191 |
Using Experimental and Computational Strategies to Understand the Biogenesis of microRNAs and piRNAs: A DissertationHan, Bo W. 24 July 2015 (has links)
Small RNAs are single-stranded, 18–36 nucleotide RNAs that can be categorized as miRNA, siRNA, and piRNA. miRNA are expressed ubiquitously in tissues and at particular developmental stages. They fine-tune gene expression by regulating the stability and translation of mRNAs. piRNAs are mainly expressed in the animal gonads and their major function is repressing transposable elements to ensure the faithful transfer of genetic information from generation to generation. My thesis research focused on the biogenesis of miRNAs and piRNAs using both experimental and computational strategies.
The biogenesis of miRNAs involves sequential processing of their precursors by the RNase III enzymes Drosha and Dicer to generate miRNA/miRNA* duplexes, which are subsequently loaded into Argonaute proteins to form the RNA-induced silencing complex (RISC). We discovered that, after assembled into Ago1, more than a quarter of Drosophila miRNAs undergo 3′ end trimming by the 3′-to-5′ exoribonuclease Nibbler. Such trimming occurs after removal of the miRNA* strand from pre-RISC and may be the final step in RISC assembly, ultimately enhancing target messenger RNA repression. Moreover, by developing a specialized Burrow-Wheeler Transform based short reads aligner, we discovered that in the absence of Nibbler a subgroup of miRNAs undergoes increased tailing—non-templated nucleotide addition to their 3′ ends, which are usually associated with miRNA degradation. Therefore, the 3′ trimming by Nibbler might increase miRNA stability by protecting them from degradation.
In Drosophila germ line, piRNAs associate with three PIWI-clade Argonaute proteins, Piwi, Aub, and Ago3. piRNAs bound by Aub and Ago3 are generated by reciprocal cleavages of sense and antisense transposon transcripts (a.k.a., the “Ping-Pong” cycle), which amplifies piRNA abundance and degrades transposon transcripts in the cytoplasm. On the other hand, Piwi and its associated piRNA repress the transcription of transposons in the nucleus. We discovered that Aub- and Ago3-mediated transposon RNA cleavage not only generates piRNAs bound to each other, but also produces substrates for the endonuclease Zucchini, which processively cleaves those substrates in a periodicity of ~26 nt and generates piRNAs that predominantly load into Piwi. Without Aub or Ago3, the abundance of Piwi-bound piRNAs drops and transcriptional silencing is compromised. Our discovery revises the current model of piRNA biogenesis.
|
192 |
Role of post-transcriptional regulation in human liverChaturvedi, Praneet 11 February 2015 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / My thesis comprises of two individual projects which revolve around the importance of post-transcriptional regulation in liver. My first project is studying the integrated miRNA – mRNA network in NAFLD. For fulfillment of the study we conducted a genome-wide study to identify microRNAs (miRs) as well as the miR-mRNA regulatory network associated with hepatic fat and NAFLD. Hepatic fat content (HFC), miR and mRNA expression were assessed in 73 human liver samples. Liver histology of 49 samples was further characterized into normal (n=33) and NAFLD (n=16). Liver miRNome and transcriptome were significantly associated with HFC and utilized to (a) build miR-mRNA association networks in NAFLD and normal livers separately based on the potential miR-mRNA targeting and (b) conduct pathway enrichment analyses. We identified 62 miRs significantly correlated with HFC (p < 0.05 with q < 0.15), with miR-518b and miR-19b being most positively and negatively correlated with HFC, respectively (p < 0.008 for both). Integrated network analysis showed that six miRs (miRs-30b*, 612, 17*, 129-5p, 204 and 20a) controlled ~ 70% of 151 HFC-associated mRNAs (p < 0.001 with q < 0.005). Pathway analyses of these HFC-associated mRNA revealed their key effect (p<0.05) in inflammation pathways and lipid metabolism. Further, significant (p<2.47e-4, Wilcoxon test) reduction in degree of negative associations for HFC-associated miRs with HFC-associated mRNAs was observed in NAFLD as compared to normal livers, strongly suggesting highly dysfunctional miR-mRNA post-transcriptional regulatory network in NAFLD. Our study makes several novel observations which provide clues to better understand the pathogenesis and potential treatment targets of NAFLD.
