Global ETD Search

41	Studies on the exaggerated inflammatory response caused by streptococcus suis at systemic and central nervous system levels Domínguez Punaro, María de la Cruz 04 1900 (has links) Streptococcus suis de type 2 est un microorganisme pathogène d’importance chez le porc. Il est la cause de différentes pathologies ayant comme caractéristique commune la méningite. C’est également un agent émergeant de zoonose : des cas cliniques humains ont récemment été rapportés en Asie. Cependant, la pathogénèse de S. suis n’est pas encore complètement élucidée. Jusqu’à présent, la réponse pro-inflammatoire initiée par S. suis n’a été étudiée qu’in vitro. L’étude du choc septique et de la méningite requiert toujours des modèles expérimentaux appropriés. Au cours de cette étude, nous avons développé un modèle in vivo d’infection chez la souris qui utilise la voie d’inoculation intra-péritonéale. Ce modèle a servi à l’étude de la réponse pro-inflammatoire associée à ce pathogène, tant au niveau systémique qu’au niveau du système nerveux central (SNC). Il nous a également permis de déterminer si la sensibilité aux infections à S. suis pouvait être influencée par des prédispositions génétiques de l’hôte. Le modèle d’infection par S. suis a été mis au point sur des souris de lignée CD1. Les résultats ont démontré une bactériémie élevée pendant les trois jours suivant l’infection. Celle-ci était accompagnée d’une libération rapide et importante de différentes cytokines pro-inflammatoires (TNF-α, IL-6, IL-12p40/p70, IFN-ɣ) et de chémokines (KC, MCP-1 and RANTES), qui ont entraîné un choc septique et la mort de 20 % des animaux. Ensuite, pour confirmer le rôle de l’inflammation sur la mortalité et pour déterminer si les caractéristiques génétiques de l’hôte pouvaient influencer la réponse inflammatoire et l’issue de la maladie, le modèle d’infection a été étendu à deux lignées murines consanguines différentes considérées comme résistante : la lignée C57BL/6 (B6), et sensible : la lignée A/J. Les résultats ont démontré une importante différence de sensibilité entre les souris A/J et les souris B6, avec un taux de mortalité atteignant 100 % à 20 h post-infection (p.i.) pour la première lignée et de seulement 16 % à 36 h p.i. pour la seconde. La quantité de bactéries dans le sang et dans les organes internes était similaire pour les deux lignées. Donc, tout comme dans la lignée CD1, la bactériémie ne semblait pas être liée à la mort des souris. La différence entre les taux de mortalité a été attribuée à un choc septique non contrôlé chez les souris A/J infectées par S. suis. Les souris A/J présentaient des taux exceptionnellement élevés de TNF-α, IL-12p40/p70, IL-1β and IFN- γ, significativement supérieurs à ceux retrouvés dans la lignée B6. Par contre, les niveaux de chémokines étaient similaires entre les lignées, ce qui suggère que leur influence est limitée dans le développement du choc septique dû à S. suis. Les souris B6 avaient une production plus élevée d’IL-10, une cytokine anti-inflammatoire, ce qui suppose que la cascade cytokinaire pro-inflammatoire était mieux contrôlée, entraînant un meilleur taux de survie. Le rôle bénéfique potentiel de l’IL-10 chez les souris infectées par S. suis a été confirmé par deux approches : d’une part en bloquant chez les souris B6 le récepteur cellulaire à l’IL-10 (IL-10R) par un anticorps monoclonal anti-IL-10R de souris et d’autre part en complémentant les souris A/J avec de l’IL-10 de souris recombinante. Les souris B6 ayant reçu le anticorps monoclonal anti-IL-10R avant d’être infectées par S. suis ont développé des signes cliniques aigus similaires à ceux observés chez les souris A/J, avec une mortalité rapide et élevée et des taux de TNF-α plus élevés que les souris infectées non traitées. Chez les souris A/J infectées par S. suis, le traitement avec l’IL-10 de souris recombinante a significativement retardé l’apparition du choc septique. Ces résultats montrent que la survie au choc septique dû à S. suis implique un contrôle très précis des mécanismes pro- et anti-inflammatoires et que la réponse anti-inflammatoire doit être activée simultanément ou très rapidement après le début de la réponse pro-inflammatoire. Grâce à ces expériences, nous avons donc fait un premier pas dans l’identification de gènes associés à la résistance envers S. suis chez l’hôte. Une des réussites les plus importantes du modèle d’infection de la souris décrit dans ce projet est le fait que les souris CD1 ayant survécu à la septicémie présentaient dès 4 jours p.i. des signes