Global ETD Search

281	Serotonergic Responsiveness in Hypothalamic Neurons Tung, Stephanie S. Y. 04 December 2012 (has links) Serotonin (5-HT) has been implicated in energy homeostasis. There is growing evidence that 5-HT, acting through the 5-HT1BR in the paraventricular nucleus of the hypothalamus (PVN), is important to this regulation. To investigate the cellular events underlying 5-HT1BR action, a PVN neuronal cell model was established. The mHypoA-2/30 cell line expresses a complement of markers and neuropeptides specifically localized to the PVN. 5-HT induces neuronal activation in a dose-dependent manner as determined by an elevation in cFos mRNA levels. As 5-HT exerted limited transcriptional control, the integrity of 5-HT signaling machinery was assessed. 5-HT signals through cAMP and calcium secondary messenger systems by suppressing cAMP and elevating intracellular calcium, effects that are mimicked by activating the 5-HT1BR and that are attenuated in the presence of inhibitors. These findings support the use of this novel PVN cell model for delineating components involved in direct 5-HT action in PVN neurons. physiology cellular biology molecular biology hypothalamus neuroendocrinology feeding behaviour serotonin neuropeptide expression transcriptional regulation obesity immortalized cell lines signal transduction paraventricular nucleus neuroscience real-time PCR calcium signaling neuronal activation secretion 0379 0307 0317 0719 0570
282	Identification et caractérisation des cibles transcriptionnelles de ETV6, un facteur de transcription impliqué dans la leucémie de l’enfant. Malouf, Camille 02 1900 (has links) La leucémie lymphoblastique aiguë (LLA) est responsable d’environ 25% de l’ensemble des cancers pédiatriques. Chez 85% des enfants diagnostiqués, la LLA entraîne une prolifération massive et incontrôlée de lymphocytes immatures de type précurseurs B dans la moelle osseuse (LLA pré-B). Des avancées intéressantes ont été faites au cours des trente dernières années et ont mené à une augmentation de l’efficacité des traitements thérapeutiques. Plus de 80% des enfants atteints de LLA seront guéris de cette maladie. Malheureusement, ces traitements manquent de spécificité à cause du manque de connaissances sur les mécanismes moléculaires impliqués durant l’initiation et le développement de la LLA pré-B pédiatrique. En d’autres termes, nous connaissons peu de chose sur l’étiologie de cette maladie. Plus de 25% des enfants atteints de la LLA pré-B présentent la translocation chromosomique t(12;21)(p13;q22) qui implique les gènes ETV6 et AML1. Celle-ci est formée in utero et mène à l’expression de la protéine chimère transcriptionnelle ETV6-AML1, dont la présence seule ne suffit pas au développement de la LLA pré-B. Ainsi, d’autres événements génétiques sont nécessaires au développement de cette leucémie. La délétion de l’allèle résiduel de ETV6 est un événement génétique fréquemment rencontré au moment du diagnostic de la LLA pré-B t(12;21)+. Cette délétion entraîne l’inactivation complète de ETV6 dans les lymphocytes pré-B leucémiques. ETV6 est un répresseur transcriptionnel de la famille Ets. Mon hypothèse de recherche est que ETV6 agit comme gène suppresseur de tumeur dans la LLA pré-B pédiatrique. L’inactivation de ETV6 causerait une dérégulation de l’expression de ses cibles transcriptionnelles et, par le fait même, favoriserait l’initiation et le déroulement de la leucémogenèse pédiatrique. Dans le cadre de mon projet, comme peu de cibles transcriptionnelles de ETV6 sont connues, j’ai effectué des expériences d’immunoprécipitation de la chromatine et des essais luciférases qui ont permis d’identifier six nouvelles cibles transcriptionnelles: TP53 (p53 et Δ133p53), SPHK1, IL-18, PTGER4 et LUM. J’ai démontré que la régulation transcriptionnelle médiée par ETV6 requiert la présence de ses deux domaines fonctionnels: PNT (interactions protéiques) et ETS (liaison à l’ADN). Ces domaines favorisent la reconnaissance d’un site EBS consensus dans une région située près du promoteur de base. Ce mécanisme peut dépendre du promoteur régulé par ETV6, mais également du contexte cellulaire. Des études fonctionnelles réalisées sur des lymphocytes pré-B leucémiques ont permis de mesurer l’impact de la dérégulation de l’expression des cibles transcriptionnelles de ETV6 