototypic HM cycle regulated master gene to induce the most of the Hcy metabolic enzymes as well as MT, which can further modulate the methylation-regulated pathological signaling. / Biomedical Sciences Pharmacology Biology, Molecular Immunology Cd40 Histone Methylation Homocysteine-methionine Cycle Hyperhomocysteinemia Hypomethylation

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