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T lymphocytes in Wegener's granulomatosis /Giscombe Stephen, Ricardo Antonio, January 1900 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst. / Härtill 6 uppsatser.
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A study of size and compositional heterogeneity of membrane rafts of CD4+ T cellsKennedy, Colleen. January 2008 (has links)
Thesis (M.S.)--Villanova University, 2008. / Biology Dept. Includes bibliographical references.
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Effects of Acute Nutritional Deprivation on Lymphocyte Subsets and Membrane Function in CatsFreitag, Kimberly A. 29 April 1998 (has links)
Identification of patients with suboptimal nutritional status allows for early treatment intervention. Currently, no definitive test of nutritional status exists. Therefore, this study was conducted to identify possible functional indicators of acute nutritional deprivation. The effects of total nutritional deprivation and subsequent refeeding on lymphocyte functions and subpopulations were examined in 23 healthy cats. Peripheral blood samples were analyzed at various times during fasting and refeeding periods. During the fasting period, decreases were observed in leukocyte number (day 4; p < 0.04), lymphocyte number (p < 0.02), CD4+ cells (day 4; p < 0.06), CD4:CD8 ratio (0 hours; p < 0.004), and mitogen stimulated CD4:CD8 ratio (72 hours; p < 0.15) during the fasting period as compared to baseline. Increases were seen in CD4+ cells (day 7; p < 0.09), CD8+ cells (day 7; p < 0.04) and intracellular calcium (day 4; p < 0.02) as compared to baseline. During the refeeding period increases (p < 0.05) were observed in leukocyte number, CD4+ cells, CD8+ cells, lymphocyte proliferation (p < 0.07) and lymphocyte number (p < 0.004) as compared to day 7. These findings suggest that 7 days starvation had immunosuppressive effects on cats which were alleviated during 7 days refeeding. The use of CD4:CD8 ratio in conjunction with intracellular calcium flux may be useful as indices of nutritional status. / Master of Science
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Efeito da lectina ArtinM sobre as células T CD4+ murinas / Effect of lectin ArtinM on murine CD4+ T cellsSilva, Thiago Aparecido da 05 April 2012 (has links)
A lectina ArtinM, extraída de sementes de Artocarpus heterophyllus e caracterizada como um homotetrâmero constituído de subunidades de 16 kDa, tem alta afinidade de ligação a manotriose Man? 1-3 [Man? 1-6] Man, que constitui o core de N-glicanas. ArtinM é dotada de interessantes propriedades biológicas: (1) ativa neutrófilos a partir do reconhecimento de N-glicanas dos receptores CXCR2 e TLR2; (2) induz a desgranulação de mastócitos por interagir com N-glicanas de Fc?R ou com N-glicanas de IgE ligadas a Fc?R; (3) estimula a produção de IL-12, por reconhecer N-glicanas contidas no ectodomínio de TLR2 da superfície de células apresentadoras de antígeno (APCs); (4) exerce atividade imunomoduladora, que direciona o padrão de resposta para o perfil Th1; (5) confere resistência a infecções por patógenos intracelulares, como Paracoccidioides brasiliensis, Leishmania amazonensis e Leishmania major, Neospora caninum e Candida albicans Células T CD4+ participam de funções essenciais do sistema imune; durante o estabelecimento de uma resposta imune, podem ser desenvolvidas subpopulações de células T CD4+ adequadas para gerar respostas eficientes de combate a patógenos, manutenção da tolerância e regulação da imunidade. A ativação das células T CD4+ depende de um primeiro sinal, desencadeado pelo complexo TCR/CD3, e de um segundo sinal, oriundo de moléculas coestimulatórias como CD28. A ativação e expansão de células T CD4+ são limitadas pela ação de moléculas inibitórias, principalmente por CTLA-4. Lectinas podem ativar as células T, sendo a fitohemaglutinina (PHA) e a Concanavalin A (ConA) os exemplos mais conhecidos. Além disso, está bem caracterizado que o alvo de reconhecimento de ConA localiza-se no complexo TCR/CD3. No presente estudo buscou-se caracterizar os efeitos da lectina ArtinM sobre células T CD4+ murinas e investigar os possíveis mecanismos responsáveis pelos efeitos exercidos. Foram avaliados, inicialmente, os efeitos diretos de ArtinM sobre as células T CD4+, no que se refere à produção de citocinas, expressão