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The Role of the Transcription Factor Ets1 in Melanocyte DevelopmentSaldana Tavares, Amy 23 June 2014 (has links)
Melanocytes, pigment-producing cells, derive from the neural crest (NC), a population of pluripotent cells that arise from the dorsal aspect of the neural tube during embryogenesis. Many genes required for melanocyte development were identified using mouse pigmentation mutants. The deletion of the transcription factor Ets1 in mice results in hypopigmentation; nevertheless, the function of Ets1 in melanocyte development is unknown. The goal of the present study was to establish the temporal requirement and role of Ets1 in murine melanocyte development. In the mouse, Ets1 is widely expressed in developing organs and tissues, including the NC. In the chick cranial NC, Ets1 is required for the expression of Sox10, a transcription factor critical for the development of melanocytes, enteric ganglia, and other NC derivatives.
Using a combination of immunofluorescence and cell survival assays Ets1 was found to be required between embryonic days 10 and 11, when it regulates NC cell and melanocyte precursor (melanoblast) survival. Given the requirement of Ets1 for Sox10 expression in the chick cranial NC, a potential interaction between these genes was investigated. Using genetic crosses, a synergistic genetic interaction between Ets1 and Sox10 in melanocyte development was found. Since Sox10 is essential for enteric ganglia formation, the importance of Ets1 on gut innervation was also examined. In mice, Ets1 deletion led to decreased gut innervation, which was exacerbated by Sox10 heterozygosity.
At the molecular level, Ets1 was found to activate a Sox10 enhancer critical for Sox10 expression in melanoblasts. Furthermore, mutating Ets1 at a site I characterized in the spontaneous variable spotting mouse pigmentation mutant, led to a 2-fold decrease in enhancer activation. Overexpression and knockdown of Ets1 did not affect Sox10 expression; nonetheless, Ets1 knockdown led to a 6-fold upregulation of the transcription factor Sox9, a gene required for melanocyte and chondrocyte development, but which impairs melanocyte development when its expression is prolonged. Together, these results suggest that Ets1 is required early during melanocyte development for NC cell and melanoblast survival, possibly acting upstream of Sox10. The transcription factor Ets1 may also act indirectly in melanocyte fate specification by repressing Sox9 expression, and consequently cartilage fate.
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Dissecting the Genetic Etiology of Lupus at ETS1 LocusLu, Xiaoming 15 December 2017 (has links)
No description available.
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Multiple regulators mediate the transcriptional activities of ERRalpha and its capacity to promote cell invasion / Régulation de l'activité transcriptionnelle de ERRα et de sa capacité à favoriser l'invasion cellulaire par différents complexesZhang, Ling 05 September 2018 (has links)
ERRα est un récepteur nucléaire dont l’activité est controlée par des co-régulateurs transcriptionnels. La forte expression de ERRα dans les cancers est corrélée à un mauvais pronostic. Les mécanismes par lesquels ERRα régule la migration des cellules cancéreuses sont mal compris, tout comme les co-régulateurs impliqués. Nous avons identifié deux enzymes modificatrices d’histone, LSD1 et SET7, agissant comme régulateurs positifs de ERRα.I. ERRα modifie les activités biochimiques de la déméthylase LSD1 vers la déméthylation (activatrice) de H3K9me2. L’activation des cibles de ERRa-LSD1 (identifiées par RNA-Seq) requiert le recrutement de ce complexe aux sites d’initiation de la transcription (TSSs), réalisé par le facteur de transcription NRF1 qui, lui, ne régule pas l’activité enzymatique de LSD1.II. Un autre groupe de cibles de ERRα (identifié par RNA-Seq) est sous le contrôle de l’histone méthyltransférase SET7 qui mono-méthyle H3K4. Le recrutement de SET7 aux TSSs est contrôlé par le facteur de transcription ETS1, qui promeut les interactions entre SET7 et ERRα, conduisant à l’activation de l’expression des gènes en aval.Des analyses par Gene Ontology ont montré que les cibles communes de ERRα/LSD1 et de ERRα/SET7 sont fortement enrichies en termes d’invasion cellulaire. De manière cohérente, la déplétion individuelle de chacun de ces facteurs (et également celle de NRF1 ou ETS1) réduit les capacités d’invasion, observée en tests in vitro (transwell) ou in vivo par xénogreffe sur embryons de poisson-zèbre.En résumé, nos résultats montrent deux réseaux de régulation impliquant des modifications d’histone induites par ERRα, conduisant à l’invasion cellulaire. / ERRα is a nuclear receptor whose activity mainly depends on its interaction with transcription co-regulators. High levels of ERRα are found in various cancer types and correlate with poor