My second project is based on uncovering important players of post-transcriptional regulation (RBPs) and how they are associated with age and gender during healthy liver development. For this study, we performed an association analysis focusing on the expression changes of 1344 RNA Binding proteins (RBPs) as a function of age and gender in human liver. We identify 88 and 45 RBPs to be significantly associated with age and gender respectively. Experimental verification of several of the predicted associations in the mouse model confirmed our findings. Our results suggest that a small fraction of the gender-associated RBPs (~40%) are likely to be up-regulated in males. Altogether, these observations show that several of these RBPs are important developmentally conserved regulators. Further analysis of the protein interaction network of RBPs associated with age and gender based on the centrality measures like degree, betweenness and closeness revealed that several of these RBPs might be prominent players in liver development and impart gender specific alterations in gene expression via the formation of protein complexes. Indeed, both age and gender-associated RBPs in liver were found to show significantly higher clustering coefficients and network centrality measures compared to non-associated RBPs. The compendium of RBPs and this study will help us gain insight into the role of post-transcriptional regulatory molecules in aging and gender specific expression of genes.
|
193 |
REGULATION OF CHOP TRANSLATION IN RESPONSE TO eIF2 PHOSPHORYLATION AND ITS ROLE IN CELL FATEPalam, Lakshmi Reddy 11 December 2012 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / In response to different environmental stresses, phosphorylation of eukaryotic initiation factor-2 (eIF2) rapidly reduces protein synthesis, which lowers energy expenditure and facilitates reprogramming of gene expression to remediate stress damage. Central to the changes in gene expression, eIF2 phosphorylation also enhances translation of ATF4, a transcriptional activator of genes subject to the Integrated Stress Response (ISR). The ISR increases the expression of genes important for alleviating stress, or alternatively triggering apoptosis. One ISR target gene encodes the transcriptional regulator CHOP whose accumulation is critical for stress-induced apoptosis. In this dissertation research, I show that eIF2 phosphorylation induces preferential translation of CHOP by a mechanism involving a single upstream ORF (uORF) located in the 5’-leader of the CHOP mRNA. In the absence of stress and low eIF2 phosphorylation, translation of the uORF serves as a barrier that prevents translation of the downstream CHOP coding region. Enhanced eIF2 phosphorylation during stress facilitates ribosome bypass of the uORF, and instead results in the translation of CHOP. Stable cell lines were also constructed that express CHOP transcript containing the wild type uORF or deleted for the uORF and each were analyzed for expression changes in response to the different stress conditions. Increased CHOP levels due to the absence of inhibitory uORF sensitized the cells to stress-induced apoptosis when compared to the cells that express CHOP mRNA containing the wild type uORF. This new mechanism of translational control explains how expression of CHOP and the fate of cells are tightly linked to the levels of phosphorylated eIF2 and stress damage.
|
194 |
Functional Insights Into Oncogenic Protein Tyrosine Phosphatases By Mass SpectrometryWalls, Chad Daniel 29 January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Phosphatase of Regenerating Liver 3 (PRL3) is suspected to be a causative factor toward cellular metastasis when overexpressed. To date, the molecular basis for PRL3 function remains an enigma, justifying the use of 'shot-gun'-style phosphoproteomic strategies to define the PRL3-mediated signaling network. On the basis of aberrant Src tyrosine kinase activation following ectopic PRL3 expression, phosphoproteomic data reveal a signal transduction network downstream of a mitogenic and chemotactic PDGF (α and β), Eph (A2, B3, B4), and Integrin (β1 and β5) receptor array known to be utilized by migratory mesenchymal cells during development and acute wound healing in the adult animal. Tyrosine phosphorylation is present on a multitude of signaling effectors responsible for Rho-family GTPase, PI3K-Akt, Jak-STAT3, and Ras-ERK1/2 pathway activation, linking observations made by the field as a whole under Src as a primary signal transducer. Our phosphoproteomic data paint the most comprehensive picture to date of how PRL3 drives pro-metastatic molecular events through Src activation. The Src-homology 2 (SH2) domain-containing tyrosine phosphatase 2 (SHP2), encoded by the Ptpn11 gene, is a bona-fide proto-oncogene responsible for the activation of the Ras/ERK1/2 pathway following mitogen stimulation. The molecular basis for SHP2 function is pTyr-ligand-mediated alleviation of intramolecular autoinhibition by the N-terminal SH2 domain (N-SH2 domain) upon the PTP catalytic domain. Pathogenic mutations that reside within the interface region between the N-SH2 and PTP domains are postulated to weaken the autoinhibitory interaction leading to SHP2 catalytic activation in the open conformation. Conversely, a subset of mutations resides within the catalytic active site and cause catalytic impairment. These catalytically impaired SHP2 mutants potentiate the pathogenesis of LEOPARD-syndrome (LS), a neuro-cardio-facial-cutaneous (NCFC) syndrome with very similar clinical presentation to related Noonan syndrome (NS), which is known to be caused by gain-of-function (GOF) SHP2 mutants. Here we apply hydrogen-deuterium exchange mass spectrometry (H/DX-MS) to provide direct evidence that LS-associated SHP2 mutations which cause catalytic impairment also weaken the autoinhibitory interaction that the N-SH2 domain makes with the PTP domain. Our H/DX-MS study shows that LS-SHP2 mutants possess a biophysical property that is absolutely required for GOF-effects to be realized, in-vivo.