de moléculas coestimulatórias e inibitórias e indução de diferenciação celular. Passou-se então à identificação de possíveis receptores de superfície reconhecidos por ArtinM e responsáveis pelo desencadeamento da ativação celular. Finalmente, buscou-se apontar moléculas sinalizadoras envolvidas nos efeitos diretos de ArtinM. A primeira evidência da interação direta de ArtinM com células T CD4+ foi proporcionada por aglutinação celular. Uma curva dose-resposta revelou que 5µg/ml foi a melhor concentração para adquirir significativa produção de citocinas Th1 (IL-2 e IFN-?) e Th17 (IL-6 e IL-17A) pelas células T CD4+. O estímulo com a concentração ótima de ArtinM mostrou que após 12 horas de incubação houve um significativo aumento nos níveis de IL-2, IFN-?, IL-6 e IL-17A no sobrenadante celular; persistindo no curso de 48 horas de observação. A secreção concomitante de IFN-? e IL-17A motivou a avaliação, por citometria de fluxo, da ocorrência de dupla marcação intracelular dessas citocinas. O estímulo, por 24 horas, com ArtinM, levou a importante aumento da frequência de células duplo-positivas para IFN-? e IL-17. Uma vez comprovado pelo padrão de citocinas secretadas que ArtinM promove a ativação das células T CD4+, investigou-se a expressão das moléculas CD25 e CTLA-4. ArtinM aumentou a expressão de ambas as moléculas, de maneira dose-dependente. Curiosamente, a detecção tanto de CD28, como de CTLA-4, foi precoce e persistente, diferindo do padrão temporal de expressão proporcionado por outros ativadores de células T CD4+. Com vistas a determinar o mecanismo através do qual ArtinM atua nas células T CD4+, alvos potenciais de reconhecimento foram ensaiados: CD3?, CD3??, CD28, CD45 e CD4. Esses receptores foram selecionados com base em predição de potenciais sítios Nglicosilados. Dessa forma, anticorpos específicos para essas moléculas foram utilizados para analisar a sua capacidade de inibir a atividade de ArtinM de induzir as células T CD4+ a produzir citocinas, como IL-2, IFN-?, IL-6 e IL-17A. Apenas o anticorpo anti-CD3?? foi capaz de impedir a secreção das citocinas induzidas por ArtinM. Além disso, esse anticorpo inibiu a marcação de células T CD4+ por ArtinM biotinilada. Esses dados indicam que ArtinM exerce sua atividade sobre células T CD4+ através do reconhecimento de glicanas na cadeia ? do receptor CD3, não excluindo-se, entretanto, a ocorrência da interação de ArtinM com outras glicoproteínas na superfície de linfócitos T CD4+. Também foi verificado que ArtinM possui alta especificidade por glicanas na superfície dessas células, pois foram necessárias elevadas concentrações de manotriose para inibir em 50% a ligação de ArtinM à superfície das células T CD4+. Através do uso de inibidores específicos para moléculas sinalizadoras, constatou-se que PI3K, PTK, p42/44MAPK, p38MAPK, JNK e PKC estão implicadas na sinalização para a produção das citocinas de perfis Th1 e Th17, induzida por ArtinM. Esse conjunto de resultados indica que ArtinM é um potente e rápido ativador de células T CD4+. A ativação celular induzida por ArtinM está relacionada com a ligação à cadeia ? do receptor CD3 e se associa à alta expressão de moléculas coestimuladoras e inibitórias. Ademais, demonstrou-se que ArtinM promove a diferenciação das células T CD4+ naive em células Th1 e Th17, utilizando moléculas sinalizadoras que são conhecidas como críticas para a indução de citocinas que caracterizam essas subpopulações celulares. / The lectin ArtinM, extracted from seeds of Artocarpus heterophyllus and characterized as a homotetramer consisted of 16 kDa subunits, has high binding affinity to the manotriose Man? 1-3 [Man? 1-6] Man, which is the core of N-glycans. ArtinM is endowed with interesting biological properties: (1) it activates neutrophils through the recognition of Nglycans attached to CXCR2 and TLR2 receptors; (2) induces degranulation of mast cells by interacting with N-glycans of Fc?R or to N-glycans of IgE bound to Fc?R; (3) stimulates the production of IL-12 through the recognition of N-glycans of the TLR2 ectodomain, expressed on the surface of antigen presenting cells (APCs); (4) exerts immunomodulatory activity, which accounts for Th1 immunity (5) confers resistance to intracellular pathogens, such as P. brasiliensis, Leishmania amazonensis and Leishmania major, Neospora caninum e Candida albicans. CD4+ T cells