prognosis. However, the mechanisms linking ERRα to cancer cell migration as well as the coregulators involved are unclear. In our study, we found two histone-modifying enzymes, LSD1 and SET7, acting as positive regulators of ERRα.I. ERRα impacts the biochemical activities of the LSD1 demethylase. Activation of ERRα -LSD1 targets (identified by RNA-Seq) requires the recruitment of this complex at Transcriptional Start Sites (TSSs), which is achieved by the NRF1 transcription factor. In our study, we have shown several points: NRF1, but not ERRα , is involved in positioning LSD1 to TSS, whereas ERRα , but not NRF1, regulates LSD1 enzymatic activities towards demethylating H3K9me2.II. A distinct group of ERRa target genes (identified by RNA-Seq) is under the control of the histone methyltransferase SET7 which mono-methylates H3K4. Appropriate recruitment of SET7 at TSSs is controlled by the ETS1 transcription factor, promoting the interaction between SET7-ERRa, leading to target gene expression.Gene Ontology analysis revealed that ERRa-LSD1 co-targets, as well as ERRa-SET7 co-targets, are enriched in terms of cell invasion. Consistently, depletion of each of these factors, as well as depletion of NRF1 or ETS1, leads to reduced cell invasion capacities as observed in transwell assays or in vivo, using xenotransplantation in the zebrafish embryo.Altogether, our results show two regulatory networks involving histone modifications induced by nuclear receptors, leading to increased cell invasion.
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ETS1 AND ETS2 ROLE IN RAS ONCOGENIC TRANSFORMATION IN MOUSE EMBRYONIC FIBROBLASTSKabbout, Mohamed Nazih 03 September 2010 (has links)
No description available.
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Impact fonctionnel de l' oncogène TLX3 sur la thymopoïse dans les leucémies aiguës lymphoblastiques T . / Functional impact of the TLX3 oncogene on T-cell development in T-cell acute lymphoblastic leukemiaKazheunikava, Larysa 27 September 2012 (has links)
Les membres de la famille Homeobox jouent un rôle critique dans le développement hématopoïétique normal. L'expression ectopique des gènes Homeobox provoque des désordres dans l'hématopoïèse et le développement de leucémies. L'oncogène TLX3 s'exprime de manière ectopique exclusivement dans les Leucémies Aiguës Lymphoblastiques T (LAL-T), avec un blocage des thymocytes à un stade de différentiation précoce cortical CD4+CD8+ DP. De nombreuses études ont investigué les mécanismes d'action des oncogènes TLX1/3, mais plusieurs questions restent en suspens. Durant ma thèse, j'ai étudié l'impact de l'expression ectopique de l'oncogène TLX3 sur le développement lymphocytaire T et les mécanismes de transformation leucémique associés. L'expression de TLX3 a provoqué le blocage des thymocytes à un stade DN2 avec une immortalisation des clones preleucémiques. Les souris transplantées avec les cellules TLX3 ont développé des tumeurs similaires aux LAL-T. Les analyses de ChIP-Seq et d'expression génique ont identifié un recrutement de TLX3 sur les enhancers spécifiques aux cellules T par le motif de fixation Ets/Runx1. Nos résultats suggèrent que la fixation de TLX3 sur les éléments cis-régulateurs peut contribuer à la transformation maligne des thymocytes en perturbant les réseaux transcriptionnels responsables de l'oncogenèse LAL-T. / It is now well established that members of the homeobox gene family play a critical role in normal hematopoietic cell development and that their unbalanced or ectopic expression can lead to characteristic perturbations in haemopoiesis and the onset of leukaemia. TLX3 expression in human haematologic malignancies is exclusive to T-ALL, where it is almost universally associated with transformation of early cortical CD4+CD8+ DP thymocytes. Multiple studies intensively investigated the mechanisms by which TLX1/3 oncogenes could promote complex tumor development, but many questions remain still unclear. During my thesis I investigated the impact of ectopic TLX3 expression on T cell development, and the initiating mechanisms of T-cell transformation leading to leukemia onset. Forced expression of TLX3 disrupted the thymic develoment at DN2-like stage giving rise to immortalized preleukemic clones. Following the transfer into immunodeficient mice TLX3 preleukemic cells initiated malignant cell transformation resulting into leukemia-like disease. Applying a combination of ChIP sequencing and gene expression profiling, we identified TLX3 recruitment onto T-cell specific enhancers via interaction with Ets1/Runx1 composite motif sites as preferential molecular events in the initial steps of TLX3-induced transformation. Thus our findings suggest that the genome-wide binding properties of TLX3 on cis-regulatory elements may contribute to its ability to promote thymocyte preleukaemic state via perturbation of transcriptional regulatory networks responsible for T-ALL oncogenesis.
