Global ETD Search

21	Transcriptome-Wide Methods for functional and Structural Annotation of Long Non-Coding RNAs Daulatabad, Swapna Vidhur 05 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Non-coding RNAs across the genome have been associated with various biological processes, ranging from regulation of splicing to remodeling of chromatin. Amongst the repertoire of non-coding sequences lies a critical species of RNAs called long non-coding RNAs (lncRNAs). LncRNAs significantly contribute to a large spectrum of human phenotypes, including cancers, Heart failure, Diabetes, and Alzheimer’s disease. This dissertation emphasizes the need to characterize the functional role of lncRNAs to improve our understanding of human diseases. This work consolidates a resource from multiple computational genomics and natural language processing-based approaches to advance our ability to functionally annotate hundreds of lncRNAs and their interactions, providing a one-stop lncRNA functional annotation and dynamic interaction network and multi-facet omics data visualization platform. RNA interactions are vital in various cellular processes, from transcription to RNA processing. These interactions dictate the functional scope of the RNA. However, the multifaceted functional nature of RNA stems from its ability to form secondary structures. Therefore, this work establishes a computational method to characterize RNA secondary structure by integrating SHAPE-seq and long-read sequencing to enhance further our understanding of RNA structure in modulating the post-transcriptional regulatory processes and deciphering the influence at several layers of biological features, ranging from structure composition to consequent protein occupancy. This study will potentially impact the research community by providing methods, web interfaces, and computational pipelines, improving our functional understanding of long non-coding RNAs. This work also provides novel integration methods of technologies like Oxford Nanopore-based long-read sequencing, RNA structure-probing methods, and machine learning. The approaches developed in this dissertation are scalable and adaptable to investigate further the functional and regulatory role of RNA and its structure. Overall, this study accelerates the development of RNA-based diagnostics and the identification of therapeutic targets in human disease. Direct RNA sequencing Lantern Long non-coding RNA Oxford Nanopore long read sequencing RNA structure prediction
22	The aryl hydrocarbon receptor regulates the expression of TIPARP and its cis long non-coding RNA, TIPARP-AS1 Grimaldi, Giulia, Rajendra, S., Matthews, J. 21 December 2017 (has links) Yes / The aryl hydrocarbon receptor (AHR) is a ligand-activated transcription factor and member of the basic helix-loop-helix-PAS family. AHR is activated by numerous dietary and endogenous compounds that contribute to its regulation of genes in diverse signaling pathways including xenobiotic metabolism, vascular development, immune responses and cell cycle control. However, it is most widely studied for its role in mediating 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) toxicity. The AHR target gene and mono-ADP-ribosyltransferase, TCDD-inducible poly-ADP-ribose polymerase (TIPARP), was recently shown to be part of a novel negative feedback loop regulating AHR activity through mono-ADP-ribosylation. However, the molecular characterization of how AHR regulates TIPARP remains elusive. Here we show that activated AHR is recruited to the TIPARP promoter, through its binding to two genomic regions that each contain multiple AHR response elements (AHREs), AHR regulates the expression of both TIPARP but also TIPARP-AS1, a long non-coding RNA (lncRNA) which lies upstream of TIPARP exon 1 and is expressed in the opposite orientation. Reporter gene and deletion studies showed that the distal AHRE cluster predominantly regulated TIPARP expression while the proximal cluster regulated TIPARP-AS1. Moreover, time course and promoter activity assays suggest that TIPARP and TIPARP-AS1 work in concert to regulate AHR signaling. Collectively, these data show an added level of complexity in the AHR signaling cascade which involves lncRNAs, whose functions remain poorly understood. / This work was supported by Canadian Institutes of Health Research (CIHR) operating grants (MOP-494265 and MOP-125919), an unrestricted research grant from the Dow Chemical Company, and the Johan Throne Holst Foundation to J.M. G.G. was supported by European Union Seventh Framework Program (FP7-PEOPLE2013-COFUND) under the Grant Agreement n609020 - Scientia Fellows 2,3,7,8-Tetrachlorodibenzo-p-dioxin Long non-coding RNA Aryl hydrocarbon receptor