cliniques neurologiques clairs et un syndrome vestibulaire relativement similaires à ceux observés lors de méningite à S. suis chez le porc et chez l’homme. L’analyse par hybridation in situ combinée à de l’immunohistochimie des cerveaux des souris CD1 infectées a montré que la réponse inflammatoire du SNC débutait avec une augmentation significative de la transcription du Toll-like receptor (TLR)2 et du CD14 dans les microvaisseaux cérébraux et dans les plexus choroïdes, ce qui suggère que S. suis pourrait se servir de ces structures comme portes d’entrée vers le cerveau. Aussi, le NF-κB (suivi par le système rapporteur de l’activation transcriptionnelle de IκBα), le TNF-α, l’IL-1β et le MCP-1 ont été activés, principalement dans des cellules identifiées comme de la microglie et dans une moindre mesure comme des astrocytes. Cette activation a également été observée dans différentes structures du cerveau, principalement le cortex cérébral, le corps calleux, l’hippocampe, les plexus choroïdes, le thalamus, l’hypothalamus et les méninges. Partout, cette réaction pro-inflammatoire était accompagnée de zones extensives d’inflammation et de nécrose, de démyélinisation sévère et de la présence d’antigènes de S. suis dans la microglie. Nous avons mené ensuite des études in vitro pour mieux comprendre l’interaction entre S. suis et la microglie. Pour cela, nous avons infecté des cellules microgliales de souris avec la souche sauvage virulente (WT) de S. suis, ainsi qu’avec deux mutants isogéniques, un pour la capsule (CPS) et un autre pour la production d’hémolysine (suilysine). Nos résultats ont montré que la capsule était un important mécanisme de résistance à la phagocytose pour S. suis et qu’elle modulait la réponse inflammatoire, en dissimulant les composants pro-inflammatoires de la paroi bactérienne. Par contre, l’absence d’hémolysine, qui est un facteur cytotoxique potentiel, n’a pas eu d’impact majeur sur l’interaction de S. suis avec la microglie. Ces études sur les cellules microgliales ont permis de confirmer les résultats obtenus précédemment in vivo. La souche WT a induit une régulation à la hausse du TLR2 ainsi que la production de plusieurs médiateurs pro-inflammatoires, dont le TNF-α et le MCP-1. S. suis a induit la translocation du NF-kB. Cet effet était plus rapide dans les cellules stimulées par le mutant déficient en CPS, ce qui suggère que les composants de la paroi cellulaire représentent de puissants inducteurs du NF-kB. De plus, la souche S. suis WT a stimulé l’expression de la phosphotyrosine, de la PKC et de différentes cascades liées à l’enzyme mitogen-activated protein kinase (MAPK). Cependant, les cellules microgliales infectées par le mutant déficient en CPS ont montré des profils de phosphorylation plus forts et plus soutenus que celles infectées par le WT. Finalement, la capsule a aussi modulé l’expression de l’oxyde nitrique synthétase inductible (iNOS) induite par S. suis et par la production subséquente d’oxyde nitrique par la microglie. Ceci pourrait être lié in vivo à la neurotoxicité et à la vasodilatation. Nous pensons que ces résultats contribueront à une meilleure compréhension des mécanismes sous-tendant l’induction de l’inflammation par S. suis, ce qui devrait permettre, d’établir éventuellement des stratégies plus efficaces de lutte contre la septicémie et la méningite. Enfin, nous pensons que ce modèle expérimental d’infection chez la souris pourra être utilisé dans l’étude de la pathogénèse d’autres bactéries ayant le SNC pour cible. / Streptococcus suis serotype 2 is an important swine pathogen responsible for diverse infections, meningitis being its most striking feature. In addition, it is an emerging agent of zoonosis, which has gained worldwide attention due to important outbreaks in Asia. Understanding the pathogenesis of S. suis infections still represents a challenge. Up to present, the pro-inflammatory response due to S. suis has only been studied in vitro, and there is still a great need of appropriate experimental models for both septic shock and meningitis. In the present study, we successfully developed an in vivo model of S. suis infection in adult mice infected by the intraperitoneal route. This model served to investigate the pro-inflammatory events that take place at both the systemic and Central Nervous System (CNS) levels associated with this important pathogen. In addition, this model was useful to determine if susceptibility to S. suis infection may be influenced by the genetic background of the host. The mouse model of S. suis