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Charakterisierung molekularer und pathogenetischer Mechanismen einer isolierten Brachydaktylie Typ E auf der Grundlage der balancierten Translokation t(8;12)(q13;p11.2)Maaß, Philipp Georg 28 September 2009 (has links)
In dieser Dissertation wurde eine isolierte Brachydaktylie vom Typ E (BDE) untersucht. Grundlage war eine Familie mit autosomal-dominanten Erbgang BDE. Der genetische Hintergrund ist eine balancierte Translokation t(8;12)(q13;p11.2). Der Bruchpunkt auf derivativem Chromosom der(8) liegt 86 kb strangaufwärts des chondrogenetisch essentiellen Kandidatengens PTHLH (Parathyroid hormone like hormone). PTHLH ist für die Differenzierungsrate von proliferativen Chondrozyten verantwortlich. Positiv oder negativ reguliertes Pthlh führen zu einer Dysbalance mit Brachydaktylie-ähnlichen Phänotypen in murinen Tiermodellen. Der Leserahmen des Kaliumkanals KCNB2 auf Chromosom 8 wurde durch die Translokation in Intron 2 getrennt. Chrondrogenetische KCNB2 Funktionen konnten durch in situ Hybridisierungen ausgeschlossen werden. Der Translokationsbruchpunkt auf der(8) liegt in einer in Mammalia hochkonservierten Region und beeinhaltet ein Bindungsmotiv für AP1 Transkriptionsfaktoren. Durch die Translokation befindet sich in unmittelbarer Nähe eine Kernkonsensussequenz für ETS Transkriptionsfaktoren. AP1 und ETS Transkriptionsfaktoren interagieren und wurden auf eine potentielle PTHLH Regulation untersucht. Epigenetische Histonmodifizierungen, charakteristisch für cis-regulatorische Elemente, sowie Reportergenassays mit AP1 und ETS1 Bindungsmotiven zeigten einen Bezug zur PTHLH Regulation. Bindungsassays mit AP1 und ETS1 Transkriptionsfaktoren an den Bruchpunktsequenzen, sowie funktionelle in vitro Experimente mit Chondrozyten verifizierten die Hypothese, dass der Translokationsbruchpunkt strangaufwärts von PTHLH regulatorische Eigenschaften besitzt. Die AP1 und ETS1 Transkriptionsfaktoren regulierten PTHLH positiv in ATDC5 und C28/I2 Chondrozyten. In chondrogeninduzierten Patientenfibroblasten war die PTHLH Expression inhibiert. Die molekulare Pathogenese der BDE wurde durch die bisher unbekannte chondrogene PTHLH Fehlregulation dargestellt. / We studied a 3-generation family with Brachydactyly Type E (BDE) and identified a t(8;12)(q13;p11.2) translocation. We identified PTHLH (Parathyroid hormone like hormone) on chromosome 12p11.2 and the ionchannel KCNB2 on chromosome 8q13 as candidate genes. KCNB2 was disrupted in intron 2, while the chromosome 12 breakpoint is localized 86 kb upstream of PTHLH; only the latter gene is involved in chondrogenesis. The 12p11.2 breakpoint is conserved and features an AP1 binding site 86 kb upstream of PTHLH. Due to the translocation, an ETS binding site from 8q13 resided near the AP1 site. Since both transcription factors interact, we tested if AP1 and ETS1 can activate PTHLH in ATDC5 and C28/I2 chondrocytes. We used the breakpoint sequences of the derivative chromosomes 8 and 12 and the nonaffected chromosome 8 and 12 allele sequences in reporter-gene assays. Reporter-gene constructs containing the der(8) breakpoint revealed activation in murine and human chondrocytes. The enrichment of histone modifications, implicating cis-regulatory effects were investigated in the breakpoint area. We found the enriched histone H3K4me1 modification at the chromosome 12 breakpoint position in murine and human chondrocytes, while affected fibroblasts showed higher H3K4me1 enrichment at the der(8) breakpoint compared to wt(12) allele. Furthermore, the breakpoint sequence bound to AP1 and C-ets-1 in EMSA. Western blotting after PMA-stimulated AP1 and ETS1 activation and overexpression of different AP1 and ETS1 combinations showed activated PTHrP expression in chondrocytes. In chondrogenic induced BDE fibroblasts PTHLH was inhibited, while IHH was upregulated. We suggest that PTHLH was dysregulated by the translocation in BDE chondrocytes. This could lead to BDE. We highlight the impact to characterize genomic breakpoints in detail and demonstrate a novel AP1- and ETS1-directed chondrogenic PTHLH regulation in wild-type chondrocytes and dysregulation in the pathogenesis of BDE.