23	Post-Transcriptional Control of RIPK1 in Macrophage Inflammation and Necroptosis Zhou, Zier 08 December 2022 (has links) Receptor-interacting protein kinase 1 (RIPK1) is a major upstream mediator of inflammation and cell death. These processes are key to common inflammatory diseases such as atherosclerosis, where macrophages play an important role in their progression. Closely linked to the expression of downstream genes, long non-coding RNAs (lncRNAs) are critical to controlling cellular processes in health and disease. As post-transcriptional regulatory mechanisms for RIPK1 are largely unknown, this project seeks to study the stability of Ripk1 mRNA and RIPK1 protein, along with Ripk1 mRNA interactions with relevant lncRNAs under various conditions. Using transcription and translation inhibitors, we determined that both Ripk1 mRNA and RIPK1 protein are relatively unstable with half-lives of approximately 3 h. Their turnover in macrophages is further influenced by the timing and duration of inflammation. We also implemented a novel RNA pull-down procedure to capture Ripk1 mRNA and attached lncRNAs for next-generation sequencing. Through differential expression analysis, we discovered significant upregulation of known lncRNA AC125611 and novel lncRNA MSTRG.5894.1 in Ripk1-targeted samples subject to inflammation. MSTRG.7477.1 was upregulated during necroptosis, while MSTRG.5684.5 was upregulated during both inflammation and necroptosis. GapmeR-mediated knockdowns of AC125611 and MSTRG.5684.5 under inflammatory conditions resulted in decreased Ripk1 mRNA expression and RIPK1 protein expression, respectively. Meanwhile, MSTRG.7477.1 knockdowns were connected to decreased RIPK1 at both the mRNA and protein levels. Our research ultimately advances the current understanding of RIPK1 regulation by focusing on Ripk1 mRNA-lncRNA associations and turnover of its mRNA and protein in macrophages, paving the way for future investigations into their capacity to act as therapeutic targets. Long non-coding RNA mRNA half-life Protein half-life Gene regulation Macrophages Inflammation Cell death RIPK1
24	Investigation of the mRNP and Transcriptome Regulated by Nonsense-Mediated RNA Decay Smith, Jenna E. 09 February 2015 (has links) No description available. Molecular Biology Biochemistry nonsense-mediated RNA decay NMD mRNP long non-coding RNA lncRNA transcriptome translation
25	Transcript Regulation within the Kcnq1 Domain Korostowski, Lisa January 2012 (has links) Epigenetics was a term first coined to understand how cells with the same genetic make up can differentiate into various cell types. Elegant research over the past 30 years has shown that these mechanisms include heritable marks such as DNA methylation and histone modifications along with stable expression of non- coding RNAs. Within the realm of epigenetics is a phenomenon known as genomic imprinting. Imprints are marks that distinguish the maternal from the paternal chromosomes in the form of methylation. Methylation marks can influence transcript expression, resulting in only one allele being expressed. One imprinted domain is the Kcnq1 domain located on chromosome 11p15.5 in humans and chromosome 7 in the mouse. This domain is thought to be under the control of a paternally expressed long noncoding RNA (ncRNA) Kcnq1ot1. The Kcnq1ot1 ncRNA is expressed on the paternal chromosome due to a differentially methylation region located within its promoter. The promoter is methylated on the maternal allele thus inhibiting ncRNA expression, whereas the promoter is unmethylated on the paternal allele. In the placenta, a most of the genes located within a one mega-basepair region are exclusively expressed from the maternal chromosome, whereas the transcripts on the paternal chromosome are silenced by the ncRNA. The placenta seems to follow the classic idea of an imprinted domain. However, in the embryo and more specifically, in