Global ETD Search

11	Expression of the cytoplasmic nucleolin for post-transcriptional regulation of macrophage colony-stimulating factor mRNA in ovarian and breast cancer cells Woo, Ho-Hyung, Lee, Sang C., Gibson, Steven J., Chambers, Setsuko K. 03 1900 (has links) The formation of the mRNP complex is a critical component of translational regulation and mRNA decay. Both the 5 ' and 3 ' UTRs of CSF-1 mRNA are involved in post-transcriptional regulation. In CSF-1 mRNA, a small hairpin loop structure is predicted to form at the extreme 5 ' end (2-21 nt) of the 5 ' UTR. Nucleolin binds the hairpin loop structure in the 5 ' UTR of CSF-1 mRNA and enhances translation, while removal of this hairpin loop nucleolin binding element dramatically represses translation. Thus in CSF-1 mRNA, the hairpin loop nucleolin binding element is critical for translational regulation. In addition, nucleolin interacts with the 3 ' UTR of CSF-1 mRNA and facilitates the miRISC formation which results in poly (A) tail shortening. The overexpression of nucleolin increases the association of CSF-1 mRNA containing short poly (A)(n), <= 26, with polyribosomes. Nucleolin both forms an mRNP complex with the eIF4G and CSF-1 mRNA, and is co-localized with the eIF4G in the cytoplasm further supporting nucleolin's role in translational regulation. The distinct foci formation of nucleolin in the cytoplasm of ovarian and breast cancer cells implicates the translational promoting role of nucleolin in these cancers. Cytoplasmic nucleolin Untranslated regions Hairpin loop structure elF4G Translation Deadenylation mRNA
12	Structural and functional characterisation of the CCR4- NOT deadenylation complex / Caractérisation fonctionnelle et structurale du complexe de déadénylation CCR4-NOT Roudko, Vladimir 19 September 2014 (has links) La dégradation des ARN messagers (ARNm) est un processus universel extrêmement complexe. D’une manière semblable aux polymerases pour la transcription et ribosomes pour la traduction, les complexes de protéines effectuant la dégradation des ARNm sont précisément régulés. La dégradation des ARNm eucaryotes s’effectue selon un schéma conservé évolutivement qui est initié par la déadénylation résultant dans la formation de transcrits avec des queues polyA courtes. De tels intermédiaires sont alors dégradés par le clivage de leur coiffe suivi par une digestion exonucléolytique 5’-3’ effectuée par Xrn1, ou alternativement par une digestion 3 ’-5’ catalysée par l’exosome. Dans ma thèse je présente une dissection fonctionnelle du complexe de déadénylation CCR4-NOT basée sur son analyse structurale. Je me suis essentiellement intéressé à cinq questions fondamentales concernant ce complexe : La formation du complexe CCR4-NOT complexe est-elle requise pour la déadénylation ? Quel est le rôle moléculaire de sous-unités Not2/3/5 du complexe ? Pourquoi la protéine Not1 est-elle essentielle chez la levure ? Le complexe CCR4-NOT joue-t-il un rôle dans la répression de la traduction ? Comment le complexe CCR4-NOT est-il ciblé sur ses substrats ARNm ? / MRNA degradation is a highly complex and versatile process. In a manner similar to polymerase complexes in transcription and ribosomes in translation, protein complexes mediating mRNA decay are tightly regulated. Eukaryotic mRNA decay follows a conserved pathway initiated by deadenylation that generates transcripts with short polyA tails. The latter intermediates are degraded either by decapping followed with 5’-3’ trimming mediated by Xrn1, or by exosome-mediated digestion in the 3’-5’ direction. In my thesis I present a functional dissection of the Ccr4-Not deadenylase complex based on its structural analysis. Essentially, I addressed five fundamental questions related to this complex: Is CCR4-NOT complex formation required for deadenylation activity? What is the molecular role of associated Not2/3/5 subunits? Why is the Not1 protein essential in yeast? Does the CCR4-NOT complex play role in translation regulation? How is the CCR4-NOT complex targeted to its mRNA substrates? CCR4-NOT Déadénylation Répression de la traduction Analyse structurale et fonctionelle CCR4-NOT Deadenylation Translation repression Structural and functional analysis 571.4 572.8