infection was standardized in CD1 mice. Results showed sustained bacteremia during the 3 days post-infection (p.i.), accompanied by a quick and substantial release of different pro-inflammatory cytokines (TNF-α, IL-6, IL-12p40/p70, IFN-ɣ) and chemokines (KC, MCP-1 and RANTES) that lead to septic shock and 20% mortality in mice. Once the hallmark of the septic phase of S. suis infection was established in CD1 mice, research continued with the objective to confirm the role of inflammation in mortality and to determine if the genetic background of the host may influence the inflammatory response toward this pathogen and the further outcome of the disease. For this, the mouse model of S. suis infection was used with two genetically different inbred mouse strains, this is, C57BL/6 (B6) and A/J mice, which are considered as the prototype of Th1-type and Th2-type mice, respectively. Results demonstrated a striking susceptibility to S. suis infection in A/J mice in comparison to B6 mice, with 100% mortality in the former mice strain at 20 h p.i., and 16 % mortality at 36 h p.i. for the latter. Very interestingly, and similarly to CD1 mice, bacteremia did not seem to be responsible for the death of mice, as both mice strains presented similar amounts of bacteria in blood and organs. Thus, it was postulated that the higher mortality in S. suis-infected A/J mice was due to uncontrolled septic shock. In fact, A/J mice presented very high levels of TNF-α, IL-12p40/p70, IL-1β and IFN-ɣ, that significantly exceeded those found in B6 mice. Remarkably, chemokine levels were similar between strains, suggesting their limited participation in the development of septic shock by S. suis. A greater survival of B6 mice was partially related to a better regulation of the pro-inflammatory cytokine cascade, as they showed a higher production of the anti-inflammatory cytokine IL-10 than A/J mice. The potential beneficial role of the IL-10 in mice infected with S. suis was confirmed using two approaches: the first, by blockage of the cell receptor of IL-10 (IL-10R) with an anti-mouse IL-10R monoclonal antibody (Mab) in B6 mice and the second by administrating recombinant mouse (rm)IL-10 (rmIL-10) to A/J mice. B6 mice that received the IL-10R MAb treatment before challenge with S. suis developed a clinical acute disease similar to that observed with A/J mice, with a striking and rapid increase in mortality and higher levels of TNF-α in comparison to those of infected mice that did not receive the treatment. Controversially, treatment with rmIL-10 significantly delayed the onset of septic shock in A/J mice infected with S. suis. These results show that survival from S. suis septic shock requires a tight regulation of pro- and anti-inflammatory mechanisms, and that the latter should be activated at the same time or soon after the onset of the pro-inflammatory response. This part of the study may represent a first step in the identification of host genes associated with resistance against S. suis. One of the most important achievements of the mouse model of infection described in this project is the development of distinct clinical signs of neurological disease in CD1 mice from 4 days p.i. Indeed, in CD1 mice that survived sepsis due to S. suis infection, clinical signs of neurological disease and vestibular syndrome, which are quite similar to those observed in clinical cases of S. suis meningitis in both pigs and humans, were observed. Studies of the brains of infected CD1 mice using in situ hybridization combined with immunocytochemistry, demonstrated that the CNS inflammatory response began with a significant increase in the transcription of Toll-like receptor (TLR)2 and CD14 initially in the brain microvasculature and choroid plexuses, suggesting that S. suis may use these structures as portals of entry to the brain. There also was activation of NF-κB (as indicated by transcriptional activation of IκBα as a reporter system) and TNF-α, IL-1β and MCP-1, mainly in cells identified as microglia and to a lesser extent in astrocytes. These signals reached different brain structures, mainly the brain cortex, corpus callosum, hippocampus, choroid plexuses, thalamus, hypothalamus and meninges. All of these pro-inflammatory events were associated with extensive areas of inflammation and necrosis, severe demyelination and presence of antigens of S. suis inside microglia. In vitro studies were conducted in order to better understand the interactions of S. suis and microglia. For this, mouse microglia were infected with a