sur trois voies biologiques: la prolifération cellulaire, l’apoptose induite par un stress génotoxique et la migration cellulaire dirigée par la voie de signalisation CXCL12/CXCR4. Ceci a permis de démontrer l’implication des gènes SPHK1, IL-18 et PTGER4 durant la leucémogenèse pédiatrique. Cette étude est une des premières à suggérer le rôle de ETV6 comme gène suppresseur de tumeur dans la LLA pré-B pédiatrique. Suite à l’inactivation du répresseur transcriptionnel ETV6, l’augmentation de l’expression de ses cibles transcriptionnelles favoriserait la prolifération et la survie des lymphocytes pré-B leucémiques dans la moelle osseuse. L’identification de nouveaux gènes impliqués dans le développement de la LLA pré-B pédiatrique ouvre la porte au développement de nouveaux traitements thérapeutiques qui pourront présenter une meilleure spécificité envers l’étiologie de la maladie. / Acute lymphoblastic leukemia (ALL) accounts for approximately 25% of all paediatric cancers. Approximately 85% of ALL cases happen in immature B precursors lymphocytes (pre-B ALL). Pre-B ALL is a sporadic cancer that leads to the massive proliferation of leukemia pre-B lymphocytes in the bone marrow. During the past 30 years, the scientific community has developed efficient therapeutic treatments against paediatric ALL, reaching more than 80% cure rate. However, these treatments lack specificity because of the lack of knowledge regarding the molecular mechanisms involved in the initiation and progression of paediatric pre-B ALL. In other words, we know little about the aetiology of this disease. Approximately 25% of children affected with pre-B ALL carry the chromosomal translocation t(12;21)(p13;q22) involving the ETV6 and AML1 genes. This translocation originates in utero and leads to the expression of the transcriptional chimera ETV6-AML1, which alone is insufficient to trigger the development of pre-B ALL. Therefore, other genetic events would be required to initiate paediatric leukemogenesis. The deletion of the residual allele of ETV6 is frequently observed at the diagnosis of pre-B ALL t(12;21)+. This leads to the complete inactivation of ETV6 in leukemia pre-B lymphocytes. ETV6 is a transcriptional repressor of the Ets family. My research hypothesis is that ETV6 acts as a tumour suppressor gene in paediatric pre-B ALL. The inactivation of ETV6 would lead to the deregulated expression of its transcriptional targets and, consequently, would favour the initiation and progression of paediatric leukemogenesis. Given the fact that only very few ETV6 transcriptional targets are known, I initially performed chromatin immunoprecipitation experiments and luciferase assays that enabled the identification of six novel transcriptional targets: TP53 (p53 and Δ133p53), SPHK1, IL-18, PTGER4 and LUM. The ETV6-mediated transcriptional regulation involves both functional domains: PNT (protein interactions) and ETS (DNA-binding domain). These functional domains facilitate the recognition of consensus EBS sites located in a region close to the basal promoter, a molecular mechanism used according to the target promoter and cellular context. Functional studies using leukemia pre-B lymphocytes were useful to understand the role of the ETV6 transcriptional targets during cell proliferation, induction of apoptosis and cell migration through the CXC12/CXCR4 signalling pathway. These functional studies showed the implication of SPHK1, IL-18 and PTGER4 genes during paediatric leukemogenesis. This study is one of the first to support the role of ETV6 as a tumour suppressor gene in paediatric pre-B ALL. Once ETV6 is inactivated, the increased expression of its transcriptional targets favours the proliferation and survival of leukemia pre-B lymphocytes in the bone marrow. The identification of new genes involved in the development of paediatric pre-B ALL opens new doors to the development of therapeutic treatments with a better specificity toward the aetiology of the disease. cancer pédiatrique leucémie lymphoblastique aiguë oncogenèse facteur de transcription ETV6 régulation transcriptionnelle études fonctionnelles paediatric cancer acute lymphoblastic leukemia oncogenesis ETV6 transcription factor transcriptional regulation functional studies
