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Glycoprotein-NMB and the microphthalmia-associated transcription factor regulatory circuitry in tuberous sclerosis complex associated tumorsProbst, Clemens Kemena 08 June 2020 (has links)
Tuberous sclerosis complex (TSC) is an autosomal dominant genetic syndrome characterized by the growth of benign tumors in multiple organ systems including brain, lung, kidney, skin, and heart. Kidney angiomyolipoma (AML) are benign, slow growing renal tumors that are seen in about 80% of TSC patients, but also occur sporadically. Although heterogeneous in nature, AMLs have a relatively low somatic mutation rate compared to most other cancers, with biallelic loss of either TSC1 or TSC2 gene considered as the primary and sufficient driver for tumor development. We hypothesized that epigenetic alterations of the AML chromatin landscape change the transcriptional dynamics of the underlying genetic system that supports and gives rise to the tumor-cell phenotype. Our data have identified microphthalmia-associated transcription factor (MITF) to be an orchestrating gene in AML development, as 6 out of the top 10 differentially expressed genes in AML are putative MITF-target genes. Integrative analysis of RNA Seq (n=28), H3K27ac ChIP Seq (n=25) and MITF ChIP Seq data (n=3), obtained from fresh-frozen kidney AML specimens, has enabled us to characterize components of a tumor-specific regulatory network under the transcriptional control of MITF. This novel approach has the potential to identify a variety of therapeutic targets, as well as provide unprecedented insight into the mechanisms behind angiomyolipoma development. / 2021-06-07T00:00:00Z
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Epigenetic regulation by estrogen receptor in breast cancer cells / Régulation de l'épigénome par le récepteur des oestrogènes dans le cancer du seinSklias, Athéna 06 September 2019 (has links)
Les travaux épidémiologiques et expérimentaux effectués à ce jour sur le cancer du sein ont montré que les oestrogènes - comme l’eostradiole (E2) - et leur récépteur (ER) - un facteur de transcription les liants - sont fortement impliqués dans au moins 70% des cas de cancer du sein. Cette implication est d’autant plus visible que les patients, suite à une thérapie anti-oestrogénique, ont tendance à développer une résistance endocrinienne au traitement. Pendant longtemps, l’ER a été étudié en tant que facteur indépendant liant directement une séquence ADN spécifique sur le génome. Aujourd’hui le paradigme a profondément changé. Il est bien connu que ER s’associe avec de nombreux autres facteurs de transcription et protéines régulant la chromatine afin de réguler l’expression des gènes. Cependant, nos connaissances concernant la fonction de modifications épigénétiques suite à l’activation de ER - notamment la méthylation de l’ADN et l’acétylation des histones - sont encore limitées. Dans cette étude, j’ai mis en place un protocole de culture cellulaire adapté à l’étude de la privation et à la re-stimulation d’E2 stricto sensu. Dans un premier temps, ce protocole a été évalué à l’aide de la toute dernière technologie de puce permettant la lecture du méthylome et couvrant la liste complète des éléments amplificateurs. Dans un deuxième temps, j’ai mesuré le transcriptome et les profiles d’acétylation de l’histone H3 (H3K27ac) afin de déterminer la capacité de ER à réguler l’expression des gènes J’ai découvert que, suite à la privation de E2, les niveaux de méthylation de l’ADN et de H3K27ac changent et que ces changements s’accentuent avec le temps, en particulier au niveau des éléments amplificateurs. Une analyse d’enrichissement des facteurs de transcription et des séquences de liaison spécifiques a révélé que les facteurs de transcriptions des familles AP-1 et FOX sont des intermédiaires favorisants la liaison de ER aux éléments amplificateurs. Finalement, la re-stimulation des cellules par de l’E2 a montré que la majorité des changements épigénétiques observé sont réversibles mais que certains éléments amplificateurs restent hyperméthylés et déacétylés. Ceci pourrait indiquer que les traitements anti-oestrogéniques sont efficaces mais pourrait également indiquer un marqueur de résistance endocrinienne. Cette étude apporte des informations nouvelles quant aux effets de l’inhibition et l’activation de ER sur la méthylation de l’ADN et l’acétylation de l’histone H3 à l’échelle du génome et renforce l’importance du rôle d’autres facteurs au niveau des amplificateurs / Previous epidemiological and experimental studies have strongly implicated estrogens in breast cancer risk and Estrogen Receptor (ER), the transcription factor to which estrogen binds, is considered as the major molecular driver of around 70% breast cancers. The importance of the deregulated estrogen signalling is further highlighted by increasing evidence that current chemopreventive and therapeutic strategies that target hormonally responsive breast cancers frequently result in the development of resistance to anti-estrogens and metastatic progression, highlighting the need for understanding the molecular underlying mechanisms. While until recently, ER was believed to act as a stand-alone transcription factor, which can directly bind its motifs in DNA, it is now accepted that ER activity is a complex and dynamic process that requires highly concerted actions of a dozen transcriptional cofactors and various chromatin regulators at DNA. Recent studies focused on characterising ER-associated cofactors and their role in opening the chromatin provided a remarkable insight into transcriptional regulation mediated by ER. However DNA methylation and histone acetylation are poorly understood in the context of ER’s dynamic binding. In this thesis, I combined a cell culture protocol adapted for studying estradiol (E2) deprivation and re-stimulation in stricto sensu in ER-positive breast cancer cells with the latest methylation array, that allowed a genome-wide interrogation of DNA methylation (including a comprehensive panel of enhancers). I further investigated histone acetylation (ChIP-seq) and transcriptome (RNA-seq) after E2 deprivation and re-stimulation to better characterise the ability of ER to coordinate gene regulation. I found that E2 deprivation and re-stimulation result in time-dependent DNA methylation changes and in histone acetylation across diverse genomic regions, many of which overlap with enhancers. Further enrichment analysis of transcription factor (TF) binding and motif occurrence highlights the importance of ER tethering mainly through two partner TF families, AP-1 and FOX, in the proximity of enhancers that are differentially methylated and acetylated. This is the first