|
195 |
Modulation de la stabilité de l'ARNm alphaENaC dans les cellules épithéliales alvéolaires : détermination du rôle des séquences 3' non traduitesMigneault, Francis 12 1900 (has links)
Le transport actif de sodium par les cellules épithéliales alvéolaires est le principal mécanisme impliqué dans la régulation du niveau de liquide dans le poumon distal. Le canal épithélial sodique (ENaC) exprimé par les cellules épithéliales alvéolaires est essentiel à la résorption du liquide des poumons à la naissance ainsi que la résolution de l'œdème pulmonaire chez l'adulte. L'activité et l'expression du canal ENaC sont modulées par de nombreux stress pathophysiologiques. L'inflammation pulmonaire constitue un facteur important dans l'inhibition de l'expression du canal ENaC et pourrait favoriser la formation d'œdème pulmonaire. Nous avons précédemment démontré que différentes cytokines pro-inflammatoires, ainsi que les lipopolysaccharides (LPS) de Pseudomonas aeruginosa, inhibent l'expression de l'ARNm αENaC par des mécanismes de régulation transcriptionnelle et post-transcriptionnelle. Ces résultats suggèrent que les mécanismes qui modulent la stabilité des ARNm αENaC pourraient jouer un rôle important dans la régulation du niveau d’expression du transcrit en condition inflammatoire.
Le principal objectif de mes travaux était de caractériser les mécanismes de modulation de l’ARNm αENaC dans les cellules épithéliales alvéolaires lors de différents stress pathophysiologiques et déterminer si cette modulation pouvait s’expliquer en partie par une régulation de la stabilité du transcrit. Mes travaux montrent que les LPS et la cycloheximide inhibent l’expression de l’ARNm αENaC de façon similaire via l’activation des voies de signalisation des MAPK ERK1/2 et p38. Cependant, les mécanismes de modulation de l’expression de l'ARNm αENaC sont différents puisque les LPS répriment la transcription du gène, alors que la cycloheximide diminuerait la stabilité du transcrit via des mécanismes post-transcriptionnels impliquant la région 3' non traduite (3'UTR) de l'ARNm αENaC. Pour mieux étudier le rôle du 3'UTR dans ce processus, nous avons développé un modèle Tet-Off nous permettant de mesurer la demi-vie de l’ARNm αENaC indépendamment de l’utilisation d’un inhibiteur de la transcription comme l'actinomycine D (Act. D). Nous avons montré que la demi-vie de l’ARNm αENaC était de 100min, un temps beaucoup plus court que celui rapporté dans la littérature. Nous avons démontré que l’Act. D a un effet stabilisateur important sur l’ARNm αENaC et qu’il ne peut être utilisé pour évaluer la stabilité du transcrit. À l’aide de différents mutants de délétion, nous avons entrepris de déterminer la nature des régions du 3’UTR impliquées dans la modulation de la stabilité du transcrit. Nous avons trouvé que le 3’UTR joue un rôle à la fois de stabilisation (région 3’UTR proximale) et de déstabilisation (région 3’UTR distale) du transcrit. Notre système nous a finalement permis de confirmer que la diminution de l’ARNm αENaC observée en présence de TNF-α s’expliquait en partie par une diminution importante de la stabilité du transcrit induite par cette cytokine. Enfin, nous avons identifié la nature des protéines pouvant se lier au 3’UTR de l’ARNm αENaC et déterminé lesquelles pouvaient moduler la stabilité du transcrit. Des trois protéines candidates trouvées, nous avons confirmé que la surexpression de DHX36 et TIAL1 diminue le niveau de transcrit par un mécanisme impliquant la stabilité du messager.
Les travaux présentés ici montrent la complexité des voies de signalisation induites par différents stress sur les cellules épithéliales alvéolaires et montrent comment la stabilité de l’ARNm αENaC et en particulier, les séquences du 3’UTR jouent un rôle important dans la modulation du niveau de transcrit. Le modèle Tet-Off que nous avons développé permet d’estimer le temps de demi-vie réel de l’ARNm αENaC et montre que le 3’UTR du messager joue un rôle complexe dans la stabilisation du messager en condition de base ainsi qu’en condition pro-inflammatoire. Enfin, nous avons identifié deux protéines liant l’ARNm qui pourraient jouer un rôle important dans la modulation de la stabilité du transcrit. / The epithelial sodium channel (ENaC) expressed in alveolar epithelial cells plays a major role for lung liquid clearance at birth and lung edema resorption in adulthood. The expression and activity of ENaC are inhibited by many pathophysiological stress that could have an impact in the clinical outcome of acute respiratory distress syndrome (ARDS). Pulmonary inflammation is an important factor in this inhibition that may promote or sustain pulmonary edema. We have previously shown that pro-inflammatory cytokines and lipopolysaccharide (LPS) from Pseudomonas aeruginosa inhibit αENaC mRNA expression by transcriptional and post-transcriptional mechanisms, suggesting that a modulation of αENaC mRNA stability could play a role in this process.