283	Régulation de l’expression de HYAL-1 par le récepteur de l’oestrogène alpha Edjekouane, Lydia 12 1900 (has links) HYAL-1 (hyaluronidase-1) appartient à la famille des hyaluronidases connues pour leur rôle dans la dégradation de l’acide hyaluronique. L’expression de HYAL-1 est élevée dans de nombreux type de cancers, notamment dans le cancer de la prostate, de la vessie, des reins et du sein où il est impliqué dans la croissance tumorale et les métastases. Récemment notre laboratoire a aussi démontré une expression élevée de HYAL-1 dans le cancer épithélial de l’ovaire (CEO) de type mucineux et à cellules claires, expression qui est inversement corrélée à celle du récepteur de l’oestrogène alpha (REα). Cependant, malgré le fait que le rôle de HYAL-1 dans le cancer soit bien établit, le mécanisme de sa régulation reste encore inconnu. Le REα est un facteur de transcription qui suite à sa liaison avec son ligand va réguler l’expression de plusieurs gènes. Le REα ainsi stimulé par l’hormone va activer la transcription de ces gènes cibles mais il est connu maintenant qu’une grande partie des gènes régulés par le REα sont en réalité réprimés par ce récepteur. Dans ce travail nous proposons d’étudier le mécanisme de la régulation du gène HYAL-1 par le REα dans le CEO à cellules claires et dans le cancer du sein. L’expression ectopique du REα dans la lignée TOV21G (RE-) de même que le traitement de la lignée MCF-7 (RE+) avec de l’oestrogène a induit une diminution du niveau d’expression de l’ARN m de HYAL-1. Ces résultats nous ont permis de confirmer que HYAL-1 est un gène cible du REα. Il est aussi connu que le REα peut exercer son action par différents mécanismes d’action, entre autres en interagissant avec une séquence d’ADN appelée élément de réponse à l’oestrogène (ERE), retrouvé sur le promoteur des gènes cibles ou bien indirectement par des interactions protéine-protéine en se liant à d’autres facteur de transcription tels que Sp1. Après avoir identifiés de telles séquences sur le promoteur proximal de HYAL-1, (1 ERE proximal à -900 pb, 3 distaux à -32350 pb, 48430, -50130 pb du site d’initiation de la transcription) en plus des 2 Sp1 connus (-60 et – 1020pb), nous avons démontrés par immunoprécipitation de la chromatine que le REα est recruté sur le promoteur de HYAL-1 au niveau de l’ERE proximal -900 pb et du distal -32350 pb de même que sur le site Sp1 -1020 pb. De plus, l’activité biologique de l’ERE -900 pb et du ii Sp1-1020pb à été confirmée par des essais de gènes rapporteurs à la luciférase. Avec son rôle connu dans la tumorigenèse, l’identification de HYAL-1 comme gène cible du REα pourrait être une avenue intéressante pour le traitement des cancers hormono-indépendants. / HYAL-1 (hyaluronidase-1) belongs to the hyaluronidase family of enzymes that degrade hyaluronic acid. HYAL-1 expression is elevated in many types of cancers including prostate, bladder, liver and breast cancer where it is involved in tumor growth and metastasis. In accordance to these observations, our group has also demonstrated high expression of HYAL-1 in clear cell and mucinous epithelial ovarian cancer (EOC) subtypes which was inversely correlated to that of estrogen receptor alpha (ERα). However, despite the fact that the role of HYAL-1 in cancer is well established, the mechanism of its regulation is still unknown. ERα is a transcriptional factor that regulates target-gene expression following ligand binding. Upon hormone stimulation, activated ERα will upregulate transcription of many target genes. However, it has been recently well documented that a large number of ERα responsive genes are in fact repressed. In this work we propose to study the mechanism by which ERα regulates HYAL-1 expression in clear cell EOC subtype as well as in breast cancer. The ectopic expression of ERα in TOV21G cell line (ERα -) and estrogen treatment of MCF-7 cells (ERα +) decreased HYAL-1 mRNA expression and allowed us to confirm that HYAL-1 is an ERα target gene. It is also known that ERα may exert its action through different mechanisms of action including interacting with a DNA sequence called estrogen response element (ERE) found in the promoter of target genes or indirectly by protein-protein interactions by binding to other transcription factor such as Sp1. Having identified such sequences in the proximal promoter of HYAL-1, (one proximal ERE -900 bp, 3 distals at -32350, -48430, -50130 bp from the start site of transcription) in addition to the two known Sp1 (-60 and -1020pb), we have demonstrated by chromatin immunoprecipitation that ERα is recruited at the HYAL-1 promoter at the ERE sites -900 pb and -32350 pb as well as at the Sp1 site -1020. Furthermore, the biological activity of the proximal ERE -900 and Sp1 -1020 sites were further confirmed by luciferase reporter gene assay. Given its known role in tumorigenesis, identification of HYAL-1 as an ERα target may provide an interesting approach for the treatment of hormono-independent cancer. Hyaluronidase-1 Récepteur de l’oestrogène alpha Régulation transcriptionnelle Répression de gènes Hyaluronidase-1 Estrogen receptor alpha clear cell epithelial ovarian cancer Transcriptional regulation Gene repression
284	Pou5f1 Post-translational Modifications Modulate Gene Expression and Cell Fate Campbell, Pearl 20 December 2012 (has links) Embryonic stem cells (ESCs) are characterized by their unlimited capacity for self-renewal and the ability to contribute to every lineage of the developing embryo. The promoters of developmentally regulated loci within these cells are marked by coincident epigenetic modifications of gene activation and repression, termed bivalent domains. Trithorax group (TrxG) and Polycomb Group (PcG) proteins respectively place these epigenetic marks on chromatin and extensively colocalize with Oct4 in ESCs. Although it appears that these cells are poised and ready for differentiation, the switch that permits this transition is critically held in check. The derepression of bivalent domains upon knockdown of Oct4 or PcG underscores their respective roles in maintaining the pluripotent state through epigenetic regulation of chromatin structure. The mechanisms that facilitate the recruitment and retention of Oct4, TrxG, and PcG proteins at developmentally regulated loci to maintain the pluripotent state, however, remain unknown. Oct4 may function as either a transcriptional activator or repressor. Prevailing thought holds that both of these activities are required to maintain the pluripotent state through activation of genes implicated in pluripotency and cell-cycle control with concomitant repression of genes required for differentiation and lineage-specific differentiation. More recent evidence however, suggests that the activator function of Oct4 may play a more critical role in maintaining the pluripotent state (Hammachi et al., 2012). The purpose of the studies described in this dissertation was to clarify the underlying mechanisms by which Oct4 functions in transcriptional activation and repression. By so doing, we wished to contextualize its role in pluripotent cells, and to provide insight into how changes in Oct4 function might account for its ability to facilitate cell fate transitions. As a result of our studies we find that Oct4 function is dependent upon post-translational modifications (PTMs). We find through a combination of experimental approaches, including genome-wide microarray analysis, bioinformatics, chromatin immunoprecipitation, functional molecular, and biochemical analyses, that in the pluripotent state Oct4, Akt, and Hmgb2 participate in a regulatory feedback loop. Akt-mediated phosphorylation of Oct4 facilitates interaction with PcG recruiter Hmgb2. Consequently, Hmgb2 functions as a context dependent modulator of Akt and Oct4 function, promoting transcriptional poise at Oct4 bound loci. Sumoylation of Oct4 is then required to maintain Hmgb2 enrichment at repressed loci and to transmit the H3K27me3 mark in daughter progeny. The expression of Oct4 phosphorylation mutants however, leads to Akt inactivation and initiates the DNA Damage Checkpoint response. Our results suggest that this may subsequently facilitate chromatin reorganization and cell fate transitions. In summary, our results suggest that controlled modulation of Oct4, Akt, and Hmgb2 function is required to maintain pluripotency and for the faithful induction of transcriptional programs required for lineage specific differentiation. Oct4 pluripotency stem cells Akt Polycomb Group Proteins Trithorax Group Proteins transcriptional regulation transcriptional regulatory network cancer cell cycle checkpoint function cell fate transitions cell cycle SET complex Hmgb2 post-translational modifications Pou5f1 Signal Transduction embryonic stem cells Set