virulent wild type (WT) strain of S. suis. Two isogenic mutants deficient in capsule (CPS) or hemolysin production (suilysin, SLY) respectively, were also included for comparative purposes. The CPS was important for S. suis resistance to phagocytosis, and it also modulated the inflammatory response by hiding pro-inflammatory components from the bacterial cell wall. On the other hand, the absence of SLY, a potential cytotoxic factor, did not have a major impact on S. suis interactions with microglia. Studies with microglia helped to confirm previous findings in vivo in mice, as the WT S. suis strain induced the up-regulation of TLR2 and the production of several pro-inflammatory mediators, including TNF-α and MCP-1. As observed in mice, S. suis induced NF-kB translocation, which was more rapid for cells stimulated with the CPS-deficient mutant, suggesting that bacterial cell wall components are potent inducers of NF-kB. Moreover, WT S. suis promoted phosphotyrosine, PKC and different mitogen-activated protein kinase (MAPK) events. However, microglia infected with the CPS-deficient mutant showed overall stronger and more sustained phosphorylation profiles. Finally, the CPS also modulated S. suis-induced inducible nitrogen oxide synthase (iNOS) expression and further nitric oxide production in microglia, which could be related to neurotoxicity and vasodilatation in vivo. We are confident that our results may help to more fully understand the mechanisms underlying S. suis induction of inflammation, leading to the design of more efficient anti-inflammatory strategies for sepsis and meningitis. Finally, we believe this experimental model of infection in mice could also be useful for studying the pathogenesis of infections of the CNS, due to other bacteria. Streptococcus suis mouse sepsis meningitis inflammation cytokine chemokine microglia TLR2 MAPK Streptococcus suis souris sepsis méningite inflammation cytokine chemiokine microglia TLR2 MAPK
42	Aspectos moleculares da gênese e progressão de lesões periapicais induzidas experimentalmente em camundongos / Molecular aspects of genesis and progression of induced apical periodontitis in mice Driely Barreiros 18 July 2017 (has links) O conhecimento dos eventos biológicos que ocorrem no periápice dos dentes com necrose pulpar se torna importante para compreender o desenvolvimento das lesões periapicais. Muitas são as moléculas e mediadores que participam na instalação da lesão periapical, a partir da infecção bacteriana que ocorre no interior dos canais radiculares. Assim, o objetivo do presente trabalho foi avaliar moléculas do sistema imune inato, da osteoclastogênese e metaloproteinases em lesões periapicais (LP) induzidas experimentalmente em camundongos knockout e wild type. Para esse objetivo, o presente estudo foi dividido em dois trabalhos distintos. O primeiro teve como objetivo avaliar a expressão de metaloproteinase 2 (MMP2) e metaloproteinase 9 (MMP9) durante a progressão da LP em camundongos knockout para TLR2 (TLR2 KO) e MyD88 (MyD88 KO), em comparação com camundongos wild type (WT). O segundo estudo avaliou a correlação da expressão gênica e imunomarcação de RANK, RANKL, OPG, TLR2 e MyD88 durante a progressão da LP em camundongos WT. No primeiro estudo lesões periapicais foram induzidas em molares inferiores de 54 camundongos TLR2 KO, MyD88 KO e WT (n=18/grupo). Após 7, 21 e 42 dias, os animais foram eutanaziados e as mandíbulas foram dissecadas e submetidas a processamento histotécnico. Os cortes histológicos foram submetidos a imunohistoquímica e posteriormente foi avaliada presença ou ausência de MMP2 e MMP9 nos diferentes grupos. No segundo estudo, 35 camundongos WT foram utilizados. As lesões periapicais foram induzidas nos primeiros molares inferiores de ambos os lados. Após 0 (G0), 7 (G7), 21 (G21) e 42 (G42) dias, os animais foram anestesiados e eutanasiados para que as mandíbulas fossem dissecadas e divididas ao meio.O lado direito das mandíbulas foi para o processamento histotécnico, para posterior marcação de RANK, RANKL, OPG, TLR2 e MyD88, por meio da imuno-histoquímica do lado esquerdo da mandíbula foi utilizado para a extração de RNA, para a determinação da expressão gênica de RANK (Tnfrsf11a), RANKL (Tnfrsf11), OPG (Tnfrsf11b), TLR2 (Tlr2) e MyD88 (Myd88) utilizando quantificação em Tempo Real da Reação da Polimerase em Cadeia (qRT-PCR). Para ambos os estudos, testes paramétricos e não paramétricos foram realizados com nível de significância de 5%. Foi possível observar, no primeiro estudo, que nos períodos iniciais da