The main objective of the present work was to characterize how different pathophysiological stress affect αENaC mRNA expression in alveolar epithelial cells and determine whether this modulation could be explained in part by regulating the stability of the transcript. Our study shows that LPS and cycloheximide decrease the level of αENaC mRNA with a similar time course and via the activation of the MAPK ERK1/2 and p38 signaling pathways. Despite similarities, there were important differences in the mechanisms involved in the modulation of αENaC mRNA expression. While LPS repress αENaC mRNA transcription, cycloheximide triggers post-transcriptional mechanisms involving the 3' untranslated region (3'UTR) of αENaC mRNA. To further study the role of αENaC 3'UTR in this process, we developed a Tet-Off model that allows us to measure the half-life of αENaC mRNA regardless of the use of a transcription inhibitor such as actinomycin D (Act. D). Using this system, we showed a 100 min half-life for αENaC mRNA, a much shorter time then the one reported for this mRNA using Act. D. We showed that Act. D has an important stabilizing effect on αENaC mRNA and cannot be used to assess the stability of the transcript. Using deletion mutants of the αENaC 3'UTR region, we determined how different portions of 3'UTR were important in modulating stability of the transcript. We found that the 3'UTR has dual functions, with portions important to promote stabilization (proximal 3'UTR) and others that strongly destabilize (distal 3'UTR) the transcript. Our system also allowed us to confirm that the decreased expression of αENaC mRNA induced by TNF-α results in part by a decreased stability of the mRNA. Finally, we identified several RNA-binding proteins that interact specifically with αENaC 3'UTR and determined if these proteins had an impact on transcript stability. Surexpression of two of these proteins in alveolar epithelial cells, DHX36 and TIAL1 was able to decrease the level of αENaC mRNA via a downregulation of mRNA stability.
The work presented here shows the complexity of the signal transduction pathways elicited by different pathological stress conditions in alveolar epithelial cells and is the first to show that αENaC mRNA stability elicited by sequences in 3’UTR plays an important role in modulating the level of the transcript. The Tet-Off model that we developed allows to accurately estimate the half-life of αENaC mRNA and shows that the 3’UTR portion of the mRNA plays a complex role in the modulation of transcript stability in basal and pro-inflammatory conditions. Finally, we identified two putative RNA-binding proteins able to specifically recognize αENaC 3’UTR and modulate the transcript stability.
|
196 |
Mécanismes modulant la stabilité de l’ARNm alphaENaC des cellules épithéliales alvéolaires dans un environnement inflammatoireGagnon, Frédéric 04 1900 (has links)
No description available.
|
197 |
Nucleo-cytoplasmic transport of TIS11 proteins and stress granule assembly: two potential new roles for Transportins / Transport nucléo-cytoplasmique des protéines de la famille TIS11 et formation des granules de stress: deux nouveaux rôles potentiels des TransportinesTwyffels, Laure 04 September 2013 (has links)
The nucleo-cytoplasmic compartmentalization enables eukaryotic cells to develop sophisticated post-transcriptional regulations of gene expression. However, managing the exchanges of macromolecules between the two compartments also represents a formidable challenge for the cells. Nucleo-cytoplasmic exchanges rely on specialized soluble carriers and take place at nuclear pore complexes that span the nuclear envelope. Active nucleo-cytoplasmic transport of proteins, in particular, is performed mainly by a family of carriers called karyopherins, which includes about twenty members in mammals. Some of them, called importins, recognize nuclear localization signals (NLSs) in their substrates and convey them into the nucleus. Others, called exportins, recognize nuclear export signals (NESs) in their substrates and bring them back to the cytoplasm. <p>Many RNA-binding proteins (RBPs) shuttle between the nucleus and the cytoplasm, where they can often fulfill different functions. RBPs also frequently localize into specialized microdomains that are not delimited by a membrane but in which specific factors are concentrated. Those include processing bodies and stress granules, which are cytoplasmic foci associated with mRNA decay, storage and translational repression. Post-transcriptional regulations mediated by RBPs can therefore be modulated rapidly and efficiently through changes in the localization of RBPs.<p>The first part of this work focuses on the subcellular localization and nucleo-cytoplasmic transport of the Drosophila RBP dTIS11. Like its mammalian and yeast homologues, dTIS11 binds AU-rich elements in the 3’UTR of its target mRNAs, and stimulates their rapid deadenylation and decay. Here, we have observed that although dTIS11 appears to be located mostly in the cytoplasm, it is constantly shuttling in and out of the nucleus. We show that the export of dTIS11 from the nucleus depends on the CRM1 exportin and is mediated by a hydrophobic NES that encompasses residues 101 to 113 in dTIS11 sequence. We also identify a cryptic Transportin-dependent PY nuclear localization signal (PY-NLS) in the tandem zinc finger region of dTIS11 and show that it is conserved across the TIS11 protein family. This PY-NLS partially overlaps the second zinc finger (ZnF2) of dTIS11. Importantly, mutations disrupting the capacity of the ZnF2 to coordinate a Zn2+ ion unmask dTIS11 and TTP PY-NLS and promote nuclear import. Taken together, our results indicate that the nuclear export of Drosophila and mammalian TIS11 proteins is mediated by CRM1 through diverging NESs, while their nuclear import mechanism might rely on a conserved PY-NLS whose activity is negatively regulated by ZnF2 folding.