the embryonic heart, this is not the case. In the embryonic heart, only a 400kb region is restricted to maternal expression. In addition, one the genes, Kcnq1, starts out expressed exclusively from the maternal allele in early development but switches to biallelic expression during mid-gestation. The purpose of my research is to determine the underlying complexities that are involved in the regulation of transcripts within the Kcnq1 domain. This involves the Kcnq1 gene itself, which has been shown to transition from mono- to biallelic expression during mid-gestation and the Kcnq1ot1 ncRNA per se. I hypothesize that regulation by the Kcnq1ot1 ncRNA is not occurring in a uniform manner in the embryo; rather, the amount of regulation by the ncRNA is dependent on the developmental stage and specific tissue. In addition, this regulation involves complex interactions between enhancers, insulators and other regulatory elements to control the amount of silencing by the Kcnq1ot1 ncRNA. First, through a series of experiments looking at the Kcnq1 promoter, the mechanism of Kcnq1 paternal expression was determined. It was confirmed that Kcnq1 becomes biallelic during mid-gestation in the heart. Bisulfite mutagenesis and methylation sensitive chromatin immunoprecipitation were used to test the hypothesis that the Kcnq1 promoter was methylated in early development and then lost its methylation mark. However, a lack of methylation disproved this mechanism of paternal Kcnq1 activation. Rather, chromosome conformation capture (3C) determined that the Kcnq1 promoter interacts in a tissue-specific manner with regions within the domain that have enhancer activity. The role of the ncRNA within our system was also investigated. Interestingly, when Kcnq1ot1 allelic expression was profiled throughout development in heart, it transitioned to biallelic expression during heart development but remained monoallelic in the liver and brain. Several possibilities could account for this phenomenon, including loss of promoter methylation and/or an alternative transcript start site. Both of these options were explored using bisulfite mutagenesis and 5' RACE. However, the Kcnq1ot1 promoter region retained its methylation mark even after the maternal transcript was turned on, disproving this idea. Rather, a maternal specific transcript was found in the heart to start downstream of the CpG islands. Lastly, to gain a better understand of the Kcnq1ot1 ncRNA, experiments were carried out on a mutant mouse in which a truncated form of the ncRNA was transmitted paternally; this is dubbed the "Kterm" mouse. Unexpectedly, Kcnq1 still followed the same mono- to biallelic transition as seen in the wild-type, whereas the head and body counterparts from the same stage embryos were biallelic for Kcnq1. Also, the immediate upstream genes, Cdk1nc and Slc22a18, lost their mono-allelic expression in neonatal heart, liver and brain when the Kterm mutation was transmitted. This suggested that Kcnq1ot1 did not function as a silencer for Kcnq1 paternal expression in the heart, but rather had an alternative and previously unknown function. From qRT-PCR, 3C and ChIP assays, it was determined that the Kcnq1ot1 ncRNA plays a role in regulating Kcnq1 gene expression in the heart by limiting its interaction to specific cis-acting enhancers. When the ncRNA was absent, the Kcnq1 promoter interacted with non-native sites along the domain, possibly causing the increase in transcript expression. This phenomenon was specific to the heart and was not seen in other tissues. These findings showed that Kcnq1 paternal expression is the result of strong developmental and tissue specific enhancers. Chromatin interactions in cis put a strong enhancer in contact with the Kcnq1 promoter to increase its expression in later development. In addition, a truncation mutation model identified a key role for the Kcnq1ot1 ncRNA in regulating Kcnq1 expression. Instead of regulating the imprinting status of Kcnq1, the ncRNA regulates the amount of Kcnq1 transcript being produced in the heart by regulating chromatin interactions. Finally, these studies identified a maternally expressed Kcnq1ot1 transcript whose role in heart development is still not fully understood. Taken together, these findings support a model where an inhibitory factor(s) silence the paternal Kcnq1 transcript and maternal Kcnq1ot1 transcript and in later development, this factor is released allowing for expression and chromatin interactions to occur. / Molecular Biology and Genetics Biology, Molecular Genetics Epigenetics Genetics Long Non-coding Rna Biology, Molecular Transcript Regulation
