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Transcriptional control of innate memory CD8+ T cellsIstaces, Nicolas 25 November 2019 (has links) (PDF)
CD8+ T cells are essential for host protection against intracellular pathogens and tumors. During antigen-driven responses, CD8+ T cell fate is governed by transcriptional and epigenetic processes that allow naïve CD8+ T cells to develop into a wide range of effector and conventional memory cell subsets. Over the last decades, novel techniques and major efforts led to a better understanding of the origin, nature, and short- and long-term effects of these processes on individual CD8+ T cells. Under certain conditions, naïve CD8+ T cells can acquire memory phenotype and functions in an antigen-independent manner. Although homeostatic cytokines and initial activation pathways that drive the development of these unconventional memory cells had been identified, the ensuing transcriptional profile of these cells and their degree of similarity with conventional memory cells remained ill-defined. The epigenetic events that accompany unconventional memory formation were also not known.Here, we show that innate memory cells, a type of thymic unconventional memory cells, are transcriptionally close to conventional memory cells but only partially epigenetically programmed toward the full memory fate. We also show that the sole overexpression of the transcription factor Eomesodermin (EOMES), a master regulator of effector and conventional memory cells, is able to drive many of the phenotypical, functional, transcriptional, and epigenetic features of innate memory cells, and to induce the recruitment of BRG1, a member of chromatin remodeling complexes, to innate memory gene regulatory regions. We further show that the in vivo interleukine-4-dependent development of innate memory cells is largely dependent on BRG1. We bring to light that, in innate memory cells, EOMES is recruited in many instances to genomic regions previously bound by the transcription factor RUNX3. Overall, we provide insights into the mechanisms that allow memory cell formation and T cell receptor stimulation to be uncoupled. / Doctorat en Sciences médicales (Médecine) / info:eu-repo/semantics/nonPublished
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Alterações genéticas e epigenéticas em meningiomas na população paraenseBASTOS, Carlos Eduardo Matos Carvalho 17 July 2013 (has links)
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Previous issue date: 2013 / CNPq - Conselho Nacional de Desenvolvimento Científico e Tecnológico / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / FAPESPA - Fundação Amazônia de Amparo a Estudos e Pesquisas / Os meningiomas são os tumores intracranianos mais frequentes, originando-se das meninges que revestem o cérebro e cordão espinhal. Apesar de terem sido um dos primeiros neoplasmas sólidos estudados citogeneticamente, ainda são escassos os estudos genéticos e epigenéticos nesses tumores. O presente trabalho teve como objetivo investigar alterações genéticas e epigenéticas que pudessem contribuir na iniciação e progressão tumoral em meningiomas na população paraense. Essa tese está subdivida em três capítulos. No Capítulo I foi investigada a associação entre o polimorfismo MTHFR C677T e meningioma em 23 pacientes da população paraense, utilizando 96 indivíduos sem histórico de lesões pré-neoplásicas como grupo controle. Essa associação não foi encontrada, apesar de sugerir um aumento não estatisticamente significante no risco de desenvolver meningioma em portadores do genótipo TT quando comparados ao genótipo CC. No Capítulo II foi avaliado o padrão de metilação em duas famílias do microRNA124 em meningiomas na população paraense. Hipermetilação na região promotora de miRN124a2 e miRNA124a3 parece ser um evento frequente, uma vez que foi encontrada em 73,9% e 69,56% das amostras analisadas, respectivamente. No Capítulo III, foi analisado o padrão de metilação dos genes APC, BRCA1, CDH1, CDH13, CDKN2A, DAPK1, ESR1, FHIT, GSTP1, MGMT, MLH1, NEUROG1, PDLIM4, PTEN, RARB, RASSF1, RUNX3, SOCS1, TIMP3, TP73, VHL e WIF1 em um meningioma de grau I e um de grau II através de uma placa comercial desenvolvida através da tecnologia MethylScreen. O padrão de metilação do gene CDKN2B também foi analisado na amostra coletada em 25 pacientes com meningioma através da conversão