Fonction des protéines BTG/TOB dans la désadénylation des ARN messagers eucaryotes

Damaging mRNA, the molecules carrying the genetic information, or altering the mechanisms responsible for their synthesis, their translation or their degradation can be responsible for initiating diseases. It is thus important to understand the mechanisms impacting mRNA, especially their degradation. The latter is initiated by the deadenylation reaction characterized by the progressive shortening of the mRNA 3’ poly(A) tail. One of the complexes responsible for deadenylation is CCR4-NOT. BTG/Tob proteins are able to bind the CAF1 deadenylase of CCR4-NOT via their APRO domain. In this thesis, interaction of BTG2 with PABPC1, the factor binding poly(A) tail, was analyzed. This binding stimulates CAF1 deadenylase activity in vitro and in cellulo. The role of this interaction on the antiproliferative properties of BTG2 and the impact of BTG2 on translation were also investigated. A model explaining deadenylation activation by BTG2 is proposed.Une détérioration des ARNm, le vecteur de l’information génétique, ou une altération des mécanismes régulant leur synthèse, leur traduction, ou leur dégradation peut être responsable de l’apparition d’une maladie. Ainsi, il est important de comprendre les mécanismes affectant les ARNm et notamment leur dégradation. Cette dernière est initiée par la réaction de désadénylation caractérisée par le raccourcissement progressif de la queue poly(A) de l’ARNm. Un complexe responsable de la désadénylation est CCR4-NOT. Les protéines BTG/Tob lient la désadénylase CAF1 de CCR4-NOT via leur domaine APRO. Dans cette thèse, l’interaction de BTG2 avec PABPC1, la protéine liant la queue poly(A), a été étudiée. Cette association augmente l’activité désadénylase de CAF1 in vitro et in cellulo. Le rôle de cette liaison sur les propriétés antiprolifératives de BTG2 et l’impact de BTG2 sur la traduction ont aussi été analysés. Un modèle expliquant l’activation de la désadénylation par BTG2 est proposé

Function of BTG/Tob proteins in messenger RNA deadenylation in eukaryotes

Une détérioration des ARNm, le vecteur de l’information génétique, ou une altération des mécanismes régulant leur synthèse, leur traduction, ou leur dégradation peut être responsable de l’apparition d’une maladie. Ainsi, il est important de comprendre les mécanismes affectant les ARNm et notamment leur dégradation. Cette dernière est initiée par la réaction de désadénylation caractérisée par le raccourcissement progressif de la queue poly(A) de l’ARNm. Un complexe responsable de la désadénylation est CCR4-NOT. Les protéines BTG/Tob lient la désadénylase CAF1 de CCR4-NOT via leur domaine APRO. Dans cette thèse, l’interaction de BTG2 avec PABPC1, la protéine liant la queue poly(A), a été étudiée. Cette association augmente l’activité désadénylase de CAF1 in vitro et in cellulo. Le rôle de cette liaison sur les propriétés antiprolifératives de BTG2 et l’impact de BTG2 sur la traduction ont aussi été analysés. Un modèle expliquant l’activation de la désadénylation par BTG2 est proposé.Damaging mRNA, the molecules carrying the genetic information, or altering the mechanisms responsible for their synthesis, their translation or their degradation can be responsible for initiating diseases. It is thus important to understand the mechanisms impacting mRNA, especially their degradation. The latter is initiated by the deadenylation reaction characterized by the progressive shortening of the mRNA 3’ poly(A) tail. One of the complexes responsible for deadenylation is CCR4-NOT. BTG/Tob proteins are able to bind the CAF1 deadenylase of CCR4-NOT via their APRO domain. In this thesis, interaction of BTG2 with PABPC1, the factor binding poly(A) tail, was analyzed. This binding stimulates CAF1 deadenylase activity in vitro and in cellulo. The role of this interaction on the antiproliferative properties of BTG2 and the impact of BTG2 on translation were also investigated. A model explaining deadenylation activation by BTG2 is proposed

BTG2 bridges PABPC1 RNA-binding domains and CAF1 deadenylase to control cell proliferation

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Degradation-Independent Inhibition of APOBEC3G by the HIV-1 Vif Protein

The ubiquitin–proteasome system plays an important role in the cell under normal physiological conditions but also during viral infections. Indeed, many auxiliary proteins from the (HIV-1) divert this system to its own advantage, notably to induce the degradation of cellular restriction factors. For instance, the HIV-1 viral infectivity factor (Vif) has been shown to specifically counteract several cellular deaminases belonging to the apolipoprotein B mRNA-editing enzyme catalytic polypeptide-like (APOBEC3 or A3) family (A3A to A3H) by recruiting an E3-ubiquitin ligase complex and inducing their polyubiquitination and degradation through the proteasome. Although this pathway has been extensively characterized so far, Vif has also been shown to impede A3s through degradation-independent processes, but research on this matter remains limited. In this review, we describe our current knowledge regarding the degradation-independent inhibition of A3s, and A3G in particular, by the HIV-1 Vif protein, the molecular mechanisms involved, and highlight important properties of this small viral protein

A conserved uORF impacts APOBEC3G translation and is essential for translational inhibition by the HIV-1 Vif protein

ABSTRACT The HIV-1 Vif protein is essential for viral fitness and pathogenicity. Vif decreases expression of cellular cytosine deaminases APOBEC3G (A3G), A3F, A3D and A3H, which inhibit HIV-1 replication by inducing hypermutations during reverse transcription. Vif counteracts A3G by several non-redundant mechanisms (transcription, translation and protein degradation) that concur in reducing the levels of A3G in cell and in preventing its incorporation into viral particles. How Vif affects A3G translation remains unclear. Here, we uncovered the importance of a short conserved uORF (upstream ORF) located within two critical stem-loop structures of the 5′ untranslated region (5′UTR) of A3G mRNA. Extensive mutagenesis of A3G 5′-UTR, combined with an analysis of their translational effect in transfected cells, indicated that the uORF represses A3G translation and that A3G mRNA is translated through a dual leaky-scanning and re-initiation mechanism. Interestingly, the uORF is also mandatory for the Vif-mediated repression of A3G translation. Furthermore, we showed that the redirection of A3G mRNA into stress granules was dependent not only on Vif, but also on the uORF. Overall, we discovered that A3G translation is regulated by a small uORF conserved in the human population and that Vif uses this specific motif to repress its translation

A Conserved uORF Regulates APOBEC3G Translation and Is Targeted by HIV-1 Vif Protein to Repress the Antiviral Factor

International audienceThe HIV-1 Vif protein is essential for viral fitness and pathogenicity. Vif decreases expression of cellular restriction factors APOBEC3G (A3G), A3F, A3D and A3H, which inhibit HIV-1 replication by inducing hypermutation during reverse transcription. Vif counteracts A3G at several levels (transcription, translation, and protein degradation) that altogether reduce the levels of A3G in cells and prevent its incorporation into viral particles. How Vif affects A3G translation remains unclear. Here, we uncovered the importance of a short conserved uORF (upstream ORF) located within two critical stem-loop structures of the 5′ untranslated region (5′-UTR) of A3G mRNA for this process. A3G translation occurs through a combination of leaky scanning and translation re-initiation and the presence of an intact uORF decreases the extent of global A3G translation under normal conditions. Interestingly, the uORF is also absolutely required for Vif-mediated translation inhibition and redirection of A3G mRNA into stress granules. Overall, we discovered that A3G translation is regulated by a small uORF conserved in the human population and that Vif uses this specific feature to repress its translatio