participate in essential functions of the immune system. During the development of an immune response, CD4+ T cells are activated and give origin to subpopulations of cells that are suitable for establishing effective responses to combat pathogens, for tolerance maintenance, and for adequate immuneregulation. The activation of CD4+ T cells depends on a first signal, triggered by the TCR/CD3 complex, and a second signal, provided by costimulatory molecules. The activation and expansion of CD4+ T cells is limited by the action of inhibitory molecules. Lectins may activate T cells, and Phytohemagglutinin (PHA) and Concanavalin A (ConA) are the best know examples. Furthermore, it is well characterized that the target for ConA recognition is localized in the TCR/CD3 complex. The present study was delineated to characterize the effects of the lectin ArtinM on murine CD4+ T cells and to investigate the possible mechanisms accounting for the observed effects. It was investigated the ArtinM direct effects on CD4+ T cells, concerning its ability to induce the production of cytokines, the expression of costimulatory and inhibitory molecules and cell differentiation. In addition, the possible surface receptors recognized by ArtinM and responsible for triggering cell activation were also assessed. Finally, signaling molecules involved in the direct effects of ArtinM were approached. The first evidence of direct interaction of ArtinM with CD4+ T cells was provided by cell agglutination. A dose-response curve has revealed that 5µg/ml was the best ArtinM concentration to achieve significant production of Th1 (IL-2 and IFN-?) and Th17 (IL-6 and IL-17A) cytokines by TCD4+ cells. Stimulus with the optimum ArtinM concentration has showed that after 12 hours incubation there was a significant augmentation of IL-2, IFN-?, IL- 6 and IL-17A levels in the cell supernatant; which has persisted in the course of 48 hours observation. The concomitant secretion of IFN-? and IL-17A led us to evaluate, by flow cytometry, the intracellular expression of these cytokines. After 24 hours stimulation with ArtinM, there was a significant increase in the frequency of cells IFN-?+IL-17+. Once the cytokines detection indicated that CD4+ T cells have been activated by ArtinM, the expression of CD25 and CTLA-4 molecules was assessed. ArtinM increased the expression of both molecules, in a dose-dependent manner. Interestingly, both cell surface molecules, CD25 and CTLA-4, were early and persistently detected a temporal pattern that is distinct from the provided by other inducers of CD4+ T cell activation. In order to determine the mechanism by which ArtinM acts on CD4+ T cells, potential targets of recognition were assessed: CD3??, CD3?, CD28, CD45 and CD4. These receptors were selected on the basis of prediction of N-glycosylation sites. Specific antibodies for these molecules were assayed regarding their ability to inhibit the ArtinM of inducing TCD4+ cells to produce cytokines, such as IL-2, IFN-?, IL-6 and IL-17A. Only anti-CD3 antibody was able to prevent the cytokines secretion induced by ArtinM. In addition, anti-CD3 antibody has inhibited the T CD4+ cell labeling by biotynil-ArtinM. These data indicate that ArtinM exerts its biological activity on T CD4+ cells through recognition of CD3 receptor ? chain glycans, without excluding the occurrence of ArtinM interactions with other glycoproteins on the surface of T CD4+ lymphocytes. The interaction of ArtinM with glycans at the surface of these cells was found to occur with great specificity, since high concentrations of the manotriose - Man? 1-3 [Man? 1-6] Man - were required to inhibit the binding. By using specific inhibitors of signaling molecules, we have found that PI3K, PTK and p42/44MAPK are relevant cytokine production profiles of Th1 and Th17 cells after stimulation with ArtinM. All toghether, these results indicate that ArtinM is a potent and rapid activator of CD4+ T cells. The activation induced by ArtinM is triggered by its binding to the CD3 receptor ? chain, which induces high expression of costimulator and inhibitory molecules. Moreover, it was demonstrated that ArtinM promotes the differentiation of naive CD4+ T cells into Th1 and Th17 cells by committing signaling molecules that are known as critical for the induction of cytokines that characterize these subpopulations of cells.