<p>In the second part, we present preliminary results which implicate the nucleo-cytoplasmic transport machinery in the assembly of stress granules (SGs) in mammalian cells. SGs contain silenced mRNPs which resemble stalled initiation complexes, and they form transiently in response to acute stress, concomitantly with a global arrest of translation. While their exact role remains undefined, it seems clear that SGs are able to exchange mRNPs with polysomes and with PBs, and that they are connected to post-transcriptional and translational regulations of gene expression during stress. Here, we show that inhibition of Transportin-1 expression or function does not affect the translational status of cells but impairs the assembly of stress granules. Finally, we show that Transportin-1 and -2B, but not -2A, localize into stress granules in response to several stresses. <p>In conclusion, we suggest two potential new roles for Transportins, in the nucleo-cytoplasmic traffic of TIS11 proteins on the one hand and in the assembly of stress granules on the other hand.<p>/<p>Le compartimentage nucléo-cytoplasmique permet aux cellules eucaryotes de réguler l’expression génétique par des mécanismes post-transcriptionnels élaborés. Les ARN messagers subissent plusieurs étapes de maturation dans le noyau avant d’être exportés vers le cytoplasme où ils sont traduits et dégradés. Ces processus sont effectués via des protéines de liaison à l’ARN, ou RBPs. Beaucoup de RBPs exercent des fonctions différentes dans le noyau et dans le cytoplasme, et leur activité peut dès lors être rapidement modulée par une modification de leur localisation.<p>Le transport nucléo-cytoplasmique actif des protéines s’effectue à travers les pores nucléaires et fait majoritairement appel à des transporteurs solubles de la famille des karyophérines. Ceux-ci reconnaissent au sein des protéines à transporter une séquence-passeport appelée NLS (nuclear localization signal) ou NES (nuclear export signal) selon la direction nécessitée. <p>Le présent travail comporte deux parties. La première porte sur la localisation subcellulaire et le transport nucléo-cytoplasmique des protéines de la famille TIS11, et plus particulièrement de dTIS11 qui est le seul représentant de cette famille chez la Drosophile. Comme ses homologues dans d’autres espèces, dTIS11 est une RBP qui favorise la déadénylation et la dégradation de ses ARN messagers cibles. Nos résultats démontrent que dTIS11 fait la navette entre le noyau et le cytoplasme. L’export de dTIS11 hors du noyau est réalisé par la karyophérine CRM1 et fait appel à un NES différent de celui présent chez les protéines TIS11 mammaliennes. Nous identifions également un NLS cryptique au sein du domaine à deux doigts de zinc avec lequel dTIS11 lie l’ARN. Ce NLS correspond partiellement au signal consensus reconnu par la Transportine. Il est démasqué par la mutation du second doigt de zinc ;dans ces conditions, il permet l’import de dTIS11 par la Transportine. Enfin, nous montrons qu’il est conservé dans d’autres protéines de la famille TIS11. <p>Dans la seconde partie, nous nous intéressons aux granules de stress, qui sont des microdomaines cytoplasmiques dans lesquels se concentrent des RBPs et des ARN messagers non traduits en réponse à un stress cellulaire. Nous montrons que les karyophérines appartenant à la sous-famille des Transportines sont présentes dans ces granules et que l’inhibition de l’expression ou de la fonction des Transportines réduit la formation de ces granules en réponse à divers stress cellulaires. Nous écartons la possibilité que ce résultat soit un effet indirect d’un ralentissement du métabolisme traductionnel. Nos résultats suggèrent donc une implication des Transportines dans la formation des granules de stress. <p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
|
198 |
Implication de la protéine Staufen 2 dans les voies de réponse aux dommages à l’ADNCondé, Lionel 10 1900 (has links)
De nombreuses voies de signalisation cellulaire complexes permettent de répondre à la présence de dommages à l’ADN. Cette réponse cellulaire est indispensable afin d’éviter l’accumulation de mutations pouvant éventuellement conduire à la transformation tumorale. Ces différentes voies de réponse aux dommages à l’ADN sont hautement coordonnées et sont regroupées au sein d’un mécanisme global appelé DNA damage response (DDR). Les facteurs du DDR sont régulés à plusieurs niveaux de la cascade de l’expression des gènes. De façon notable, plusieurs protéines de liaison à l’ARN (RBP) participent à la régulation de l’expression des gènes du DDR via la régulation post- transcriptionnelle de leur ARN messager. La RBP STAU2 est connue pour lier plusieurs ARNm codant pour des protéines impliquées dans le contrôle du cycle cellulaire ainsi que dans les voies du DDR. La protéine STAU2 est elle-même régulée au niveau transcriptionnel par le facteur de transcription E2F1. De récentes observations laissent penser que la kinase centrale du DDR, CHK1, pourrait être impliquée dans la régulation de la stabilité de STAU2. Par ailleurs, les conséquences cellulaires de la diminution du niveau d’expression de STAU2 sont à ce jour très peu connues.
