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

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

Drosophila UNR: a factor involved in the translational regulation of dosage compensation

Abaza, Irina

03 November 2006

Dosage compensation is a mechanism that equalizes the expression of X-linked genes in those organisms in which males and females differ in the number of X chromosomes. In Drosophila melanogaster, dosage compensation is achieved by up-regulating the transcription of the single male X chromosome. This effect is mediated by a chromatin remodeling complex known as the Male Specific Lethal (MSL) complex or Dosage Compensation Complex (DCC). In female flies, dosage compensation is inhibited primarily because of the translational repression of the mRNA encoding one of the DCC subunits, MSL-2, by the female-specific RNA binding protein Sex-lethal (SXL). To inhibit translation, SXL binds to poly(U) stretches present in both the 5’ and 3’ UTRs of msl-2 mRNA. Sequences adjacent to those SXL-binding sites in the 3´UTR are also required for translation inhibition and are bound by co-repression. In this thesis work, we have designed an affinity chromatography assay to isolate the putative co-repressor(s), and have identified the protein Upstream of N-ras (UNR). Drosophila UNR (dUNR) is an ubiquitous, conserved protein that contains 5 cold shock domains (CSD) and a glutamine- (Q) rich amino- terminal extension. We show that dUNR is a necessary co-factor for SXL-mediated msl-2 repression. SXL recruits dUNR to the 3’ UTR of msl-2 mRNA, imparting a sex-specific function to this ubiquitous protein. Domain mapping experiments indicate that dUNR interacts with SXL and msl-2 mRNA through CSD1, and that the domains for translation inhibition and SXL interaction can be distinguished. Our data indicate that the Q-rich domain, together with CSDs 1 and 2, plays an important role in translational repression, and suggest that factors in addition to dUNR and SXL are required for repression of msl-2 mRNA. Using a combination of UNR immunoprecipitation and microarray analysis, we have identified the mRNAs that are bound to dUNR in male and female flies. Our results suggest that dUNR is not only a novel regulator of dosage compensation, but also a general post-transcriptional regulator of gene expression.

translation

initiation

translational control

5’UTR binding proteins

3’ UTR binding proteins

SXL

dosage compensation

msl-2

UNR

poly(A) tail and PABP

microarrays

co-repressors

575

Caracterização de interações entre subunidades do complexo de iniciação da tradução EIF4F e homólogos da proteína de ligação ao poli-A (PABP) de Leishmania sp / Characterization of interactions between the subunits of the translation initiation of the eIF4F complex and homologues of poly A binding protein (PABP) of Leishmania sp

Xavier, Camila Cavalcanti

January 2015

Made available in DSpace on 2016-05-19T13:08:18Z (GMT). No. of bitstreams: 2 199.pdf: 2457764 bytes, checksum: f3219878be3144c523ae28e85c474b10 (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2015 / Fundação Oswaldo Cruz. Centro de Pesquisas Aggeu Magalhães. Recife, PE, Brasil / Os tripanossomatídeos são caracterizados por processos moleculares diferenciados como a transcrição policistrônica e regulação pós-transcricional da expressão gênica. Em mamíferos, a tradução se inicia com a ligação do complexo eIF4F (formado pelos eIF4A, eIF4E e eIF4G) a extremidade 5' dos mRNAs, o que facilita seu reconhecimento pelo ribossomo. A atividade do eIF4F é reforçada pela proteína de ligação a cauda poli-A (PABP), na extremidade 3' dos mRNAs, que interage com o eIF4G. Dois complexos do tipo eIF4F foram identificados em tripanossomatídeos: o primeiro formado pelos EIF4G3, EIF4E4 e EIF4AI com a PABP1; e um outro baseado na interação do EIF4G4 com o EIF4E3 e o EIF4A1. Este trabalho buscou caracterizar as interações entre as subunidades destes complexos e sua associação com PABPs de Leishmania, avaliando o efeito de mutações em motivos específicos. Proteínas recombinantes foram geradas fusionadas a GST e avaliadas quanto a sua habilidade de interagir com parceiros marcados radioativamente em ensaios do tipo pull-down. Para o EIF4G3, mutações individuais em dois resíduos vizinhos (I8A e R9A), afetaram a interação com o EIF4E4 e a mutação de ambos os resíduos equivalentes do EIF4G4 (IL25-26AA) também impediu sua ligação ao EIF4E3, sugerindo um motivo comum para a ligação aos seus parceiros. As proteínas EIF4E3 e EIF4E4 foram avaliadas quanto à capacidade de interagir com a PABP2 e PABP1 respectivamente, e mutações em motivos conservados nas regiões N-terminais dos EIF4E (Boxes A, B e C) aboliram sua interação com os homólogos da PABP. Para identificar que regiões da PABP1 estão relacionadas às interações com o parceiro EIF4E4, foram obtidas proteínas PABP1 mutantes em motivos conservados e observou-se que a mutação no motivo TGM, C-terminal, aboliu sua interação com o EIF4E4. Com estas abordagens conseguiu-se avançar na definição das interações entre as referidas subunidades do eIF4F e PABP, identificando-se diferenças relevantes em relação a outros eucariotos

Leishmania

Fator de Iniciação 4F em Eucariotos

Ligação Proteica

Subunidades Proteicas/metabolismo