285	Functional Genetic Analysis Reveals Intricate Roles of Conserved X-box Elements in Yeast Transcriptional Regulation Voll, Sarah 13 November 2013 (has links) Understanding the functional impact of physical interactions between proteins and DNA on gene expression is important for developing approaches to correct disease-associated gene dysregulation. I conducted a systematic, functional genetic analysis of protein-DNA interactions in the promoter region of the yeast ribonucleotide reductase subunit gene RNR3. I measured the transcriptional impact of systematically perturbing the major transcriptional regulator, Crt1, and three X-box sites on the DNA known to physically bind Crt1. This analysis revealed interactions between two of the three X-boxes in the presence of Crt1, and unexpectedly, a significant functional role of the X-boxes in the absence of Crt1. Further analysis revealed Crt1- independent regulators of RNR3 that were impacted by X-box perturbation. Taken together, these results support the notion that higher-order X-box-mediated interactions are important for RNR3 transcription, and that the X-boxes have unexpected roles in the regulation of RNR3 transcription that extend beyond their interaction with Crt1. functional genetic analysis transcription factor (TF) cis-regulatory element (CRE) binary interaction higher order interaction multiple linear regression additive multiplicative synthetic genetic array (SGA) green fluorescent protein (GFP) ribonucleotide reductase (RNR) yeast X-box transcriptional regulation RNR3
286	Expression variation in lysosomal storage disorder genes Mason, Lyndel Ann January 2006 (has links) Metachromatic leukodystrophy (MLD) and Gaucher disease (GD) are caused by a deficiency of arylsulphatase A (ASA) and b-glucocerebrosidase (GBA), respectively. They are lysosomal storage disorders with a heterogeneous clinical spectrum encompassing visceral, skeletal and neurologic involvement resulting in high morbidity and mortality. The overall aim of this study is to elucidate the genetic component/s of high ASA and GBA enzyme activity in normal healthy individuals with the ultimate goal of using this information to produce greater protein activity from a recombinant protein. A wide variation in ASA and GBA enzyme activity levels has been observed in the normal population. The first objective of this project was to identify and characterise single nucleotide polymorphisms (SNPs) in the arylsulphatase A (ARSA) and glucocerebrosidase (GBA) genes that are responsible for determining the levels of expressed enzyme activity in the normal population. The second objective was to assess the contribution of transcriptional regulation and TCP80 mediated translational control to normal enzyme variation. TCP80, a translational control protein that interacts with the GBA coding region, is a splice variant of the interleukin binding factor 3 (ILF3) gene. Ten samples from individuals with high ASA activity and twenty samples from individuals with high GBA activity were screened for polymorphisms via denaturing high pressure liquid chromatography (dHPLC) and sequencing. The frequency of these polymorphisms in the normal population was determined using dot-blot hybridisation. Fifteen ARSA polymorphisms (4 promoter, 5 coding, 5 intronic and 1 poly(A) signal) and two GBA polymorphisms (1 intronic and 1 in 3¢-UTR) were identified. Two low frequency ASA polymorphisms (2723A > G, W193C) were found to be correlated with low activity, while another low frequency ASA polymorphism (1101+123C > T) was found to be correlated with high activity in a population of 113 individuals. Real time PCR was used to measure mRNA levels of GBA, ASA and LF3 along with enzyme activity levels of GBA and ASA in two cell types (leucocytes and skin fibroblasts) from four healthy individuals and seven cell lines (HL60, THP1, Huh7, U118, SW1353, Hep G2, and B-cells). Transcriptional control was evident for all three genes with GBA mRNA levels varying over 30 fold, ASA mRNA levels varying over seven fold and ILF3 levels varying more than 24 fold. The 5¢-flanking region of GBA was investigated for the cis-elements responsible for tissue-specific expression. However, it was not possible to demonstrate that the cis-element