13	Rôle du facteur de terminaison de la traduction eRF3 (eukaryotic Release Factor 3) dans la stabilité des ARN messagers / The role of the translation termination factor eRF3 (eukaryotic Release Factor 3) in the messenger RNA stability Jerbi Chaabnia, Soumaya 22 September 2015 (has links) La désadénylation des ARNm fait intervenir les complexes de désadénylation PAN2-PAN3 et CCR4-NOT-TOB mais aussi le complexe de terminaison de la traduction eRF1-eRF3. Ces trois complexes ont la capacité d'interagir avec la protéine PABP. Cependant, le rôle d'eRF3 n'est pas clairement établi. Il a été décrit que les facteurs eRF3, PAN3 et TOB sont en compétition pour l'interaction avec PABP et qu'il y a un couplage entre la terminaison de la traduction et la désadénylation assuré par eRF3. Chez l'homme, le gène eRF3/GSPT1 présente 5 formes alléliques qui diffèrent par le nombre de répétitions de codons GGC à l'extrémité 5' du cadre de lecture (7, 9, 10, 11 et 12-GGC). Une corrélation entre l'allèle 12-GGC et le risque de développement de cancer du sein et de l'estomac a été mis en évidence. Notre objectif est (i) d'améliorer notre compréhension du rôle d'eRF3 dans le processus de couplage traduction-dégradation des ARNm, (ii) de comprendre l'effet du polymorphisme de la région N-terminale d'eRF3 sur son interaction avec PABP. A travers la méthode de résonnance plasmonique de surface (SPR), nous montrons que l'affinité de la forme allélique 12-GGC est 10 fois plus faible que celle d'eRF3a (10-GGC). Cette différence est essentiellement due à la plus faible association de la forme 12-GGC avec PABP. La plus faible affinité de la forme 12-GGC d'eRF3 entrainerait une dérégulation de la désadénylation au moins pour certains ARNm et pourrait ainsi promouvoir la prolifération cellulaire et la carcinogenèse. La région N-terminale d'eRF3 contenant la répétition de glycine joue un rôle crucial dans l'interaction eRF3-PABP, dans la désadénylation et donc dans la stabilité de l'ARNm. / The mRNA deadenylation involves the deadenylation complexes PAN2-PAN3 and CCR4-NOT-TOB and the translation termination complex eRF1-eRF3. All three proteins, eRF3, PAN3 and TOB, interact with the PABP protein. However, the role of eRF3 is still unclear. It has been reported that eRF3, TOB and PAN3 compete for the binding to PABP. Recently, it has been suggested that eRF3 may regulate mRNA deadenylation in a translation termination-coupled manner. In human, the gene eRF3/GSPT1, contains a trinucleotide GGC repeat in its 5’ end which lead to 5 allelic forms of the gene. There are five known alleles of this gene (7, 9, 10, 11 and 12-GGC). A strong correlation between the longest allele (12-GGC) and gastric and breast cancer development has been reported. Our project was (i) to improve our understanding on the role of eRF3 in the coupling of mRNA deadenylation with translation termination, (ii) to understand whether the GGC repeat polymorphism of eRF3 influences eRF3-PABP interaction. The kinetic measurements of eRF3-PABP interaction obtained by Surface Plasmon Resonance (SPR) show that the affinity of the allelic 12-GGC form is 10 fold lower than that of eRF3a (10-GGC). This decrease is mostly due to difference in the association rate of the complex. The weaker affinity of the 12-GGC allelic form may result in a deregulation of deadenylation, at least for some mRNAs, and thus, could promote cell proliferation and carcinogenesis. In fine, we show that the N-terminal region of eRF3 containing the glycine expansion plays a key role in the eRF3-PABP interaction, in the deadenylation process, and hence, in mRNA stability. ERF3 GSPT1 PABP Terminaison de la traduction Cancer Résonance Plasmonique de Surface Répétition de GGC Désadénylation des ARNm MRNA deadenylation Surface Plasmon Resonance 572
14	Poly(A)-Specific Ribonuclease (PARN) Ren, Yan-Guo January 2001 (has links) <p>Degradation of the mRNA 3'-end located poly(A) tail is an important step for mRNA decay in mammalian cells. Thus, to understand mRNA decay in detail, it is important to identify the catalytic activities involved in degrading poly(A). We identified and purified a 54-kDa polypeptide responsible for poly(A)-specific 3' exonuclease activity in calf thymus extracts. The 54-kDa polypeptide is a proteolytic fragment of the poly(A)-specific ribonuclease (PARN) 74-kDa polypeptide. PARN is a divalent metal ion dependent, poly(A)-specific, oligomeric, processive and cap interacting 3' exonuclease. An active deadenylation complex, consisting of the poly(A)-tailed RNA substrate and PARN, has been identified. The interaction with the 5'-end cap structure