progressão da lesão periapical, houve um aumento na imunomarcação de MMP9 nos camundongos TLR2 KO e MyD88 KO, quando comparados aos WT, diferente da MMP2 que não se observou nenhum aumento na imunomarcação. No entanto, aos 42 dias observou-se uma redução da imunomarcação de MMP2 e um aumento da MMP9 nos camundongos TLR2 KO. Adicionalmente, no segundo estudo, foi possível observar um aumento da imunomarcação para RANK, RANKL, OPG, TLR2 e MyD88 durante a progressão da lesão periapical (p<0,05). O aumento da expressão de Tnfrsf11 foi diferente entre os grupos G0 e G42, e G21 e G42 (p=0,006). No entanto, a expressão de Tnfrsf11b foi diferente entre os grupos G0 e G7, G7, G21 e G42, sendo possível observar uma diminuição dessa expressão ao longo do tempo (p<0,001). Tlr2 foi mais expresso entre os grupos G0 e G42 (p=0,03). E a expressão da molécula Myd88 foi estatisticamente significante entre os grupos G0 e G7, G21 e G42 (p=0,01). A razão Tnfrsf11/Tnfrsf11b aumentou durante a progressão da lesão periapical (p=0,002). Também foi possível observar uma correlação moderada entre Myd88 e Rankl (r=0,42; p=0,03) e entre Myd88 e Tlr2 (r=0,48; p<0,0001). Após as metodologias empregadas e os dados analisados, concluímos que a produção de MMP2 e MMP9 foi modulada por TLR2 e Myd88 durante a progressão da lesão periapical. Alem disso, podemos sugerir que existe uma correlação positiva entre o sistema RANK/RANKL/OPG e as proteínas do sistema imune inato, TLR2 e MyD88, durante a perda óssea decorrente da infecção bacteriana dos canais radiculares e posterior progressão da lesão periapical. / Knowledge of the biological events occurring inteeth apex with pulp necrosis becomes important to understand the development of periapical lesions. There are manymolecules and mediators that participate in the installation of the periapical lesion, from the bacterial infection that occurs inside the root canals. Thus, the aim of the present study was to evaluate molecules of the innate immune system, osteoclastogenesis and metalloproteinases in experimentally apical periodontitis (AP) induced in knockout and wild type mice. For this purpose, the present study was divided into two distinct studies. The first one aimed to evaluate the expression of metalloproteinases 2 (MMP2) and metalloproteinases 9 (MMP9) during the progression of AP in TLR2 knockout mice (TLR2 KO) and MyD88 knockout mice (MyD88 KO), compared to wild type mice (WT). The second study evaluated the correlation of gene expression and immunostaining of RANK, RANKL, OPG, TLR2 and MyD88 during LP progression in WT mice. In the first study AP were induced in lower molars of 54 TLR2 KO, MyD88 KO and WT mice (n = 18 / group). After 7, 21 and 42 days, the animals were euthanized and the jaws were dissected and submitted to histotechnical processing. The histological sections were submitted to immunohistochemistry and subsequently the presence or absence of MMP2 and MMP9 in the different groups was evaluated. In the second study, 35 WT mice were used. Periapical lesions were induced in the lower first molars on both sides. After 0 (G0) to 7 (G7), 21 (G21) and 42 (G42) days, the animals were anesthetized and euthanized so that the jaws were dissected and divided in half. The right side of the jaws was for the histotechnic processing, for subsequent imunostaining of RANK, RANKL, OPG, TLR2 and MyD88, through immunohistochemistry and the left side of the jaws was used for the extraction of RNA, for the determination of expression of RANK (Tnfrsf11a), RANKL (Tnfrsf11), OPG (Tnfrsf11b), TLR2 (Tlr2) and MyD88 (Myd88) using Quantification Real Time of Polymerase Chain Reaction (qRT-PCR). For both studies, parametric and non-parametric tests were performed with significance level of 5%. It was possible to observe in the first study that in the initial periods of AP progression there was an increase in MMP9 immunostaining in TLR2 KO and MyD88 KO mice when compared to WT, different from MMP2 that no increase in immunostaining was observed. However, at 42 days there was a reduction in MMP2 immunostaining and an increase of MMP9 in TLR2 KO mice was observed. Additionally, in the second study, it was possible to observe an increase in the immunostaining for RANK, RANKL, OPG, TLR2 and MyD88 during periapical lesion progression (p <0.05). The increase in Tnfrsf11 expression was different between groups G0 and G42, and G21 and G42 (p = 0.006). However, the expression of Tnfrsf11b was different between the G0 and G7, G7, G21 and G42 groups, and a decrease in expression over time (p <0.001) was observed. Tlr2 was more expressed between the G0 and G42 groups (p = 0.03). And the expression of the Myd88 molecule was statistically significant between the G0 and G7, G21 and G42 groups (p = 0.01). The Tnfrsf11 / Tnfrsf11b ratio increased during the AP progression (p = 0.002). It was also possible to observe a moderate correlation between Myd88 and Rankl (r = 0.42, p = 0.03) and between Myd88 and Tlr2 (r = 0.48, p <0.0001). After the methodologies used and the data analyzed, we conclude that the production of MMP2 and MMP9 was modulated by TLR2 and Myd88 during the AP progression. In addition, we can suggest that there is a positive correlation between the RANK / RANKL / OPG system and the proteins of the innate immune system, TLR2 and MyD88, during bone loss due to bacterial infection of the root canals and subsequent progression of the apical periodontitis. Camundongos knockout Camundongos wild type Lesão periapical MMP2 MMP9 MyD88 OPG RANKL Sistema RANK TLR2 Apical periodontitis Knockout mice MMP2 MMP9 MyD88 OPG system RANK RANKL TLR2 Wild typemice
43	Nouveaux régulateurs de la signalisation TLR2-NF-kB Rossi, Anne-Lise 29 November 2013 (has links) (PDF) L'invasion de l'hôte par un pathogène induit l'activation séquentielle des réponses immunitaires innées et adaptatives. La reconnaissance du pathogène par des récepteurs tels que les récepteurs de type Toll (TLRs) initie la réponse innée qui repose sur l'activation des lignées myéloïdes, la production de cytokines, de chémokines et de médiateurs pro-inflammatoires qui contribuent à l'éradication du pathogène. L'amplification incontrôlée de la réaction inflammatoire est délétère pour l'organisme. Afin de mieux comprendre les mécanismes de régulation des réponses dépendant de TLR2, récepteur impliqué dans la reconnaissance de bactéries, parasites ou champignons, nous avons étudié la composition des complexes multimoléculaires d'activation au sein des radeaux lipidiques. En utilisant des approches protéomiques complémentaires, nous avons mis en évidence le rôle de la Src kinase Lyn et de la déshydrogénase IMPDHII après engagement des hétérodimères TLR2/TLR1 ou TLR2/TLR6. La tyrosine kinase Lyn est indispensable à l'activation de NF-kB après engagement de TLR2 et agit en phosphorylant la sous-unité p110 de la PI3-kinase (PI3-K). IMPDHII, cible de l'acide mycophénolique, est un régulateur négatif de la voie TLR2-NF-kB. IMPDHII interagit avec SHP1 pour inhiber la phosphorylation sur tyrosine de p85α, la sous-unité régulatrice de PI3-K, et prévenir la transactivation de NF-kB. Enfin, nous avons étudié le rôle d'un polymorphisme de IMPDHII dans la gravité du choc septique. Ces travaux affinent la compréhension de la régulation de la réponse dépendant de TLR2 et permettent d'identifier de nouvelles cibles thérapeutiques pour la prise en charge des infections graves. Immunité innée TLR2 Phosphorylation des tyrosines Lyn IMPDHII SHP1
44	Estudio de mecanismos de la inmunidad innata en la patogénesis de la leptospirosis Cedola, Maia Tatiana 16 April 2014 (has links) El trabajo de tesis consta de tres bloques: 1) la caracterización de dos proteínas (BatA y BatB) codificadas en el genoma de Leptospira interrogans; 2) el estudio del rol de los neutrófilos durante la infección con Leptospira interrogans, utilizando un modelo de leptospirosis murina experimental; 3) el análisis de la relación entre el polimorfismo Arg753Gln del TLR2 humano y la leptospirosis. modelo animal polimorfismo TLR2 infección inmunidad innata neutrófilos proteínas recombinantes Ciencias Exactas Biología Proteínas Leptospira interrogans Leptospirosis
45	Functional Insights into PRR-Driven SHH Signaling : Implications for Host-Microbial Interactions Naick, Ravindra M January 2015 (has links) (PDF) Mycobacterium are important human pathogens and their strength lies in establishing acute infections, latent infections as well as co-existing with other dreadful infectious agents like HIV. The success of mycobacterium infection often relies in its ability to evade immune-surveillance mechanisms mediated by sentinels of host immunity by modulating host signal transduction pathways and expression of immune regulatory molecules. In this scenario, the role of pattern recognition receptors (PRRs) in orchestrating host immune responses assumes central importance. Of the PRRs, the Toll-like receptors (TLRs) or intracellular surveillance receptors such as retinoic acid-inducible gene 1 (RIG-I)-like receptors (RLRs) govern key immune-surveillance mechanisms in recognition as