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Efeito da lectina ArtinM sobre as células T CD4+ murinas / Effect of lectin ArtinM on murine CD4+ T cellsThiago Aparecido da Silva 05 April 2012 (has links)
A lectina ArtinM, extraída de sementes de Artocarpus heterophyllus e caracterizada como um homotetrâmero constituído de subunidades de 16 kDa, tem alta afinidade de ligação a manotriose Man? 1-3 [Man? 1-6] Man, que constitui o core de N-glicanas. ArtinM é dotada de interessantes propriedades biológicas: (1) ativa neutrófilos a partir do reconhecimento de N-glicanas dos receptores CXCR2 e TLR2; (2) induz a desgranulação de mastócitos por interagir com N-glicanas de Fc?R ou com N-glicanas de IgE ligadas a Fc?R; (3) estimula a produção de IL-12, por reconhecer N-glicanas contidas no ectodomínio de TLR2 da superfície de células apresentadoras de antígeno (APCs); (4) exerce atividade imunomoduladora, que direciona o padrão de resposta para o perfil Th1; (5) confere resistência a infecções por patógenos intracelulares, como Paracoccidioides brasiliensis, Leishmania amazonensis e Leishmania major, Neospora caninum e Candida albicans Células T CD4+ participam de funções essenciais do sistema imune; durante o estabelecimento de uma resposta imune, podem ser desenvolvidas subpopulações de células T CD4+ adequadas para gerar respostas eficientes de combate a patógenos, manutenção da tolerância e regulação da imunidade. A ativação das células T CD4+ depende de um primeiro sinal, desencadeado pelo complexo TCR/CD3, e de um segundo sinal, oriundo de moléculas coestimulatórias como CD28. A ativação e expansão de células T CD4+ são limitadas pela ação de moléculas inibitórias, principalmente por CTLA-4. Lectinas podem ativar as células T, sendo a fitohemaglutinina (PHA) e a Concanavalin A (ConA) os exemplos mais conhecidos. Além disso, está bem caracterizado que o alvo de reconhecimento de ConA localiza-se no complexo TCR/CD3. No presente estudo buscou-se caracterizar os efeitos da lectina ArtinM sobre células T CD4+ murinas e investigar os possíveis mecanismos responsáveis pelos efeitos exercidos. Foram avaliados, inicialmente, os efeitos diretos de ArtinM sobre as células T CD4+, no que se refere à produção de citocinas, expressão de moléculas coestimulatórias e inibitórias e indução de diferenciação celular. Passou-se então à identificação de possíveis receptores de superfície reconhecidos por ArtinM e responsáveis pelo desencadeamento da ativação celular. Finalmente, buscou-se apontar moléculas sinalizadoras envolvidas nos efeitos diretos de ArtinM. A primeira evidência da interação direta de ArtinM com células T CD4+ foi proporcionada por aglutinação celular. Uma curva dose-resposta revelou que 5µg/ml foi a melhor concentração para adquirir significativa produção de citocinas Th1 (IL-2 e IFN-?) e Th17 (IL-6 e IL-17A) pelas células T CD4+. O estímulo com a concentração ótima de ArtinM mostrou que após 12 horas de incubação houve um significativo aumento nos níveis de IL-2, IFN-?, IL-6 e IL-17A no sobrenadante celular; persistindo no curso de 48 horas de observação. A secreção concomitante de IFN-? e IL-17A motivou a avaliação, por citometria de fluxo, da ocorrência de dupla marcação intracelular dessas citocinas. O estímulo, por 24 horas, com ArtinM, levou a importante aumento da frequência de células duplo-positivas para IFN-? e IL-17. Uma vez comprovado pelo padrão de citocinas secretadas que ArtinM promove a ativação das células T CD4+, investigou-se a expressão das moléculas CD25 e CTLA-4. ArtinM aumentou a expressão de ambas as moléculas, de maneira dose-dependente. Curiosamente, a detecção tanto de CD28, como de CTLA-4, foi precoce e persistente, diferindo do padrão temporal de expressão proporcionado por outros ativadores de células T CD4+. Com vistas a determinar o mecanismo através do qual ArtinM atua nas células T CD4+, alvos potenciais de reconhecimento foram ensaiados: CD3?, CD3??, CD28, CD45 e CD4. Esses receptores foram selecionados com base em predição de potenciais sítios Nglicosilados. Dessa forma, anticorpos específicos para essas moléculas foram utilizados para analisar a sua capacidade de inibir a atividade de ArtinM de induzir as células T CD4+ a produzir citocinas, como