Ce mémoire a d’abord été entrepris dans le but de mieux comprendre l’implication de la voie de la kinase CHK1 dans la régulation de la protéine de liaison à l’ARN STAU2. CHK1 est une protéine centrale des voies du DDR ainsi que du contrôle de la progression du cycle cellulaire en l’absence de dommages à l’ADN. Nos résultats montrent que la diminution de CHK1 induit une dégradation rapide de STAU2 par les caspases d’une façon indépendante de l’apoptose. Nous avons également renforcé ce lien entre STAU2 et les mécanismes de réparation des dommages à l’ADN en identifiant plusieurs protéines des voies de réparation dans l’environnement immédiat de STAU2.
D’autre part nos travaux visent à mettre en évidence les conséquences de la déplétion de STAU2 dans plusieurs types cellulaires. STAU2 étant une RBP, sa dérégulation impacte inévitablement le devenir de plusieurs ARNm. Afin de caractériser ces différentes conséquences, nous avons dans un premier temps réalisé la déplétion totale de STAU2
dans des cellules hTert-RPE par la technique de CRISPR/Cas9. Nos résultats montrent que ces cellules accumulent anormalement des dommages à l’ADN et prolifèrent plus rapidement que des cellules normales. En outre plusieurs gènes impliqués dans la réparation des dommages à l’ADN se retrouvent diminués dans ces cellules. Dans un second temps, afin de définir si cet effet est dépendant du type cellulaire, nous avons induit la diminution de l’expression de STAU2 dans des cellules IMR90. Nous avons montré que dans ce cas, la diminution de STAU2 induit un arrêt du cycle cellulaire et une entrée des cellules en sénescence.
Ainsi, les données présentées dans ce mémoire contribuent à mieux comprendre l’implication de STAU2 dans les processus cellulaires majeurs que sont la régulation du DDR et le contrôle du cycle cellulaire. / Many complex cellular pathways are induced in response to DNA damages. This cellular response is indispensable to prevent the accumulation of mutations and to avoid malignant transformation. These different pathways are highly coordinated and are organized in a global mechanism called DNA damage response (DDR). Proteins involved in the DDR are regulated at different levels of the gene expression process. Notably, several RNA binding proteins are involved in the regulation of DDR gene expression through the post-transcriptional control of their mRNA. The RBP STAU2 is known to bind various mRNAs coding for proteins involved in the DDR or cell cycle control. STAU2 is regulated at the transcriptional levels by the major transcription factor E2F1. Recent observations suggest that CHK1 could be implicated in the control of the steady-state level of STAU2. Otherwise, the cellular consequences of STAU2 downregulation remain elusive.
The purpose of this research was first to elucidate the implication of CHK1 pathway in STAU2 regulation. CHK1 is a major protein involved in the DDR regulation as well as in the control of cell cycle progression in the absence of DNA damage. Our data show that the downregulation of CHK1 rapidly leads to a caspase-dependent degradation of STAU2 independently of apoptosis. The link between STAU2 and mechanisms of DNA repair was reinforced by our BioID2 experiment that identified several proteins of the DDR in close proximity with STAU2.