well as control of mycobacterial or viral infections. The first part of this study illustrates the role of SHH signaling in macrophage induced neutrophil recruitment during mycobacterial infections. The present investigation demonstrates that, in response to mycobacterium infection, macrophages displayed robust activation of TLR2 dependent SHH signaling. By utilizing the well-documented experimental air pouch model, we show that the ability of pathogenic mycobacterium infected macrophages to recruit polymorph nuclear leukocytes (PMNs) like neutrophils to the infected site was dependent on SHH signaling. The activated SHH signaling differentially regulated the expression of proteolytic enzymes, MMP-9 and MMP-12 that would contribute to PMN migration. Interestingly, SHH-responsive krüppel-like family (KLF) of transcription factors, KLF4 and KLF5 were found to modulate these chemokine effectors to regulate neutrophil recruitment. Subsequent chapters describe novel functions of SHH signaling during RIG-I mediated anti-viral immunity and RIG-I mediated modulation of TLR2 anti-inflammatory signature in mycobacteria infected macrophages. In this perspective, we demonstrate that RIG-I ligand robustly induces the activation of SHH signaling via the phosphatidylinositide 3-kinase (PI3K) pathway in macrophages. Furthermore, we show that the sustained inhibition of PKA-GSK-3β-SUFU negative regulatory axis upon RIG-I engagement with 5'3pRNA is critical for the activation of SHH signaling. Gain or loss of function studies implicate the necessity of RIG-I triggered MAVS-TBK1 canonical axis in the inhibition of PKA-GSK-3β-SUFU negative regulatory axis that contributes to SHH signaling activation. The RIG-I activated SHH signaling drives the production of anti-viral type 1 interferons leading to the inhibition Japanese encephalitis virus (JEV) replication. Further, RIG-I-mediated anti-viral type 1 interferon production and subsequent control of viral replication suggested the involvement of two transcriptional factors, IRF3 and YY1 in the response along a SHH axis. Further, mounting evidence clearly depicts a significant cross talk among the molecular events initiated by given TLRs and RLRs like RIG-I. Clearly, these studies present an interesting challenge in delineating the events during polymicrobial infection of host immune cells like macrophages or DCs. Altogether, our results improve our understanding of mycobacteria associated confections’ and may add significantly to the current knowledge of the delicate balance that determines a successful mycobacterial infection. Mycobateria tuberculosis Mycobacterial Infections Immune Response - Mycobateria Mycobacteria Pathogenic Mycobacteria SHH Signaling TLR2 Signaling Host-Microbial Interactions Microbiology and Cell Biology
46	Mechanisms of induction of CCL20/MIP3-α in lung epithelial cells by Moraxella catarrhalis Serrano Aybar, Pablo 12 November 2008 (has links) No description available. Cellular Biology Molecular Biology Moraxella catarrhalis TLR4 TLR2 lung epithelial cells CCL20/MIP3-&945 A549 cells
47	SYNTHESIS OF FLUORINATED AND IODINATED CARBOXYETHYLPYRROLE RECEPTOR LIGANDS Zhang, Yu 21 February 2014 (has links) No description available. Biochemistry Analytical Chemistry Organic Chemistry
48	Design and Synthesis of TLR2 and TLR6 Heterodimer Ligands, a Triply Functionalized α-GalCer Derivative for Identifying Proteins Involved in Glycolipid Trafficking, and the Disaccharide of Staphylococcus aureus CP8 Towards a Self-Adjuvanting Vaccine Mata, Sara Mayeth 01 July 2019 (has links) Toll like receptors (TLRs) are found on B cells, macrophages, monocytes, and dendritic cells, and these cells belong to the innate immune system that recognizes antigens and induces multiple cell responses through the release of cytokines. TLR1, TLR2 and TLR6 function as heterodimers, either as TLR1/TLR2 or TLR2/TLR6 to recognize lipopeptides. TLR1/2 dimer activation releases inflammatory cytokines, while TLR2/TLR6 dimer activation releases immunomodulatory cytokines. Based on the size of the binding pocket between TLR2 and TLR6, it was hypothesized that lipopeptides, such as FSL1, could be simplified while keeping overall activity. FSL1 is a lipopeptide first isolated from Mycoplasma salivarum that activates macrophages at picomolar concentrations. It is expected that synthetic lipopeptides mimicking immunostimulatory molecules such as FSL1 will allow development of better ways to stimulate or modulate the immune system. Therefore, novel synthetic TLR2/6 ligands were