por bissulfito, PCR e sequenciamento direto. O gene RASSF1A apresentou-se metilado em 16,73% e 63,66% dos sítios CpGs analisados na amostra de meningioma de grau I e grau II, respectivamente. O gene RUNX3 se apresentou metilado apenas na amostra de grau II em 52,88% dos sítios CpG analisados. Nossos resultados apontam a importância das alterações epigenéticas na tumorigênese e progressão tumoral em meningiomas. / Meningiomas are the most common intracranial tumors that originate from the meninges surrounding the brain and spinal cord. Despite meningiomas were among the first solid neoplasms to be studied cytogenetically, little is known about their genetic and epigenetic profile. This study aimed to investigate genetic and epigenetic alterations that could contribute to tumor initiation and progression in meningiomas in the population of Pará, Brazil. This thesis is subdivided into three chapters. In Chapter I we investigated the association between the MTHFR C677T and meningioma in 23 patients in the population of Pará. A total of 96 healthy individuals with no previous pre-neoplastic lesions were selected for the control group. This association was not found. Although not statistically significant, our observation suggests that the TT genotype increases the risk of developing meningioma when compared to CC genotype. In Chapter II we evaluated the methylation pattern in two members of microRNA124 family in meningiomas in the population of Pará. Hypermethylation of the promoter region of miRN124a2 and miRNA124a3 appears to be a frequent event, as was found in 73.9% and 69.56% of the samples, respectively. In Chapter III, we analyzed the methylation pattern of the APC, BRCA1, CDH1, CDH13, CDKN2A, DAPK1, ESR1, FHIT, GSTP1, MGMT, MLH1, NEUROG1, PDLIM4, PTEN, Rb, RASSF1, RUNX3, SOCS1, TIMP3, TP73, VHL and WIF1 genes in a grade I and in a grade II meningiomas through an assay developed by MethylScreen. Pattern of methylation of CDKN2B was also analyzed in 25 patients with meningioma through bisulfite conversion, PCR and direct sequencing. RASSF1A was methylated in 16.73% and 63.66% of the CpG sites analyzed in the grade I and grade II meningioma, respectively. RUNX3 is methylated only in grade II meningioma in 52.88% of the CpG sites analyzed. Our results point to the importance of epigenetic changes in tumorigenesis and tumor progression in meningiomas.
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Etablierung eines Verfahrens zum Nachweis epigenetischer Biomarker im peripheren Blut zur Stratifizierung der Therapie des Rektumkarzinoms / Fully-automated hypermethylation testing by One-Step-Real-Time-PCR of 6 different potential epigenetic biomarkers in peripheral blood for rectal cancer detection and follow-up.Thormann, Tobias 17 December 2015 (has links)
No description available.
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The role of ThPOK and T cell receptor signaling in CD4+ versus CD8+ T-cell lineage fateZeidan, Nabil 09 1900 (has links)
Les lymphocytes T sont au coeur du système immunitaire adaptatif et leur dérégulation est à la base de pathologies. Les cellules T se développent dans le thymus et passent par de nombreuses étapes de maturations identifiables par l'expression des corécepteurs CD4+/CD8+ à la surface des cellules. À leur sortie du thymus, les cellules T sont divisées en deux sous-types principaux: les cellules T auxiliaires CD4+ spécifique aux antigènes présentés sur complexe majeur d'histocompatibilité (CMH) de classe II et les cellules T cytotoxiques CD8+ reconnaissant un antigène présenté sur un CMH-I. Toutes les cellules T proviennent d’un précurseur commun. Leur différenciation en cellule T CD4+ et T CD8+ est influencée par l'intensité et la durée de la signalisation du récepteur des cellules T (RCT) et des cytokines. Cette signalisation résulte en l’expression des facteurs de transcription ThPOK pour la différenciation de cellule T CD4+ et Runx3 pour les cellules T CD8+. Il a été démontré que ThPOK est à la fois nécessaire et suffisant pour le développement des lymphocytes T CD4+, puisque le gain et la perte de la fonction de ThPOK favorise le développement de cellules lymphocytes T CD4+ et CD8+, respectivement. Ma thèse vise à approfondir notre compréhension du choix de la lignée CD4+/CD8+ en explorant les mécanismes moléculaires de la voix de signalisation de ThPOK et du RCT.