26	New Microfluidic Technologies for Studying Histone Modifications and Long Non-Coding RNA Bindings Hsieh, Yuan-Pang 01 June 2020 (has links) Previous studies have shown that genes can be switched on or off by age, environmental factors, diseases, and lifestyles. The open or compact structures of chromatin is a crucial factor that affects gene expression. Epigenetics refers to hereditary mechanisms that change gene expression and regulations without changing DNA sequences. Epigenetic modifications, such as DNA methylation, histone modification, and non-coding RNA interaction, play critical roles in cell differentiation and disease processes. The conventional approach requires the use of a few million or more cells as starting material. However, such quantity is not available when samples from patients and small lab animals are examined. Microfluidic technology offers advantages to utilize low-input starting material and for high-throughput. In this thesis, I developed novel microfluidic technologies to study epigenomic regulations, including 1) profiling epigenomic changes associated with LPS-induced murine monocytes for immunotherapy, 2) examining cell-type-specific epigenomic changes associated with BRCA1 mutation in breast tissues for breast cancer treatment, and 3) developing a novel microfluidic oscillatory hybridized ChIRP-seq assay to profile genome-wide lncRNA binding for numerous human diseases. We used 20,000 and 50,000 primary cells to study histone modifications in inflammation and breast cancer of BRCA1 mutation, respectively. In the project of whole-genome lncRNA bindings, our microfluidic ChIRP-seq assay, for the first time, allowed us to probe native lncRNA bindings in mouse tissue samples successfully. The technology is a promising approach for scientists to study lncRNA bindings in primary patients. Our works pave the way for low-input and high-throughput epigenomic profiling for precision medicine development. / Doctor of Philosophy / Traditionally, physicians treat patients with a one-size-fits-all approach, in which disease prevention and treatment are designed for the average person. The one-size-fits-all approach fits many patients, but does not work on some. Precision medicine is launched to improve the low efficiency and diminish side effects, and all of these drawbacks are happening in the traditional approaches. The genomic, transcriptomic, and epigenomic data from patients is a valuable resource for developing precision medicine. Conventional approaches in profiling functional epigenomic regulation use tens to hundreds of millions cells per assay, that is why applications in clinical samples are restricted for several decades. Due to the small volume manipulated in microfluidic devices, microfluidic technology exhibits high efficiency in easy operation, reducing the required number of cells, and improving the sensitivity of assays. In order to examine functional epigenomic regulations, we developed novel microfluidic technologies for applications with the small number of cells. We used 20,000 cells from mice to study the epigenomic changes in monocytes. We also used 50,000 cells from patients and mice to study epigenomic changes associated with BRCA1 mutation in different cell types. We developed a novel microfluidic technology for studying lncRNA bindings. We used 100,000-500,000 cells from cell lines and primary tissues to test several lncRNAs. Traditional approaches require 20-100 million cells per assay, and these cells are infected by virus for over-producing specific lncRNA. However, our technology just needs 100,000 cells (non-over-producing state) to study lncRNA bindings. To the best of our knowledge, this is the first allowed us to study native lncRNA bindings in mouse samples successfully. Our efforts in developing microfluidic technologies and studying epigenomic regulations pave the way for precision medicine development. Microfluidics Epigenomics Precision Medicine Chromatin Immunoprecipitation Histone Modification Long Non-coding RNA Interaction Next Generation Sequencing NGS