On the other hand, the aim of this study was to determine the consequences of STAU2 downregulation in different cell lines. Given that STAU2 is an RBP, its dysregulation will inevitably change the fate of several mRNA. In order to increase our understanding of theses consequences, we generated an hTert-RPE1 STAU2-KO cell line using the CRISPR/Cas9 technique. Our data show that these cells accumulate DNA damage and have an increased proliferation rate. Moreover, several genes involved in the DNA repair pathway are downregulated. We also downregulated STAU2 in IMR90 to determine if the
previous observations are cell-type specifics. In the latter case, STAU2 diminution triggers cell cycle arrest and cellular senescence.
Altogether, these results contribute to improve our knowledge of STAU2 function, especially in DNA damage response pathway and in cell cycle regulation.
|
199 |
Caractérisation systématique des motifs de régulation en cis à l’échelle transcriptomique et liens avec la localisation des ARNBenoit Bouvrette, Louis Philip 04 1900 (has links)
La localisation subcellulaire de l’ARN permet un déploiement prompt et spatialement restreint autant des activités protéiques que des ARN noncodant. Le trafic d’ARN est dirigé par des éléments de séquences (sous-séquences primaires, structures secondaires), aussi appelés motifs de régulation, présents en cis à même la molécule d’ARN. Ces motifs sont reconnus par des protéines de liaisons aux ARN qui médient l’acheminement des transcrits vers des sites précis dans la cellule. Des études récentes, chez l’embryon de Drosophile, indiquent que la majorité des ARN ont une localisation subcellulaire asymétrique, suggérant l’existence d’un « code de localisation » complexe. Cependant, ceci peut représenter un exemple exceptionnel et la question demeurait, jusqu’ici, si une prévalence comparable de localisation d’ARN est observable chez des cellules standards développées en culture. De plus, des informations facilement disponibles à propos des caractéristiques de distribution topologique d’instances de motifs à travers des transcriptomes complets étaient jusqu’à présent manquantes.
Afin d’avoir un aperçu de l’étendue et des propriétés impliquées dans la localisation des ARN, nous avons soumis des cellules de Drosophile (D17) et de l’humain (HepG2) à un fractionnement biochimique afin d’isoler les fractions nucléaire, cytosolique, membranaire et insoluble. Nous avons ensuite séquencé en profondeur l’ARN extrait et analysé par spectrométrie de masse les protéines extraites de ces fractions. Nous avons nommé cette méthode CeFra-Seq. Par des analyses bio-informatiques, j’ai ensuite cartographié l’enrichissement de divers biotypes d’ARN (p. ex. ARN messager, ARN long non codant, ARN circulaire) et protéines au sein des fractions subcellulaires. Ceci a révélé que la distribution d’un large éventail d’espèces d’ARN codants et non codants est asymétrique. Une analyse des gènes orthologues entre mouche et humain a aussi démontré de fortes similitudes, suggérant que le processus de localisation est évolutivement conservé. De plus, j’ai observé des attributs (p. ex. la taille des transcrits) distincts parmi les populations d’ARN messagers spécifiques à une fraction. Finalement, j’ai observé des corrélations et anti-corrélations spécifiques entre certains groupes d’ARN messagers et leurs protéines.
Pour permettre l’étude de la topologie de motifs et de leurs conservations, j’ai créé oRNAment, une base de données d’instances présumée de sites de liaison de protéines chez des ARN codants et non codants. À partir de données de motifs de liaison protéique par RNAcompete et par RNA Bind-n-Seq, j’ai développé un algorithme permettant l’identification rapide d’instances potentielles de ces motifs dans un transcriptome complet. J’ai pu ainsi cataloguer les instances de 453 motifs provenant de 223 protéines liant l’ARN pour 525 718 transcrits chez cinq espèces. Les résultats obtenus ont été validés en les comparant à des données publiques de eCLIP.
J’ai, par la suite, utilisé oRNAment pour analyser en détail les aspects topologiques des instances présumées de ces motifs et leurs conservations évolutives relatives. Ceci a permis de démontrer que la plupart des motifs sont distribués de façon similaire entre espèces. De plus, j’ai discerné des points communs entre les sous-groupes de protéines liant des biotypes distincts ou des régions d’ARN spécifiques. La présence de tels patrons, similaires ou non, entre espèces est susceptible de refléter l’importance de leurs fonctions. D’ailleurs, l’analyse plus détaillée du positionnement d’un motif entre régions transcriptomiques comparables chez les vertébrés suggère une conservation synténique de ceux-ci, à divers degrés, pour tous les biotypes d’ARN. La topologie régionale de certaines instances de motifs répétées apparaît aussi comme évolutivement conservée et peut être importante afin de permettre une liaison adéquate de la protéine. Finalement, les résultats compilés avec oRNAment ont permis de postuler sur un nouveau rôle potentiel pour l’ARN long non codant HELLPAR comme éponge de protéines liant l’ARN.