Dans cette étude, nous avons étudié l'impact d'un gain-de-fonction de ThPOK sur la différenciation des thymocytes, en utilisant trois lignées transgéniques exprimant des niveaux variables de ThPOK. Une analyse approfondie de ces transgènes chez des souris dont le RCT est restreint soit au CMH de classe I ou de classe II, a démontré que, comparés aux thymocytes restreints au CMH-II, les thymocytes restreints au CMH-I requéraient des niveaux plus importants de ThPOK pour se différencier en CD4+. L’introduction d’un transgène exprimant un niveau moins élevé de ThPOK comparé aux deux autres transgènes, mais un niveau plus élevé de ThPOK par rapport au niveau endogène dans les cellules CD4+ WT, n'induit qu'une réorientation partielle des cellules T CD8+ en CD4+, ce qui a mené à la génération, à la fois de lymphocytes T CD4+, DN (doubles négatifs) et CD8+ matures. L'analyse génotypique, plus précisément celle des cellules DN chez les souris porteuses du transgène ThPOK et dont le RCT est restreint au CMH-I, a révélé que l’inhibition des gènes spécifiques à la lignée CD8+
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nécessitait des niveaux d'expression différents de ThPOK comparés à ceux requis pour l’induction des gènes spécifiques à la lignée CD4+. En effet, cette étude nous a permis de démontrer que l’intensité du signal dérivé du RCT ainsi que sa spécificité pour un CMH donné jouent un rôle essentiel dans le choix de différentiation CD4+/CD8+ induit par ThPOK. Ainsi, la réorientation CD8+/CD4+ chez les souris exprimant le transgène ThPOK-H est significativement augmentée par l'amplification de l’intensité du signal dérivé du RCT dans les cellules spécifiques aux CMH-I. De plus, la fréquence des cellules CD4+ était plus élevée lorsqu’une quantité identique de ThPOK était exprimée dans des lymphocytes T spécifiques au CMH-II, suggérant qu’il existe un aspect qualitatif quant à la régulation de la différenciation des lymphocytes T CD4+ par la signalisation induite par le RCT.
Nous avons également tenté d’étudier la voie de différenciation CD4+ en l’absence de ThPOK, à la suite de la perturbation physiologique de la voie de signalisation induite par le RCT, par rapport à la perte de fonction de ThPOK. Bien que nous ayons observé une réorientation des thymocytes spécifiques au CMH-II vers la lignée CD8+, aussi bien à la suite d'une délétion de Thpok, qu’à la perturbation de la signalisation RCT les deux modes de redirections semblent toutefois être différents. En effet, notre investigation a démontré qu’en l’absence de ThPOK, la signalisation induite par le RCT dans les cellules restreintes au CHM-II induit l’activation de certains gènes, suggérant ainsi leur implication dans la voie de différenciation CD4+. Ces résultats suggèrent également que la contribution de la signalisation du RTC dans la différenciation des thymocytes restreints au CMH-II ne se limitait pas à l'induction de ThPOK. Étonnamment, seul un effet synergique limité a été observé sur la différenciation des thymocytes restreints au CMH-I, lorsque Gata3, un autre facteur de transcription également induit dans les thymocytes restreints au CMH-II, et ThPOK étaient surexprimés en même temps dans ces cellules, suggérant peu de chevauchement fonctionnel entre ces deux facteurs de transcription. L’ensemble de ces résultats indique que ThPOK et la signalisation induite par le RCT fonctionnent en synergie durant le développement des lymphocytes T CD4+. / T lymphocytes are at the core of the adaptive immune system and their dysfunction is associated with several disorders and pathologies, which are at times fatal. The two main types of T-cells in mice and man are: the major histocompatibility complex (MHC) class-II-restricted CD4+ helper T-cells, and the MHC-I-restricted CD8+ cytotoxic T-cells. Developmental stages of the two types of T-cells occurs in the thymus in multiple sequential maturation stages that are identified by cell-surface CD4+/CD8+ co-receptor expression. Differentiation of the two types of T-cells in the thymus from a common precursor is influenced by the intensity and duration of signals derived from the T-cell receptor (TCR) and cytokines secreted by the thymic stromal cells. These signals lead to the activation of ThPOK or Runx/CBF transcription factors, which control the transcriptional network regulating CD4+ and CD8+ lineage fate, respectively. Studies have demonstrated that ThPOK is both necessary and sufficient for CD4+ T-cell development as gain- and loss-of-ThPOK function redirects positively selected MHC-I- and MHC-II-restricted thymocytes into CD4+ and CD8+ T-cell lineage fate, respectively. However, the role of TCR signaling and the extent to which ThPOK expression influences CD4+ lineage choice remains to be investigated. My thesis aims to elucidate the fundamental basis the CD4+/CD8+ lineage choice by exploring the molecular mechanism of action of ThPOK and TCR signaling in CD4+ lineage fate of MHC-I- and MHC-II-specific thymocytes.