IL-2, IFN-?, IL-6 e IL-17A. Apenas o anticorpo anti-CD3?? foi capaz de impedir a secreção das citocinas induzidas por ArtinM. Além disso, esse anticorpo inibiu a marcação de células T CD4+ por ArtinM biotinilada. Esses dados indicam que ArtinM exerce sua atividade sobre células T CD4+ através do reconhecimento de glicanas na cadeia ? do receptor CD3, não excluindo-se, entretanto, a ocorrência da interação de ArtinM com outras glicoproteínas na superfície de linfócitos T CD4+. Também foi verificado que ArtinM possui alta especificidade por glicanas na superfície dessas células, pois foram necessárias elevadas concentrações de manotriose para inibir em 50% a ligação de ArtinM à superfície das células T CD4+. Através do uso de inibidores específicos para moléculas sinalizadoras, constatou-se que PI3K, PTK, p42/44MAPK, p38MAPK, JNK e PKC estão implicadas na sinalização para a produção das citocinas de perfis Th1 e Th17, induzida por ArtinM. Esse conjunto de resultados indica que ArtinM é um potente e rápido ativador de células T CD4+. A ativação celular induzida por ArtinM está relacionada com a ligação à cadeia ? do receptor CD3 e se associa à alta expressão de moléculas coestimuladoras e inibitórias. Ademais, demonstrou-se que ArtinM promove a diferenciação das células T CD4+ naive em células Th1 e Th17, utilizando moléculas sinalizadoras que são conhecidas como críticas para a indução de citocinas que caracterizam essas subpopulações celulares. / The lectin ArtinM, extracted from seeds of Artocarpus heterophyllus and characterized as a homotetramer consisted of 16 kDa subunits, has high binding affinity to the manotriose Man? 1-3 [Man? 1-6] Man, which is the core of N-glycans. ArtinM is endowed with interesting biological properties: (1) it activates neutrophils through the recognition of Nglycans attached to CXCR2 and TLR2 receptors; (2) induces degranulation of mast cells by interacting with N-glycans of Fc?R or to N-glycans of IgE bound to Fc?R; (3) stimulates the production of IL-12 through the recognition of N-glycans of the TLR2 ectodomain, expressed on the surface of antigen presenting cells (APCs); (4) exerts immunomodulatory activity, which accounts for Th1 immunity (5) confers resistance to intracellular pathogens, such as P. brasiliensis, Leishmania amazonensis and Leishmania major, Neospora caninum e Candida albicans. CD4+ T cells participate in essential functions of the immune system. During the development of an immune response, CD4+ T cells are activated and give origin to subpopulations of cells that are suitable for establishing effective responses to combat pathogens, for tolerance maintenance, and for adequate immuneregulation. The activation of CD4+ T cells depends on a first signal, triggered by the TCR/CD3 complex, and a second signal, provided by costimulatory molecules. The activation and expansion of CD4+ T cells is limited by the action of inhibitory molecules. Lectins may activate T cells, and Phytohemagglutinin (PHA) and Concanavalin A (ConA) are the best know examples. Furthermore, it is well characterized that the target for ConA recognition is localized in the TCR/CD3 complex. The present study was delineated to characterize the effects of the lectin ArtinM on murine CD4+ T cells and to investigate the possible mechanisms accounting for the observed effects. It was investigated the ArtinM direct effects on CD4+ T cells, concerning its ability to induce the production of cytokines, the expression of costimulatory and inhibitory molecules and cell differentiation. In addition, the possible surface receptors recognized by ArtinM and responsible for triggering cell activation were also assessed. Finally, signaling molecules involved in the direct effects of ArtinM were approached. The first evidence of direct interaction of ArtinM with CD4+ T cells was provided by cell agglutination. A dose-response curve has revealed that 5µg/ml was the best ArtinM concentration to achieve significant production of Th1 (IL-2 and IFN-?) and Th17 (IL-6 and IL-17A) cytokines by TCD4+ cells. Stimulus with the optimum ArtinM concentration has showed that after 12 hours incubation there was a significant augmentation of IL-2, IFN-?, IL- 6 and IL-17A levels in the cell supernatant; which has persisted in the course of 48 hours observation. The concomitant secretion of IFN-? and IL-17A led us to evaluate, by flow cytometry, the intracellular expression of these cytokines. After 24 hours stimulation with ArtinM, there was a significant increase in the frequency of cells IFN-?