27	Bedeutung nicht-kodierender RNAs im Immunsystem Hösler, Nadine 26 August 2015 (has links) (PDF) Immer mehr Berichte deuten darauf hin, dass nicht-kodierende RNAs an der Regulation des Immunsystems beteiligt sind. In dieser Arbeit wurden nicht-kodierende RNAs identifiziert, die durch zwei unterschiedliche immunologische Prozesse in zwei verschiedenen Zelltypen reguliert wurden. Zum einen wurde das Transkriptom von Multiplen Myelom-Zellen in Abhängigkeit von der Interleukin 6-Stimulation untersucht. Dabei wurden einige sehr lange, IL 6-regulierte macroRNAs identifiziert, die STAIRs (STAT3-induced RNAs). Bei den STAIRs handelt es sich wahrscheinlich um funktionelle, kontinuierliche, nicht-kodierende macroRNAs, die im Zellkern angereichert sind. Einige STAIRs dienen eventuell zusätzlich oder ausschließlich als Primärtranskript für gespleißte, lange ncRNAs (lncRNAs), die weitere Funktionen in der Zelle ausüben können. Die STAIRs weisen eine große Bandbreite an Gewebsspezifität auf und bei den Untersuchungen in dieser Arbeit zeigten sich Hinweise, dass sie sich für verschiedene Krebserkrankungen als Biomarker eignen könnten. Die zweite Transkriptomanalyse wurde bei der Aktivierung naiver T Zellen durchgeführt. Dabei offenbarte sich, dass die Zellen bei diesem Prozess einen dramatischen Wechsel ihres Transkriptionsprogrammes vollziehen und eine Vielzahl nicht Protein-kodierender Gene reguliert werden. Es wurde die Regulation von ncRNAs, die bisher noch nicht im Zusammenhang mit T Zellen beschrieben wurden, beobachtet und erneut unbekannte, differentiell exprimierte Bereiche identifiziert. Im Anschluss wurde STAIR18, eine nicht-kodierende RNA, die durch die beiden untersuchten Signalwege reguliert wird, eingehender untersucht. Es zeigte sich, dass STAIR18 im menschlichen Genom dupliziert ist und beide Loci die gespleißte, lange ncRNA152 in diversen Varianten transkribieren. ncRNA152 ist hauptsächlich im Zytoplasma lokalisiert und befindet sich dort anscheinend in perinukleären Aggregaten. Die verschiedenen ncRNA152-Isoformen scheinen unter-schiedliche Funktionen auszuführen. Einerseits ist eine Wirkung als competing endogenous RNA wahrscheinlich. Eine weitere Aufgabe der ncRNA152 scheint darin zu bestehen, das STAT3-Primärtranskript zu stabilisieren oder dessen Prozessierung zu fördern. lang nicht-kodierende RNA macroRNA STAT3 STAiR STAiR18 LINC00152 LOC541471 long non-coding RNA STAT3 STAiR STAiR18 LINC00152 LOC541471 ddc:572
28	Les longs ARN non codants, une nouvelle classe de régulateurs génomique tissu-spécifique : signature moléculaire spécifique des neurones dopaminergiques et sérotoninergiques / Long non coding RNA, a new class of tissu-specific genomic regulators : dopaminergic and serotoninergic neurons specific molecular signatures Gendron, Judith 30 October 2017 (has links) Seul 1,2% du génome code des protéines :98,8% est non-codant,cependant 93% du génome est transcrit, principalement en longs ARN non-codants (lncRNA). Or ces lncRNA constituent une nouvelle classe de régulateurs génomique agissant à tous les niveaux d’expression des gènes et ils sont fortement spécifiques du tissu,modulés au cours du temps et en conditions physiopathologiques.Ainsi,nous proposons que chaque cellule spécifiée exprime son répertoire de lncRNA spécifique avec une carte des zones de chromatines ouvertes renseignant son identité cellulaire.Dans cette perspective,nous avons isolé par FACS 2types cellulaires impliqués dans des pathologies: i) des neurones dopaminergiques humains(nDA) différenciés à partir d’hiPS et ii) des neurones DA et sérotoninergiques (n5-HT)murins.Sur ces 2types neuraux isolés,nous avons identifié 1363 lncRNA exprimés dans les nDA (dont 989nouveaux) constituant le répertoire des neurones DA et 1257 lncRNA dans les n5-HT (719nouveaux) constituant le répertoire des n5-HT.Or leur comparaison a montré que seuls 194 lncRNA sont communs aux 2types cellulaires:la majorité des lncRNA est exprimée soit dans les nDA soit dans les n5-HT,attestant leur spécificité cellulaire.De plus,39%des zones de chromatines ouvertes/potentiellement régulatrices des nDA ne sont pas non plus retrouvées dans les n5-HT.Ainsi, nous avons généré un catalogue d’éléments non codants constituant des signatures