region was influencing GBA expression. Translational efficiency was measured using the magnitude of the mRNA:enzyme activity ratio as an indicator. GBA translational inefficiency was most pronounced in B cells which require four times more mRNA molecules than hepatocytes (Hep G2) and over 25 times more mRNA molecules than chondrocytes (SW1353) to produce one unit of GBA enzyme activity. Except in B-cells, GBA translational efficiency appears to increase as ILF3 mRNA levels decrease. The tissue-specific variation observed in the protein levels of the ILF3 splice variants, TCP80 and DRBP76, may play a role. The correlation of several low frequency SNPs with low ASA enzyme activity or high ASA activity indicates a role in determining the distribution of enzyme activity levels in the normal population. However, there do not appear to be any common high activity polymorphisms. Knowledge of the exact mechanisms responsible for the observed transcriptional and translational control of these lysosomal genes will greatly enhance the understanding of genotype-phenotype correlation and the contribution of genetic variants to natural variation. gaucher disease GD glucocerebrosidase gene GBA glucocerebrosidase GBA metachromatic leucodystrophy MLD arylsulphatase A gene ARSA arylsulphatase A ASA single nucleotide polymorphism SNP polymerase chain reaction PCR promoter transcriptional regulation translational regulation lysosomal storage disorders LSDs
287	Identification et caractérisation des cibles transcriptionnelles de ETV6, un facteur de transcription impliqué dans la leucémie de l’enfant Malouf, Camille 02 1900 (has links) No description available. cancer pédiatrique leucémie lymphoblastique aiguë oncogenèse facteur de transcription ETV6 régulation transcriptionnelle études fonctionnelles paediatric cancer acute lymphoblastic leukemia oncogenesis ETV6 transcription factor transcriptional regulation functional studies
288	Impact des altérations du récepteur des androgènes sur les voies de signalisation liées à la différenciation cellulaire et à la progression du cancer de la prostate / Impact of constitutively active androgen receptor variants on prostate cancer progression Cottard, Félicie 22 September 2015 (has links) La voie de signalisation du récepteur des androgènes (RA) est la principale cible thérapeutique des cancers de la prostate métastatiques. Toutefois, l'émergence de variants constitutivement actifs du RA dépourvus de leur partie C-terminale conduit à une résistance au traitement. Pendant ma thèse, j'ai montré que les variants du RA induisent une transition épithélio-mésenchymateuse (EMT) partielle, un phénomène observé lors de la progression tumorale. J'ai ensuite étudié les mécanismes conduisant à cette expression différentielle de marqueurs de l’EMT en me focalisant sur la N-cadhérine (CDH2). Le RA entier (AR-FL) et les variants du RA interagissent tous les deux au niveau des éléments de réponse aux androgènes dans l'intron1 de CDH2. Cependant, une augmentation du niveau d’acétylation des histones est observée uniquement avec les variants du RA. Mes données nous mène à un modèle où l'AR-FL réprimerait l'expression de CDH2 alors que les variants du RA induiraient son expression. / Androgen receptor (AR) pathway is the main therapeutic target for metastatic prostate cancer (Pca).However, the expression of AR variants lacking the carboxy-terminal end lowers therapy efficacy. During myphD, I showed that AR variants induce a partial epithelial-mesenchymal transition (EMT), a phenomenon observed during tumor progression. To understand the mode of action of AR variants, I explored the mechanisms leading to this differential expression of EMT markers focusing my research on N-cadherin(CDH2). While both the full length AR (AR-FL) and AR variants could interact with androgen response elements present in intron 1 of CDH2, I highlighted that they had opposite effects concerning histone modifications. Indeed, increased histone acetylation in this genomic region was observed only in the presence of AR variants. My data lead us to propose a model in which AR-FL represses CDH2 gene, while AR variants favor its expression. Cancer de la prostate N-cadhérine Régulation transcriptionnelle Prostate cancer (Pca) Epithelial-Mesenchymal Transition (EMT) N-cadherin Transcriptional regulation 572.8 615.7 616.99