+IL-17+. Once the cytokines detection indicated that CD4+ T cells have been activated by ArtinM, the expression of CD25 and CTLA-4 molecules was assessed. ArtinM increased the expression of both molecules, in a dose-dependent manner. Interestingly, both cell surface molecules, CD25 and CTLA-4, were early and persistently detected a temporal pattern that is distinct from the provided by other inducers of CD4+ T cell activation. In order to determine the mechanism by which ArtinM acts on CD4+ T cells, potential targets of recognition were assessed: CD3??, CD3?, CD28, CD45 and CD4. These receptors were selected on the basis of prediction of N-glycosylation sites. Specific antibodies for these molecules were assayed regarding their ability to inhibit the ArtinM of inducing TCD4+ cells to produce cytokines, such as IL-2, IFN-?, IL-6 and IL-17A. Only anti-CD3 antibody was able to prevent the cytokines secretion induced by ArtinM. In addition, anti-CD3 antibody has inhibited the T CD4+ cell labeling by biotynil-ArtinM. These data indicate that ArtinM exerts its biological activity on T CD4+ cells through recognition of CD3 receptor ? chain glycans, without excluding the occurrence of ArtinM interactions with other glycoproteins on the surface of T CD4+ lymphocytes. The interaction of ArtinM with glycans at the surface of these cells was found to occur with great specificity, since high concentrations of the manotriose - Man? 1-3 [Man? 1-6] Man - were required to inhibit the binding. By using specific inhibitors of signaling molecules, we have found that PI3K, PTK and p42/44MAPK are relevant cytokine production profiles of Th1 and Th17 cells after stimulation with ArtinM. All toghether, these results indicate that ArtinM is a potent and rapid activator of CD4+ T cells. The activation induced by ArtinM is triggered by its binding to the CD3 receptor ? chain, which induces high expression of costimulator and inhibitory molecules. Moreover, it was demonstrated that ArtinM promotes the differentiation of naive CD4+ T cells into Th1 and Th17 cells by committing signaling molecules that are known as critical for the induction of cytokines that characterize these subpopulations of cells.
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Analyse des profils d'expression génique des lymphocytes T CD4+ chez les patientes atteintes d'un cancer du sein/ Gene expression profiles analysis of T CD4+ lymphocytes from breast cancer patientsEqueter, Carole 22 September 2009 (has links)
De nombreux travaux ont démontré la modulation, par les tumeurs, de certaines fonctions des cellules du système immunitaire. Dans le cadre de notre travail, nous avons étudié les lymphocytes T CD4+, cellules clefs de la réponse immune spécifique, chez des patientes atteintes d’un cancer du sein.
Sur base de l’établissement des profils d’expression génique des lymphocytes T infiltrant les tumeurs, nous avons dérivé la « tumor-infiltrating CD4+ signature » (TICD4S) composée de 61 gènes immuns et qui reflète l’état d’activation immunitaire. Cette signature présente une valeur prédictive chez les patientes porteuses de tumeurs ERBB2-positives et ER-négative/PR-négative/ERBB2-négative: une plus forte expression de ces gènes est associée à une meilleure survie.
Nous avons également étudié conjointement les profils géniques établis au départ des lymphocytes T CD4+ de la tumeur, du ganglion axillaire et du sang de dix patientes. Nous avons constaté que ces profils d’expression génique des TIL CD4+ diffèrent selon le statut ER de la tumeur qu’ils infiltrent. Les lymphocytes T ganglionnaires CD4+ subissent également les effets de la masse tumorale et, tout comme les TIL, sont moins activés chez les patientes porteuses de tumeurs ER-négatives. Par contre, les lymphocytes T sanguins semblent subir dans une moindre mesure les effets de la tumeur et peu de différences ont été notées par rapport à leurs homologues isolés chez des donneuses saines.