La caractérisation systématique d’ARN localisés et de motifs de régulation en cis présentée dans cette thèse démontre comment l’intégration d’information à l’échelle transcriptomique permet d’évaluer la prévalence de l’asymétrie, les caractéristiques distinctes et la conservation évolutive de collections d’ARN. / The subcellular localization of RNA allows a rapid and spatially restricted deployment of protein and noncoding RNA activities. The trafficking of RNA is directed by sequence elements (primary subsequences, secondary structures), also called regulatory motifs, present in cis within the RNA molecule. These motifs are recognized by RNA-binding proteins that mediate the transport of transcripts to specific sites in the cell. Recent studies in the Drosophila embryo indicate that the majority of RNAs display an asymmetric subcellular localization, suggesting the existence of a complex "localization code". However, this may represent an exceptional example and the question remained, until now, whether a comparable prevalence of RNA localization is observable in standard cells grown in culture. In addition, readily available information about the topological distribution of pattern instances across full transcriptomes has been hitherto lacking.
In order to have a broad overview of the extent and properties involved in RNA localization, we subjected Drosophila (D17) and human (HepG2) cells to biochemical fractionation to isolate the nuclear, cytosolic, membrane and insoluble fractions. We then performed deep sequencing on the extracted RNA and analyzed through mass spectrometry the proteins extracted from these fractions. We named this method CeFra-Seq. Through bioinformatics analyses, I then profiled the enrichment of various RNA biotypes (e.g. messenger RNA, long noncoding RNA, circular RNA) and proteins within the subcellular fractions. This revealed the high prevalence of asymmetric distribution of both coding and noncoding RNA species. An analysis of orthologous genes between fly and human has also shown strong similarities, suggesting that the localization process is evolutionarily conserved. In addition, I have observed distinct attributes (e.g. transcript size) among fraction-specific messenger RNA populations. Finally, I observed specific correlations and anti-correlations between defined groups of messenger RNAs and the proteins they encode. To study motifs topology and their conservation, I created oRNAment, a database of putative RNA-binding protein binding sites instances in coding and noncoding RNAs. Using data from protein binding motifs assessed by RNAcompete and by RNA Bind-n-Seq experiments, I have developed an algorithm allowing their rapid identification in a complete transcriptome. I was able to catalog the instances of 453 motifs from 223 RNA-binding proteins for 525,718 transcripts in five species. The results obtained were validated by comparing them with public data from eCLIP.
I then used oRNAment to further analyze the topological aspects of these motifs’ instances and their relative evolutionary conservation. This showed that most motifs are distributed in a similar fashion between species. In addition, I have detected commonalities between the subgroups of proteins linking preferentially distinct biotypes or specific RNA regions. The presence or absence of such pattern between species is likely a reflection of the importance of their functions. Moreover, a more precise analysis of the position of a motif among comparable transcriptomic regions in vertebrates suggests a syntenic conservation, to varying degrees, in all RNA biotypes. The regional topology of certain motifs as repeated instances also appears to be evolutionarily conserved and may be important in order to allow adequate binding of the protein. Finally, the results compiled with oRNAment allowed to postulate on a potential new role for the long noncoding RNA HELLPAR as an RNA-binding protein sponge.
The systematic characterization of RNA localization and cis regulatory motifs presented in this thesis demonstrates how the integration of information at a transcriptomic scale enables the assessment of the prevalence of asymmetry, the distinct characteristics and the evolutionary conservation of RNA clusters.
|
200 |
Expression of histone deacetylase enzymes in murine and chick optic nerveTiwari, Sarika January 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Epigenetic alterations have been shown to control cell type specification and differentiation leading to the changes in chromatin structure and organization of many genes. HDACs have been well documented to play an important role in both neurogenesis and gliogenesis in ganglionic eminence and cortex-derived cultures. However, the role of HDACs in glial cell type specification and differentiation in the optic nerve has not been well described. As a first step towards understanding their role in glial cell type specification, we have examined histone acetylation and methylation levels as well as the expression levels and patterns of the classical HDACs in both murine and chick optic nerve. Analysis of mRNA and protein levels in the developing optic nerve indicated that all 11 members of the classical HDAC family were expressed, with a majority declining in expression as development proceeded. Based on the localization pattern in both chick and murine optic nerve glial cells, we were able to group the classical HDACs: predominantly nuclear, nuclear and cytoplasmic, predominantly cytoplasmic. Nuclear expression of HDACs during different stages of development studied in this project in both murine and chick optic nerve glial cells suggests that HDACs play a role in stage-dependent changes in gene expression that accompany differentiation of astrocytes and oligodendrocytes. Examination of localization pattern of the HDACs is the first step towards identifying the specific HDACs involved directly in specification and differentiation of glia in optic nerve.
|
Page generated in 0.045 seconds