289	Caracterização do envolvimento do gene RECKna proliferação celular e progressão tumoral: inversa correlação com a expressão do oncogene c-myc / Characterisation of the involvement of the RECK gene on cell proliferation and tumor progression: inverse correlation with the oncogene expression c-myc Sheila Maria Brochado Winnischofer 24 May 2005 (has links) Este trabalho mostra o envolvimento do gene RECK no processo de progressão do ciclo celular. Foi verificado que a expressão endógena de RECK é modulada durante a progressão do ciclo celular. A superexpressão de RECK em fibroblastos normais de camundongo promove uma diminuição da capacidade proliferativa das células e um retardo da transição das fases G0/G1-S do ciclo celular. Além disso, os resultados sugerem que um dos possíveis mecanismos de ação de RECK, que promovem este processo, envolve a indução da expressão de um inibidor de CDK, especificamente de p21, e retardo da fosforilação de pRb. Os resultados indicam, ainda, que durante a progressão do ciclo celular a expressão do gene RECK apresenta uma correlação inversa com a expressão do proto-oncogene c-myc. Estes dados corroboram os dados da literatura que mostram RECK como um alvo para o produto de diversos oncogenes, como ras e c-myc. A caracterização da repressão de RECK por c-Myc mostrou que a mesma ocorre ao nível transcricional e que sítios Sp1, presentes no promotor de RECK, são essenciais para a ação de Myc. Dados adicionais sugerem que a repressão de RECK por c-Myc parece envolver mecanismos de desacetilação de histonas. A modulação da expressão de RECK também foi avaliada durante a progressão maligna de tumores do sistema nervoso central (especificamente, gliomas). Foi verificado que a expressão de RECK não é alterada com a progressão deste tipo de tumor. Porém, foi verificado que os pacientes que manifestaram um maior tempo de sobrevida apresentaram tumores com uma significativa maior expressão do gene RECK. Estes dados sugerem que RECK possa ser um possível marcador prognóstico. A caracterização da regulação da expressão de RECK, tanto em células normais como em diferentes tipos de tumores, assim como os alvos moleculares da sua ação, são pontos muito importantes para o entendimento dos mecanismos que controlam a proliferação celular e podem contribuir para o desenvolvimento de novas formas de terapia anti-tumoral. / This work shows, for the fIrst time, the involvement of the RECK gene in cell cycle progression. Our data shows that the RECK gene product regulates cell cycle progression by altering the G1 to S transition. Also, we show that RECK is able to induce p21 expression and, consequently, lead to hypophosphorylation of the Rb protein, revealing at least one molecular mechanism through which RECK modulates the cell cycle progression. It has been described that induction of the c-Myc transcription factor promotes cell proliferation and cell transformation by regulating several genes that are involved in cell cycle progression. Here, we show that activation of a Mycestrogen receptor fusion protein with 4-hydroxytamoxifen in mouse fibroblasts was suffIcient to repress the expression of the RECK gene, by acting at the RECK promoter region. In addition, we show that Myc-responsiveness seems to be mediated by the upstream Sp1 sites and to be dependent on cromatin remodelling mechanisms. RECK gene expression was aIso evaluated during human glioma progression. Our results indicate that RECK gene expression is not altered during glioma progresslOn, but a correlation was found between the abundance of RECK expression in gliomas and patient survival. The levels of RECK expression can be considered a good prognostic indicator for glioma patients. Better understanding of RECK gene regulation may contribute to uncover the mechanisms of cell cycle and tumor progression, and to the development of new strategies for cancer prevention and therapeutic intervention. Carcinoma Expressão Gênica Fator de transcrição Sp1 Gene supressor de metástase RECK Oncogene Myc Proliferação celular Regulação transcricional Carcinoma Cell proliferation Gene Expression Gene RECK metastasis suppressor Oncogene Myc Transcription factor Sp1 Transcriptional regulation