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Blocage de maturation thymique et aberration des recombinaisons V(D)J : modèle des Leucémies Aigües Lymphoblastiques de la lignée T exprimant les onco-protéines à homéodomaines TLX1 et TLX3 / Thymic maturation arrest and V(D)J illegitime recombinaison TLX1 and TLX3 positive Tcell acute Lymphoblastic leucemia modelDadi, Saida 07 April 2010 (has links)
Le blocage du processus de maturation est un élément central de l’oncogenèse des LAL-Tcomme en témoigne la forte corrélation observée entre le stade d’arrêt de maturation et le type d’oncogène dérégulé. Une meilleure compréhension des mécanismes moléculaires responsables de l’arrêt de différenciation est une piste de choix dans la recherche de thérapie« différenciante ». Les LAL-T qui expriment les oncogènes TLX1/HOX11 et TLX3/HOX11L2correspondent à des lymphoblastes T ayant arrêté leur développement au stade cortical « préalphabeta». A ce stade, les thymocytes expriment une chaine TCRβ mais n’expriment pas la protéine TCRα. Une analyse moléculaire du locus TCRα montre que ce dernier n’est pas réarrangé dans ces LAL-T. Notre hypothèse est que les oncoprotéines TLX1 et TLX3bloquent l’expression et le réarrangement du locus TCRα et ainsi sont directement impliqués dans l’arrêt de la différentiation au stade pré-αβ. La mise en route des réarrangements aulocus TCRα est sous le contrôle d’un élément de régulation de la transcription situé en 3’ dulocus : l’enhancer alpha (Eα) dont l’activation nécessite les facteurs de transcription ETS1,RUNX1 et LEF1. Nous avons montré que l’expression de TLX1/3 réprime l’activité transcriptionnelle de l’enhanceosome Eα, que cette répression est dépendante de l’homéodomaine et qu’elle est spécifique et dose dépendante. De plus, nous avons mis en évidence que cette répression exercée par TLX1/3 est possible par une interaction protéine/protéine mise en évidence par Co-IP avec ETS1. Nous avons montré par EMSA que ETS1recrute TLX1/3 au niveau de Eα et confirmé ces résultats in vivo par la technique de ChIP.Par ailleurs, par une approche fonctionnelle de ‘knockdown’, nous avons utilisé des lentivirus contenant des vecteurs shRNAs de TLX1 et TLX3 afin d’éteindre leur expression dans les lignées cellulaires LAL-T qui l’exprime (respectivement ALL-SIL et DND-41). Ces expériences nous ont permis d’observer qu’au sein de ces lignées LAL-T TLX+, la down-régulation des oncogènes TLX1/3 est accompagnée d’une réactivation de l’Eα, traduite par la présence d’expression de transcrits germinaux du TCRα. L’ensemble de nos résultats suggère que TLX1/3 sont impliqués dans l’inhibition du locus TCRα et, par conséquence dans l’arrêt de différenciation observé dans ces leucémies / Acute lymphoblastic leukemias (ALL) are characterized by multi-step oncogenic processesleading to a cell differentiation arrest. Improved understanding of the underlying molecular mechanisms is a prerequisite for targeted therapeutic approaches. In T lineage ALLs, over expressionof the orphan homeobox factors, TLX1 or TLX3 is associated with a corticalthymic maturation arrest. We demonstrate that both TLX1 and TLX3 proteins interact withETS1, an essential component of the TCRα gene-enhanceosome, resulting in repression ofenhancer activity, blocked TCR-Jα rearrangement, and auto-extinction of clones with a TCRαenhancer driven TLX1-TCRδ chromosomal translocation. Our results identify novel functionsfor homeodomain proteins during T-cell development and imply that TLX1/3 exert an ETS1-dependent block to αβ T-cell maturation in T-ALLs, there fore representing promising targets for differentiation therapy
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RUNX1/AML1 functions and mechanisms regulating granulocyte-macrophage colony-stimulating factor transcriptionLiu, Hebin January 2005 (has links)