moléculaires spécifiques des nDA et n5-HT,ouvrant de nouvelles pistes physiopathologiques:Dans cette optique,les signatures non codantes DA ont été comparées avec les SNP associés à la maladie de Parkinson et des études de fonction sur des lncRNA candidats ont été réalisées. / Only 1.2% of the genome codes for proteins; 98.8% is thus non-coding, despite 93% of the human genome being actively transcribed, mostly in long non-coding RNA (lncRNA).These lncRNA constitute a new class of genomic regulator capable of acting at all levels of gene expression and their expression is highly tissue-specific,modulated during the time and under normal/pathological conditions.Thus, we propose that each specified cell expresses a specific repertoire of lncRNA correlated to open/active chromatin regions specifying its cellular identity.In this context, we isolated by FACS 2neural types involved in many pathologies: i) human dopaminergic neurons (nDA) differentiated from hiPS and ii) DA and serotoninergic (n5-HT) neurons. From these 2neural types, we identified 1,363 lncRNA in nDA (among which 989 new, whether 73%) constituting the repertoire of nDA, and 1,257 lncRNA (among which 719 new) constituting the repertoire of n5-HT. Moreover,their comparison has shown that only 194 lncRNA are common to both neural types:thus the majority of lncRNA is expressed either in nDA or in n5-HT, indicating a high degree of cell-specificity.In addition, 39% of open chromatin regions, potentially regulatory, were also not detected in the n5-HT.Thus, we have generated DA and 5-HT specific catalogues of non-coding elements of the genome, which constitute DA and 5-HT specific molecular signatures, that could participate in deepening our knowledge regarding nDA or n5-HT development and dysfunctions. With this in mind,these DA specific elements have been compared with the SNP described as Parkinson Disease risk variants and candidate lncRNA were selected to perform studies of function. Longs ARN non-codants Dopaminergique Sérotoninergique Neurone Régulateurs génomique ADN non-codant Long non-coding RNA Dopaminergic neurons Serotoninergic neurons 573.8
29	Régulation de la télomérase dans un modèle de leucémie aigue promyélocytaire : rôle de l'ARN long non codant H19 / Regulation of telomerase in a model of acute promyelocytic leukemia : role of the long non coding RNA H19 El hajj, Joelle 17 May 2018 (has links) Le couple télomère/télomérase apparaît comme une cible prometteuse pour de potentiels agents anticancéreux qui seraient actifs sur un large éventail de tumeurs. Le laboratoire d’accueil a montré dans un modèle de leucémie aiguë promyélocytaire (LAP), qu'un agent utilisé en clinique, l'acide rétinoïque (ATRA), exerce une activité anti-tumorale en réprimant la transcription de la sous-unité catalytique hTERT indépendamment de la différenciation. Ce modèle (NB4) avec ses variants cellulaires résistant (NB4-LR1SFD) ou non à la répression de hTERT (NB4-LR1) par l’ATRA constitue un outil de choix pour l’identification de facteurs régulateurs de hTERT et la recherche des bases moléculaires de sa réactivation.Une approche transcriptomique a été utilisée afin d’identifier de nouveaux gènes et/ou réseaux de signalisation induits par l’ATRA et régulateurs de hTERT. L’analyse bioinformatique nous a permis de construire des profils d’expression différentielle entre les 2 lignées et des réseaux d’interaction. Parmi les candidats, H19, un ARN long de 2.5Kb, polyadénylé et non codant. H19 est classé parmi les gènes supresseurs de tumeurs : en son absence il y a développement de cancer (cas de la tumeur de Wilms, rhabdomyosarcome embryonnaire, Syndrome Beekwith-Wiedman) ; sa réintroduction par transfection conduit à une perte de tumoriginicité. Cependant H19 est reconnu de plus en plus comme un oncogène vu que son expression est élevée dans plusieurs types de cancers solides. Par contre peu d’études s’intéressent au rôle de H19 dans les leucémies, d’où notre intérêt pour l’étudier dans le modèle LAP que nous avons développé.Nous avons mis au point la mesure d’expression de H19 par RT-PCR quantitative, validé les données obtenues dans l’analyse transcriptomique et montré que le traitement ATRA induit l’expression de H19 dans les cellules NB4-LR1 alors que cette expression est plutôt diminuée dans les cellules