In this study, we have characterized gain-of-function of ThPOK in three independent transgenic mouse lines expressing varying amounts of ThPOK. Extensive analysis of the three ThPOK transgenic lines expressing MHC-I- and MHC-II-specific monoclonal TCR indicated that MHC-I-restricted, compared to MHC-II-restricted, thymocytes required significantly more ThPOK for efficient differentiation into the CD4+ lineage. Interestingly, the founder line with the lowest transgene expression, despite expressing significantly higher amounts of ThPOK compared to the endogenous levels in WT CD4+ T cells, induced a partial CD8+ to CD4+ redirection of MHC-I-restricted cells, leading to the generation of mature CD4+, DN and CD8+ T-cells in the same mouse. Lineage specific gene expression analysis, specifically in DN mature T cells from ThPOK transgenic mice expressing MHC-I-specific TCR, showed that, compared to induction of helper program, suppression of cytotoxic program required lower amount of ThPOK. Further investigation showed that TCR signal strength and MHC specificity of
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developing thymocytes played a critical role in determining ThPOK-induced CD4+ lineage fate. While increase in TCR signal strength augmented the efficiency of ThPOK-induced CD4+ lineage choice of MHC-I-restricted thymocytes in part via endogenous ThPOK induction, it appeared to have ThPOK independent function as well as judged by significantly different CD4+ T-cell frequencies in OTI mice expressing the same amount of ThPOK but transduced quantitatively different TCR signal. Importantly, the efficiency of CD4+ lineage choice of MHC-I-specific thymocytes with augmented TCR signal strength was still significantly lower compared to the efficiency of CD4+ lineage choice of MHC-II-restricted thymocytes expressing only the transgene-encoded ThPOK suggesting a qualitative role for TCR signaling as well in CD4+ lineage choice.
We then evaluated CD4+ lineage fate decision in the absence of ThPOK induction in physiologically relevant alteration in TCR signaling versus loss of ThPOK function. While we observed CD4+ to CD8+ lineage redirection of MHC-II-specific thymocytes due to Thpok-deficiency as well as lack of ThPOK induction due to disruption of TCR signaling, the two modes of lineage redirection appeared to be due to different mechanisms. Our investigation demonstrates that TCR signaling in MHC-II-restricted thymocytes induces the expression of select genes in loss-of-function of ThPOK model suggesting potential role for these genes in establishing the CD4+ helper program. These results also suggest that the contribution of MHC-II-specific TCR signaling in driving CD4+ lineage choice is not limited to Thpok induction. Interestingly, only a limited synergistic effect was observed when both Gata3, which is also induced in MHC-II-signaled thymocytes, and ThPOK were overexpressed in MHC-I-restricted thymocytes suggesting a limited functional overlap between the two transcription factors. Collectively, these data indicate that ThPOK and TCR signaling work synergistically to promote the development of CD4+ T-cells with some ThPOK independent function for TCR signaling.
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