stimulates PARN activity and also amplifies the processivity of the deadenylation reaction. Furthermore, the cap binding site and the active site of PARN are separate from each other. To characterise the active site of PARN, we per-formed side-directed mutagenesis, Fe<sup>2+</sup>-mediated hydroxyl radical cleavage and metal ion switch experiments. We have demonstrated that the conserved acidic amino acid residues D28, E30, D292 and D382 of human PARN are essential for PARN activity and that these amino acid residues are directly involved in the co-ordination of at least two metal ions in the active site of PARN. Phosphorothioate modification on RNA substrates revealed that the pro-R oxygen atom of the scissile phosphate group interacts directly with the metal ion(s). Based on our studies, we propose a model for the action of PARN. Similarly to what has been observed for ribozymes, aminoglycoside antibiotics inhibit PARN activity, most likely by the displacement of catalytically important divalent metal ions. Among the aminoglycoside antibiotics tested, neomycin B is the most potent inhibitor. We speculate that inhibition of enzymes using similar catalytic mechanisms as PARN could be a reason for the toxic side effects caused by aminoglycoside antibiotics in clinical practice. </p> Cell and molecular biology Poly(A)-specific ribonuclease PARN deadenylation processive oligomeric cap interacting aminoglycoside active site FE2+-mediated cleavage metal ion switch Cell- och molekylärbiologi Cell and molecular biology Cell- och molekylärbiologi
15	Poly(A)-Specific Ribonuclease (PARN) Ren, Yan-Guo January 2001 (has links) Degradation of the mRNA 3'-end located poly(A) tail is an important step for mRNA decay in mammalian cells. Thus, to understand mRNA decay in detail, it is important to identify the catalytic activities involved in degrading poly(A). We identified and purified a 54-kDa polypeptide responsible for poly(A)-specific 3' exonuclease activity in calf thymus extracts. The 54-kDa polypeptide is a proteolytic fragment of the poly(A)-specific ribonuclease (PARN) 74-kDa polypeptide. PARN is a divalent metal ion dependent, poly(A)-specific, oligomeric, processive and cap interacting 3' exonuclease. An active deadenylation complex, consisting of the poly(A)-tailed RNA substrate and PARN, has been identified. The interaction with the 5'-end cap structure stimulates PARN activity and also amplifies the processivity of the deadenylation reaction. Furthermore, the cap binding site and the active site of PARN are separate from each other. To characterise the active site of PARN, we per-formed side-directed mutagenesis, Fe2+-mediated hydroxyl radical cleavage and metal ion switch experiments. We have demonstrated that the conserved acidic amino acid residues D28, E30, D292 and D382 of human PARN are essential for PARN activity and that these amino acid residues are directly involved in the co-ordination of at least two metal ions in the active site of PARN. Phosphorothioate modification on RNA substrates revealed that the pro-R oxygen atom of the scissile phosphate group interacts directly with the metal ion(s). Based on our studies, we propose a model for the action of PARN. Similarly to what has been observed for ribozymes, aminoglycoside antibiotics inhibit PARN activity, most likely by the displacement of catalytically important divalent metal ions. Among the aminoglycoside antibiotics tested, neomycin B is the most potent inhibitor. We speculate that inhibition of enzymes using similar catalytic mechanisms as PARN could be a reason for the toxic side effects caused by aminoglycoside antibiotics in clinical practice. Cell and molecular biology Poly(A)-specific ribonuclease PARN deadenylation processive oligomeric cap interacting aminoglycoside active site FE2+-mediated cleavage metal ion switch Cell- och molekylärbiologi Cell and molecular biology Cell- och molekylärbiologi
16	A novel molecular relationship between PARN and PLD that, when deregulated, contributes to the aggressive phenotype of breast cancer cell lines. Miller, Taylor Elaine 09 May 2017 (has links) No description available. Biochemistry Cellular Biology Molecular Biology PARN polyA-specific ribonuclease deadenylase phospholipase D PLD breast cancer MDA-MB-231 microRNA miR miR-203 mRNA decay post-transcriptional regulation miR-dependent deadenylation

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