Granulocyte-macrophage colony-stimulating factor (GM-CSF) is a multipotent cytokine involved in the production and function of hematopoietic cells, and GM-CSF plays in particular a major role in responses to infection and physiological and pathological inflammatory processes. GM-CSF is produced in many cell types, and increases in the intracellular Ca2+ concentration are, like in many other systems, of major importance in the intracellular signaling that determines GM-CSF expression after receptor stimulation of the cells. Previous studies have shown that the Ca2+/calmodulin-dependent phosphatase calcineurin (CN) mediates stimulation of GM-CSF transcription in response to Ca2+. This thesis shows that Ca2+ signaling also regulates GM-CSF transcription negatively through Ca2+/calmodulin-dependent kinase II (CaMK II) phosphorylation of serines in the autoinhibitory domain for DNA binding of the transcription factor Ets1. Mutation of the CaMK II target serines increased transactivation of the GM-CSF promoter/enhancer and decreased the sensitivity to inhibition by increased Ca2+ or constitutively active CaMK II. The Ca2+-dependent phosphorylation of Ets1 was also shown to reduce the binding of Ets1 to the GM-CSF promoter in vivo. RUNX1, also known as acute myeloid leukemia 1 (AML1), is one of three mammalian RUNX transcription factors and has many essential functions in hematopoiesis. RUNX1 has also many important roles in the immune system, and RUNX1 is the most frequent target for chromosomal translocation of genes in acute human leukemias. This thesis shows that RUNX1 directly interacts with both subunits of CN and that the strongest interaction is localised to the regulatory CN subunit and the DNA binding domain of the RUNX protein. Constitutively active CN was shown to activate the promoter/enhancer of GM-CSF synergistically with RUNX1, RUNX2 or RUNX3, and the Ets1 binding site of the promoter was shown to be essential for the synergy between RUNX1 and CN in Jurkat T cells. The analysis suggests that Ets1 phosphorylated by the protein kinase glycogen synthase kinase-3β is the target of RUNX1-recruited CN phosphatase at the GM-CSF promoter. Transforming growth factor-β (TGF-β) is another multipotent cytokine that often has a role opposite to that of GM-CSF in inflammatory responses since it is a potent suppressor of immune cells and therefore is anti-inflammatory. This thesis shows that TGF-β can decrease transcription from a GM-CSF promoter/enhancer. Certain constitutively active TGF-β receptors and the TGF-β activated transcription factor Smad3 could also repress GM-CSF transcription, whereas several other Smad proteins did not have this inhibitory effect. The inhibition required intact DNA binding ability of Smad3, and the 125 bp upstream of the transcription initiation site, which was sufficient for the inhibition, contains several weak Smad binding sites near the TATA box next to an Ets1 site of the promoter. Smad3 was able to bind to the promoter DNA together with Ets1 and could also be in complex with Ets1 in the absence of DNA. Surface plasmon resonance analysis revealed that Ets1 interacted with the DNA binding domain of Smad3, and the binding constant of this interaction was about 1 µM. The results identify a negative regulation of the GM-CSF promoter by TGF-β signaling through direct Smad3 binding and indicate that the mechanism is by Smad3 interaction with Ets1 and perhaps other proteins around the TATA box of the promoter. This thesis also identifies a novel transactivation domain in the N-terminal of RUNX1 including the N-terminal α-helix in the DNA binding domain. The domain was also required for RUNX2 and RUNX3 transactivation. Despite this, the N-terminal domain of RUNX1 was not essential for RUNX1 function in megakaryocytopoiesis in vitro from mouse embryonic stem cells.
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