NB4-LR1SFD. L’induction observée dans les cellules NB4-LR1 existe indépendamment de la différenciation. Par contre, cette induction peut être observée associée à la différenciation ou à l’apoptose dans la lignée cellulaire NB4-LR1SFD parallèlement à une diminution importante de l’expression de hTERT. Ce résultat important montre que la lignée NB4-LR1SFD ne présente pas de défaut général d’induction de H19. Ces données suggèrent l’existence d’une corrélation inverse entre le niveau d’expression de hTERT et celui de H19 dans ce modèle cellulaire. De façon importante, l’analyse des banques de données issues de patients LAP publiquement accessibles retrouve cette corrélation inverse.Une diminution d’activité télomérasique est observée dans des extraits cellulaires incubés en présence de l’ARN H19 transcrit in vitro. Cette diminution d’activité est observée aussi après surexpression de H19 in cellulo. Les expériences de RIP (RNA immunoprecipitation) ont montré une diminution de la quantité de hTR lié à hTERT suite à une augmentation d’expression de H19 après traitement ATRA in vitro ou après surexpression de H19 in cellulo. Une hypothèse serait que H19 induirait un déplacement de hTR du complexe hTR-hTERT. Cependant, les expériences de « pull-down » n’ont pas réussi à confirmer l’hypothèse d’une interaction possible entre l’ARN H19 et la protéine TERT.Mon travail de thèse identifie pour la première fois H19, un ARN long non codant, comme facteur régulateur potentiel de hTERT pouvant modifier son activité. Ce travail proposerait non seulement un mécanisme nouveau de régulation de l’activité télomérase mais aussi une fonction nouvelle pour H19 dans ce type de cancer. / The telomere / telomerase pair appears to be a promising target for potential anticancer agents that would be active on a wide range of tumors. The host laboratory has shown in a model of acute promyelocytic leukemia (APL), that a clinically used agent, retinoic acid (ATRA), exerts anti-tumor activity by repressing the transcription of the catalytic subunit hTERT regardless of differentiation. This model (NB4) with its resistant cell variants (NB4-LR1SFD) or not to the repression of hTERT (NB4-LR1) by ATRA is a tool of choice for the identification of hTERT regulatory factors and the search for molecular bases of its reactivation.A "microarray" approach has been used to identify new ATRA-mediated genes and / or signaling networks and potential hTERT regulators. Bioinformatic analysis allowed us to build differential expression profiles between the 2 lineages and interaction networks. Among the candidates, H19, a 2.5Kb long, polyadenylated and non-coding RNA. H19 is classified as a tumor suppressor gene: in its absence there is cancer development (case of Wilms tumor, embryonic rhabdomyosarcoma, Beckwith-Wiedman syndrome); its reintroduction by transfection leads to a loss of tumorigenicity. However H19 is increasingly recognized as an oncogene as its expression is elevated in several types of solid cancers. However, few studies are interested in the role of H19 in leukemias, hence our interest in studying it in the APL model that we have developed.We developed the H19 expression measurement by quantitative RT-PCR, validated the data obtained in the "microarray" analysis and showed that the ATRA treatment induces the expression of H19 in NB4-LR1 cells whereas this expression is rather diminished in NB4-LR1SFD cells. The induction observed in NB4-LR1 cells exists independently of differentiation. On the other hand, this induction can be observed associated with the differentiation or apoptosis in the NB4-LR1SFD cell line in parallel with a significant decrease in the expression of hTERT. This important result shows that the NB4-LR1SFD line does not have a general H19 induction defect. These data suggest the existence of an inverse correlation between the expression level of hTERT and that of H19 in this cellular model. Importantly, the analysis of publicly accessible APL patients’ databases finds this inverse correlation as well.We observed a decrease in telomerase activity in cellular extracts incubated in the presence of in vitro transcribed H19 RNA. This decrease in activity was also observed after overexpression of H19 in cellulo. The RIP (RNA immunoprecipitation) experiments showed a decrease in hTR amount