290	Transcription par les récepteurs des estrogènes : identification d’un gène cible et d’un nouveau corépresseur Edjekouane, Lydia 12 1900 (has links) Malgré de nombreux progrès réalisés dans les traitements des cancers gynécologiques, ceux-ci demeurent la principale cause de mortalité due au cancer chez la femme. Les instabilités chromosomiques et génomiques au niveau du locus 3p21.3 sont des événements fréquents liés à des cancers épithéliaux, notamment les cancers du sein et de l'ovaire. C’est dans cette région que se trouvent les gènes hyaluronidases HYAL-1, HYAL-2 et HYAL-3. HYAL-1 est particulièrement surexprimé dans plusieurs cancers, notamment, le cancer de la prostate, la vessie, le cou, la tête et le sein où il est impliqué dans la progression tumorale et les métastases. Nous avons démontré que dans le locus 3p21.3, HYAL-1 est un gène cible sélectivement réprimé par ERα et l’estrogène. L’analyse de la cohorte METABRIC a révélé une corrélation inverse significative entre l’expression du gène HYAL-1 et ERα. Nous avons identifié des sites de liaison pour ERα au niveau du locus 3p21.3, parmi eux, un ERE proximal était responsable de la répression de HYAL-1 par ERα en plus d’un site Sp-1 requis pour atteindre une répression optimale. Cette répression de HYAL-1 est accompagnée par un enrichissement de la marque répressive H3K27me3 au niveau des deux sites ERE et Sp-1. En plus de réguler l’expression de nombreux gènes, l’activité transcriptionnelle des ERs est aussi régulée par les corégulateurs qui sont recrutés sur les ERs. Nous avons identifié un nouveau partenaire d’interaction inattendu pour les ERs, soit le facteur de transcription hématopoïétique TAL1. Malgré sa réputation d’oncogène dans les leucémies lymphoblastiques aiguës des cellules T, ce facteur de transcription est un corépresseur d’ERα, dû à son effet répresseur direct sur l’activité transcriptionnelle du récepteur en réponse à l’estrogène et donc sur l’expression de ces gènes cible dans le cancer du sein. De plus, TAL1 réprime aussi l’activation d’ERα en réponse à la phosphorylation induite par la voie des MAPK/Erk. Cette répression d’ERα par TAL1 résulte en une diminution de la prolifération et la migration des cellules cancéreuses mammaires. / Despite many advances in treatment of gynecological cancers, they remain the leading cause of cancer death in women. Chromosomal and genome instabilities at the 3p21.3 locus are frequent events related to epithelial cancers, including breast and ovarian cancers. It is in this region that the hyaluronidase HYAL-1, HYAL-2 and HYAL-3 genes are found. HYAL-1 is particularly overexpressed in several cancers, including prostate, bladder, neck, head and breast cancers where it promotes tumor progression and metastasis. We demonstrate here, that in the 3p21.3 locus, HYAL-1 is a target gene selectively repressed by ERα and estrogen. Integrative data mining using METABRIC dataset revealed a significant inverse correlation between ERα and HYAL-1 gene expression in human breast tumors. We identified binding sites for ERα at the 3p21.3 locus, among which a proximal ERE responsible for repression of HYAL-1 by ERα, in addition to an Sp-1 site required to achieve optimal repression. This repression of HYAL-1 is accompanied by an enrichment of the repressive mark H3K27me3 at the two sites ERE and Sp-1. In addition to regulate the expression of many target genes, the transcriptional activity of estrogen receptors is also regulated by coregulators who are recruited on ERs. We identified a new unexpected interaction partner for ERs, the hematopoietic transcription factor TAL1. Despite its reputation as an oncogene in T-cell acute lymphoblastic leukemia, this transcription factor is an ERα-corepressor due to its direct repressive effect on the transcriptional activity of the receptor in response to estrogen and thus to expression of its target genes in breast cancer. Moreover, TAL1 also inhibits ERs activation in response to phosphorylation induced by the MAPK/Erk pathway. This repression of ERα by TAL1 results in decreased growth and migration of mammary cancer cells. Récepteurs des estrogènes ER Estrogène Hyaluronidase-1 HYAL-1 Gène cible Répression Locus 3p21.3 TAL1 Corépresseur Régulation Estrogen receptors Estrogen Hyaluronidase-1 HYAL-1 Target gene 3p21.3 locus Corepressor Transcriptional regulation Breast cancer

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