Notre étude a contribué à la caractérisation des lymphocytes T CD4+ chez les patientes atteintes d’un cancer du sein et offre matière à réflexion pour des investigations futures où davantage de patientes pourraient être incluses et où des analyses pourraient être réalisées également au niveau protéique. Les cellules immunes semblent jouer un rôle dans l’évolution de la pathologie cancéreuse et sont susceptibles d’offrir une valeur prédictive sur l’évolution clinique des patientes porteuses de tumeur ER-négative et ERBB2-positive.
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Mechanisms of CD4+ T cell apoptosis and the role of ethanol as a cofactor in HIV pathogenesisDong, Qing, January 2000 (has links) (PDF)
Thesis (Ph. D.)--University of Kentucky, 2000. / Title from document title page. Document formatted into pages; contains vi, 137 p. : ill. Includes abstract. Includes bibliographical references (p. 108-135).
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Antigen Stability Influences Processing Efficiency and Immunogenicity of Pseudomonas Exotoxin Domain III and OvalbuminJanuary 2020 (has links)
archives@tulane.edu / Effective adaptive immune responses depend on the presentation to CD4+ T cells antigen peptides bound to major histocompatibility complex class II proteins. The structure of an antigen strongly influences its processing within the endolysosome and potentially controls the identity and abundance of peptides that are presented to T cells. The dissertation presented here sought to expand our understanding of how antigen structure and stability influence adaptive immune responses for two model antigens. Pseudomonas exotoxin A domain III (PE-III) functions as an ADP-ribosyltransferase with significant cellular toxicity and has been incorporated into a recombinant immunotoxin for the treatment of cancer. The bacterial component of the PE-III immunotoxin is highly immunogenic and generates neutralizing antibodies that render subsequent treatments ineffective. A group of six single-amino-acid substitutions in PE-III that were predicted to disrupt CD4+ T-cell epitopes have been shown to reduce antibody responses in mice. Here we demonstrate that only one of the substitutions, R494A, exhibits reduced folding stability and proteolytic resistance through the removal of a hydrogen bond. This destabilization significantly reduces its antibody immunogenicity while generating CD4+ T-cell epitopes that are indistinguishable from those of wildtype PE-III. PE-III specific B cells isolated from R494A-immunized animals contained fewer somatic mutations, which are associated with affinity maturation, and exhibited a weaker germinal-center gene signature, compared to B cells from wildtype-immunized animals. Chicken ovalbumin (cOVA) has been studied for decades primarily due to the robust genetic and molecular resources that are available for experimental investigations. cOVA is a member of the serpin superfamily of proteins that function as protease inhibitors, although cOVA does not exhibit this activity. As a serpin, cOVA possess a protease-sensitive reactive center loop that lies adjacent to the OT-II epitope. We took advantage of the previously described single-substitution-variant, OVA R339T, which can undergo the dramatic structural transition observed in serpins to study how changes in loop size and protein stability influences CD4+ T-cell priming in vivo. We observed that OVA R339T loop-insertion increases overall stability and protease resistance and significantly shortens the reactive center loop. This results in reduced CD4+ T-cell priming of the OT-II epitope in SJL mice. These findings have implications for the design of more effective vaccines for the treatment of infectious diseases and cancer as well as the development of more robust CD4+ T-cell epitope prediction tools. / 1 / Daniel Moss
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Late Antigen Regulates the Differentiation of Cytotoxic CD4 T Cells in Influenza InfectionVong, Allen M. 15 December 2017 (has links)
CD4 T cells differentiate into multiple effector subsets that mediate pathogen clearance. ThCTL are anti-viral effectors with MHC-II restricted cytotoxicity. The factors regulating ThCTL generation are unclear, in part due to a lack of a signature marker. I show here that in mice, NKG2C/E identifies ThCTL that develop in the lung during influenza A virus (IAV) infection. ThCTL phenotype indicates they are highly activated effectors with high levels of binding to P-selectin, T-bet, IFNγ production, and degranulation. ThCTL express increased levels of granzymes and perforin and lower levels of genes associated with memory and recirculation compared to non-ThCTL lung effectors. ThCTL are also restricted to the site of infection, the lung in IAV and systemically in LCMV. ThCTL require Blimp-1 for their differentiation, suggesting a unique effector CD4 population. As ThCTL are highly activated, they also require antigen signaling post priming during IAV infection. Late antigen was necessary and sufficient for the differentiation of ThCTL. In the context of late antigen encounter, ThCTL surprisingly do not require CD80 and CD86 costimulation for their differentiation. Additionally ThCTL do not require late IL-2 for their differentiation and instead require late IL-15 signals for their efficient generation. Thus these data suggest ThCTL are marked by the expression of NKG2C/E and represent a unique CD4 effector population specialized for cytotoxicity.