bound to hTERT following an increase in H19 expression after ATRA treatment in vitro or after overexpression of H19 in cellulo. We hypothesize that H19 induces a displacement of hTR from the hTR-hTERT complex. However, the "pull-down" experiments failed to confirm the hypothesis of a possible interaction between H19 RNA and TERT protein.My thesis work identifies, for the first time, the long non-coding RNA H19, as a potential regulator of hTERT that can modify its activity. This work would propose not only a new mechanism of regulation of telomerase activity but also a new function for H19 in this type of cancer. Télomerase Régulation ARN long non codant Leucemie aigue promyelocytaire H19 Atra Telomerase Regulation Long non coding RNA Acute promyelocytic leukemia H19 Atra
30	La perturbation du locus Nr2f1-K12 entraine une différenciation gliale précoce dans un nouveau modèle murin de mégacôlon aganglionnaire Nguyen, Chloé My Anh 08 1900 (has links) La maladie de Hirschsprung est une affection congénitale de la motilité intestinale caractérisée par un segment aganglionnaire dans le côlon terminal. Un criblage génétique par mutation insertionnelle aléatoire chez la souris nous a permis d’identifier la lignée transgénique Spot dont les homozygotes souffrent de mégacôlon aganglionnaire. L’analyse d’intestins d’embryons mutants a révélé une baisse de prolifération et un délai de migration des cellules de la crête neurale entériques (CCNe) progénitrices dus à leur différenciation gliale précoce, entrainant un défaut de colonisation de l’intestin et une aganglionose du côlon. Le séquençage du génome Spot indique que le transgène s’est inséré à l’intérieur du locus K12-Nr2f1 sur le chromosome 13, une région dépourvue de gènes préalablement associés à la maladie, perturbant également une séquence non-codante très conservée dans l’évolution. K12 est un gène d’ARN long non codant (ARNlnc) et antisens du gène Nr2f1, lui-même impliqué dans la gliogénèse du système nerveux central. Le séquençage du transcriptome des CCN a montré une surexpression de Nr2f1 et des formes courtes de K12 chez Spot et des essais luciférase ont révélé l’activité répressive de l’élément conservé. Nous avons observé l’expression de K12 dans les CCNe et sa localisation subcellulaire dans des zones transcriptionnellement actives du noyau. Avec l’émergence des ARNlnc régulateurs, ces données nous permettent de pointer deux nouveaux gènes candidats associés à une différenciation gliale prématurée du SNE menant au mégacôlon aganglionnaire, en supposant que la régulation de Nr2f1 se fait par son antisens, K12. / Hirschsprung disease is a congenital intestinal motility disorder characterized by an aganglionic segment in the distal colon. A genetic screen performed via random insertional mutagenesis in mice allowed identifying the Spot line, whose homozygotes suffer from an aganglionic megacolon. The analysis of mutant embryonic intestines revealed a decreased proliferation rate and a delay in migration of the enteric neural crest cell (eNCC) progenitors, secondary to their early glial differentiation, resulting in failure to properly colonize the intestine. Sequencing of the Spot genome indicated that the transgene was inserted into the K12-Nr2f1 locus on chromosome 13, a region devoid of genes associated with the disease, and disrupted in addition a highly conserved non-coding sequence. K12 is an uncharacterized long non-coding RNA (LncRNA) gene antisense to the Nr2f1 gene, which is involved in gliogenesis in the central nervous system. Sequencing of the eNCC transcriptome revealed an overexpression of Nr2f1 and short forms of K12 in Spot, and luciferase assays showed repressive activity of the conserved element. We observed the expression of K12 in the eNCC and its subcellular localization in transcriptionally active zones of the nucleus. With the recent emergence of LncRNA regulators and supposing that the regulation of Nr2f1 is done by its antisense K12, these data allowed us identifying two new candidate genes associated with a premature glial differentiation leading to aganglionic megacolon. ARN long non-codant Génétique Gliogénèse Hirschsprung Système nerveux entérique Souris Enteric nervous system Genetics Gliogenesis Long non-coding RNA Mice

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