study that comprehensively characterized DNA methylation at enhancers in response to inhibition and activation of ER signalling. The transcriptome and genome occupancy data further reinforced the notion that ER activity may orchestrate a broad transcriptional programme through regulating a limited panel of critical enhancers. Finally, the E2 re-stimulation experiments revealed that although the majority of the observed epigenetic changes induced by E2 deprivation could be largely reversed when the cells were re-stimulated we show that DNA hypermethylation and H3K27 acetylation at enhancers as well as several gene expression changes are selectively retained. The partial reversibility can be interpreted as a sign of treatment efficiency but also as a mechanism by which ER activity may contribute to endocrine resistance. This study provides entirely new information that constitutes a major advance in our understanding of the events by which ER and its cofactors mediate changes in DNA methylation and chromatin states at enhancers. These findings should open new avenues for studying role of the deregulated estrogen signalling in the mechanism underlying the “roots” of endocrine resistance that commonly develops in response to anti-estrogen therapy
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Genome-Wide Identification and Characterization of Stimulus-Responsive Enhancers in the Nervous SystemMalik, Athar Naveed 08 June 2015 (has links)
During development, intrinsic genetic programs give rise to distinct cellular lineages through the establishment of cell type specific chromatin states. These distinct chromatin states instruct gene expression primarily through the genome-wide demarcation of enhancers. In addition to maintaining cellular identity, the chromatin state of a cell provides a platform for transcriptional responses to environmental signals. However, relatively little is known about the influence of extracellular stimuli on chromatin state at enhancers, and it is not clear which enhancers among the tens of thousands that have been recently identified function to drive stimulus-responsive transcription. In the nervous system, the chromatin state of terminally differentiated neurons not only maintains neuronal identity but also provides a platform for sensory experience-dependent gene expression, which plays a critical role in the development and refinement of neural circuits and in long-lasting changes in neuronal function that underlie learning, memory, and behavior. Using chromatin-immunoprecipitation followed by high through put sequencing (ChIP-Seq), we determined the effects of neuronal stimuli on the active chromatin landscape of mouse cortical neurons. We discover that stimulation with neuronal activity and brain derived neurotrophic factor (BDNF) cause rapid, widespread, and distinct changes in the acetylation of histone H3 lysine 27 (H3K27Ac) at thousands of enhancers throughout the neuronal genome. We find that functional stimulus-responsive enhancers can be identified by stimulus- inducible H3K27Ac, and we use this dynamic chromatin signature to discover neuronal enhancers that respond to neuronal activity, BDNF, or both stimuli. Finally, we investigate the transcriptional mechanisms underlying the function of stimulus responsive enhancers. We show that a subset of stimulus-responsive enhancers in the nervous system require the coordinated action of the stimulus-general transcription factor activator protein 1 (AP1) with additional stimulus-specific factors. Our studies reveal the genome-wide basis for transcriptional specificity in response to distinct neuronal stimuli. Furthermore, the comprehensive identification of neuronal activity and BDNF-dependent enhancers in cortical neurons provides a critical resource for elucidating the role of stimulus-responsive transcription in synaptic plasticity, learning and memory, behavior, and disease. Finally, the epigenetic signature of stimulus-inducible H3K27Ac may aid in the identification and study of stimulus- regulated enhancers in other tissues.
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ORGAN-SPECIFIC EPIGENOMIC AND TRANSCRIPTOMIC CHANGES IN RESPONSE TO NITRATE IN TOMATORussell S Julian (8810357) 21 June 2022 (has links)
Nitrogen (N), an essential plant macronutrient, is among the most limiting factors of crop yield. To sustain modern agriculture, N is often amended in soil in the form of chemical N fertilizer, a major anthropogenic contributor to nutrient pollution that affects climate, biodiversity and human health. To achieve agricultural sustainability, a comprehensive understanding of the regulation of N response in plants is required, in order to engineer crops with higher N use efficiency. Recently, epigenetic mechanisms, such as histone modifications, have gained increasing importance as a new layer of regulation of biological processes. However, our understanding of how epigenetic processes regulate N uptake and assimilation is still in its infancy. To fill this knowledge gap, we first performed a meta-analysis that combined functional genomics and network inference approaches to identify a set of N-responsive epigenetic regulators and predict their effects in regulating epigenome and transcriptome during plant N response. Our analysis suggested that histone modifications could serve as a regulatory mechanism underlying the global transcriptomic reprogramming during plant N response. To test this hypothesis, I applied chromatin immunoprecipitation-sequencing (ChIP-Seq) to monitor the genome-wide changes of four histone marks (H3K27ac, H3K4me3, H3K36me3 and H3K27me3) in response to N supply in tomato plants, followed by RNA-Seq to profile the transcriptomic changes. To investigate the organ specificity of histone modifications, I assayed shoots and roots separately. My results suggest that up to two-thirds of differentially expressed genes (DEGs) are modified in at least one of the four histone marks, supporting an integral role of histone modification in regulating N response. I observed a synergistic modification of active histone marks (H3K27ac, H3K4me3 and H3K36me3) at gene loci functionally relevant to N uptake and assimilation. Surprisingly, I uncovered a non-canonical role of H3K27me3, which is conventionally associated with repressed genes, in modulating active gene expression. Interestingly, such regulatory role of H3K27me3 is specifically associated with highly expressed genes or low expressed genes, depending on the organ context. Overall, I revealed the multi-faceted role of histone marks in mediating the plant N response, which will guide breeding and engineering of better crops with higher N use efficiency
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