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Mémoire lymphocytaire T et persistance virale / T Memory lymphocyte and viral persistenceJaafoura, Salma 11 December 2014 (has links)
Au cours d’une réponse immunitaire primaire, les lymphocytes T CD8 mémoires émergent à partir d'un environnement de forte activation immunitaire. Les cellules régulatrices T CD4 FoxP3+ (LTregs) jouent un rôle clé de suppression de la réponse immunitaire. Nous montrons que les LTregs sont nécessaires pour la génération d’une réponse mémoire T CD8 fonctionnelle. En absence de LTregs lors du priming, les LT CD8 mémoires générées prolifèrent faiblement et ne parviennent pas à se différencier après une réactivation antigénique en effecteurs cytotoxiques secondaires fonctionnelles. Nous suggérons que les LTregs agissent tôt, lors de la phase d'expansion des LT CD8, en réduisant l’exposition des précurseurs mémoires T CD8 à l'interleukine-2. Ce nouveau rôle crucial des LTregs a des implications pour le développement optimal de vaccin.Chez les patients sous traitement antirétroviral efficace et prolongée (ART), le VIH peut persister dans un petit pool de cellules T CD4 mémoires quiescentes de longue durée de vie infectées par du virus latent intégré. Ce réservoir latent comprend différentes sous-populations mémoires. Nos résultats suggèrent une contraction progressive de la taille du réservoir latent autour d'un noyau formé de sous-populations T CD4 mémoires moins différenciées (centrales mémoires TCM et souches mémoires TSCM). Ce processus très lent semble dépendre de la taille initiale et du taux de décroissance qui diffère entre les sous-populations mémoires infectées de manière latente. Nos résultats suggèrent également une extrême stabilité du sous-réservoir TSCM, dont la taille est directement liée à l'exposition cumulée au virus plasmatique avant le début du traitement ART, soulignant l'importance d'une initiation précoce du traitement antirétroviral efficace. La présence de cette dynamique intrinsèque dans le réservoir latent peut avoir des implications pour la conception de stratégies optimales de purge thérapeutique contre le VIH. / During the primary immune response, CD8 memory emerges from an environment of strong immune activation. The FoxP3 regulatory CD4 T-cell subset (Treg) is known as a key suppressive component of the immune system. We report that Tregs are required for the generation of functional CD8 memory. In the absence of Tregs during priming, the resulting memory cells proliferate poorly and fail to differentiate into functional cytotoxic secondary effectors following antigen reactivation. We find that the Tregs act early, during the expansion phase of primary CD8 effectors, by fine tuning interleukin-2 exposure of CD8 memory precursors. This crucial new role of Tregs has implications for optimal vaccine development. In patients who are receiving prolonged antiretroviral treatment (ART), HIV can persist within a small pool of long-lived resting memory CD4 T cells infected with integrated latent virus. This latent reservoir involves distinct memory subsets. We provide results that suggest a progressive reduction of the size of the blood latent reservoir around a core of less-differentiated memory subsets (central memory and stem cell-like memory).This process appears to be driven by the differences in initial sizes and decay rates between latently infected memory subsets. Our results also suggest an extreme stability of the TSCM sub-reservoir, the size of which is directly related to cumulative plasma virus exposure before the onset of ART, stressing the importance of early initiation of effective ART. The presence of these intrinsic dynamics within the latent reservoir may have implications for the design of optimal HIV therapeutic purging strategies.
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