synthesized replacing the polylysine chain with a polyamine chain showing activation of the immune cells in a manner like FSL1. Natural killer T-cell (NKT) antigens, such as α-galactosylceramide (α-GalCer), are carried through the body by lipid transfer proteins before they interact with the NKT cells. Not all the proteins involved in glycolipid transportation have been characterized. The synthesis of an α-GalCer analogue, termed CD1d-Triceps was designed to help find additional proteins involved in glycolipid trafficking. CD1d-Triceps has three functionalities: the first is the α-GalCer structure, and the other two are on C6 of the sugar: biotin, which helps tag the molecule for its purification, and a photoactive tag that, upon UV light activation, will cross-link with neighboring proteins. Antibiotic-resistant strains of Staphylococcus aureus (SA) are a growing health problem worldwide. Serotype 5 and 8 are the most common SA pathogens. Loading the serotype 5 or 8 disaccharides onto Qβ-particles that are linked to an NKT cell activator yield a vaccine that is expected to trigger adaptive immunity to the disaccharide. Previous similar studies showed production of antibodies with high affinity against Streptococcus pyogenes oligosaccharides in a similar vaccine. immune system NKT cell adjuvant glycolipid synthesis organic chemistry immunology trafficking carbohydrate TLR2 TLR6 ligand Q-β particle Staphylococcus A serotype disaccharide vaccine Physical Sciences and Mathematics
49	Identification of signaling pathways important for Borrelia burgdorferi-elicited IL-10 production by macrophages and their effects on suppressing antigen presenting cell immune responses Chung, Yutein 18 August 2011 (has links) No description available. Immunology Microbiology Borrelia burgdorferi macrophages dendritic cells interleukin 10 IL-10 toll-like receptor 2 TLR2 phagocytosis OspA, PI3-kinase MAP kinase p38 ERK 1/2
50	CHARACTERIZING THE ROLE OF TOLL-LIKE RECEPTOR 2 IN SENSING AND REGULATING HUMAN IMMUNDEFICIENCY VIRUS-1 INFECTION FROM MOTHER-TO-CHILD THROUGH BREAST MILK Henrick, Bethany M. 10 1900 (has links) <p>Breastfeeding from HIV-infected mothers is one of the major sources of pediatric HIV-1 infection; however, an intervention that promotes exclusive breastfeeding has significantly reduced vertical HIV transmission rates and infant mortality. The mechanisms underlying this phenomenon remain unknown; however, have been closely linked to high levels of innate immune factors in breast milk. Indeed, the level of several innate factors in breast milk correlate with protection and/or have direct anti-viral properties <em>in vitro.</em> The innate immune factor, soluble TLR2 (sTLR2) is found in high concentration in breast milk and has previously been investigated for its anti-bacterial properties; however, its anti-viral properties remain poorly understood. Thus, the research presented in this thesis extended our understanding of sTLR2 by characterizing the mechanisms by which sTLR2 inhibited HIV-induced inflammation and infection. Chapter 2 examined the predominant forms of sTLR2 in breast milk from different women, its cellular source, bioavailability and kinetics postpartum. Functionally, we confirmed sTLR2’s anti-bacterial properties and extended to show, for the first time, that sTLR2 directly inhibited HIV infection <em>in vitro.</em> Chapter 3 documented a potential mechanism of sTLR2’s direct inhibition of HIV infection <em>in vitro</em> and, investigated sTLR2 and TLR2 expression in HIV uninfected compared to HIV infected breast milk and breast milk cells, respectively. Chapter 4 investigated the role of TLR2’s recognition of novel HIV pathogen associated molecular patterns (PAMPs), and whether TLR2 expression increased HIV infection and integration. Taken together, we present novel anti-viral functions of sTLR2 by demonstrating that sTLR2 bound to specific HIV PAMPs, which led to significantly decreased HIV-induced inflammation, co-receptor expression, and HIV infection. Furthermore, we demonstrated, for the first time, that TLR2 recognizes specific HIV PAMPs, which led to significantly increased pro-inflammatory cytokine production, co-receptor expression and HIV infection. Thus, sTLR2 and TLR2 represent innate immune factors that might have preventative and therapeutic applications for both infants and adults in the future.<strong><br /> </strong></p> / Doctor of Philosophy (Medical Science) Medical Immunology Virus Diseases Medical Immunology

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