Rôle de la protéine EB2 du virus d'Epstein-Barr dans le métabolisme des ARN messagers / Role of the Epstein-Barr virus protein EB2 in messenger RNA metabolism

Mure, Fabrice

14 December 2016

La régulation post-transcriptionnelle de l’expression génique est basée sur un réseau complexe et dynamique d’interactions ARN-protéines. Un défi important est de comprendre les mécanismes par lesquels ces protéines de liaison à l’ARN (RBPs) influencent chaque étape du métabolisme des ARNm. Les travaux réalisés au cours de cette thèse ont permis de caractériser de nouvelles fonctions de la RBP virale EB2 qui est indispensable à la production du virus d’Epstein-Barr (EBV). Des travaux antérieurs ont montré qu’EB2 favorise l’accumulation cytoplasmique de la majorité des ARNm viraux, dont la caractéristique est d’être transcrit à partir de gènes sans intron. Nous montrons que le rôle d’EB2 ne se limite pas à celui de facteur d’export des ARNm car cette RBP stabilise aussi ses ARNm cibles dans le noyau en les protégeant de la dégradation par l’exosome. Nos résultats indiquent qu’en absence d’EB2 : (i) certains ARNm viraux sont instables car ils contiennent des sites cryptiques d’épissage ; (ii) le facteur d’épissage SRSF3 déstabilise ces ARNm en interagissant à la fois avec l’exosome et le complexe NEXT, un des cofacteurs nucléaires de l’exosome. Par ailleurs, nous montrons également qu’EB2 est associée aux polysomes et stimule efficacement la traduction de ses ARNm cibles, en interagissant avec les facteurs d’initiation de la traduction eIF4G et PABP. Le développement d’un nouveau système de traduction in vitro nous a permis de montrer que l’effet d’EB2 sur la traduction nécessite le passage nucléaire de ses ARNm cibles. Ainsi, l’ensemble de nos travaux démontre le rôle clé d’une RBP virale dans le couplage entre les étapes nucléaires et cytoplasmiques de la biogenèse des ARNm. / Post-transcriptional regulation of gene expression is based on a complex and dynamic network of RNA-proteins interactions. A major challenge is to understand the precise contribution of these RNA-binding proteins (RBPs) to each step of mRNA metabolism. During this thesis, we have characterized new functions of the EB2 viral RBP which is essential for the production of the Epstein-Barr virus (EBV). Previous works have shown that EB2 promotes cytoplasmic accumulation of most intronless viral mRNAs. Here, we show that EB2 is not just an mRNA export factor because this RBP also stabilizes its target mRNAs in the nucleus by protecting them from RNA exosome degradation. Our results indicate that in the absence of EB2 : (i) some viral mRNAs are unstable because they contain cryptic splice sites ; (ii) the splicing factor SRSF3 destabilizes these mRNAs by interacting with both the RNA exosome and the Nuclear EXosome Targeting (NEXT) complex. Moreover, we also show that EB2 is associated with polysomes and it strongly stimulates translation of its target mRNAs through interactions with the eIF4G and PABP initiation factors. Interestingly, the development of a new in vitro translational assay allowed us to show that EB2’s translation stimulation requires that EB2 binds its target mRNAs in the nucleus. Taken together, our works demonstrate the key function of a viral RBP in the coordination of the nuclear and cytoplasmic steps of mRNA biogenesis.

Protéines de liaison à l’ARN

Herpèsvirus

Dégradation des ARNm

Traduction

RNA-binding proteins

Herpesvirus

MRNA decay

Translation

Biochemical and Functional Characterization of Novel RNA-binding Proteins Interacting with SMN in Motor Neuron-derived Cells

Laframboise, Janik

January 2013

Spinal muscular atrophy is an autosomal recessive genetic disease that results from the loss and/or degeneration of alpha motor neurons in the lower part of the spinal cord. With ~ 1 in 6000 live births per year being affected, this disease is the second leading cause of infant death and is caused by the loss or decrease of the Survival of Motor Neuron protein (SMN). While a lot is known about the role that SMN plays in the cytoplasmic assembly of spliceosomal small nuclear ribonucleoproteins (snRNPs), it remains a crucial question in the field to gain a better understanding of what specific/distinct function(s) SMN might have in motor neurons. We have identified novel interactions between SMN and two RNA-binding proteins (RBPs) known to be components of axonal RNA granules. More specifically, we demonstrated that SMN interacts with HuD and SERBP1 in a direct fashion in foci-like structures along neurites of motor neuron-derived cells. We have also demonstrated that the SMN/HuD interaction is required for the localization of HuD into RNA granules in neurites of motor neuron-derived cells. Furthermore, I have shown that SERBP1 is down-regulated in the absence of normal levels of SMN and, most importantly, that over-expression of SERBP1 can rescue SMA-like neuronal defects using a cell culture model of the disease. These findings may help shed light on the non-canonical molecular pathway(s) involving SMN and RBPs in motor neurons and underscores the possible therapeutic benefits of targeting these RBPs in the treatment of SMA.

Spinal muscular atrophy

HuD

SERBP1

SMN

Arginine methylation

RNA-binding protein

Novel Functions for the RNA-binding Protein Staufen1 in Skeletal Muscle Biology and Disease

Crawford Parks, Tara

January 2016

Over the past decade several converging lines of evidence have highlighted the importance of post-transcriptional events in skeletal muscle. This level of regulation is controlled by multi-functional RNA-binding proteins and trans-acting factors. In fact, several RNA-binding proteins are implicated in neuromuscular disorders including myotonic dystrophy type I, spinal muscular atrophy and amyotrophic lateral sclerosis. Therefore, it is necessary to examine the impact of RNA-binding proteins during skeletal muscle development and plasticity in order to understand the consequences linked to their misregulation in disease. Here, we focused on the RNA-binding protein Staufen1, which assumes multiple roles in both skeletal muscle and neurons. We previously demonstrated that Staufen1 is regulated during myogenic differentiation and that its expression is increased in denervated and in myotonic dystrophy type I skeletal muscles. The increased expression of Staufen1 initially appeared beneficial for DM1 since further elevating Staufen1 levels rescued key hallmarks of the disease. However, based on the multi-functional nature of Staufen1, we hypothesized that Staufen1 acts as a disease modifier in DM1. To test this, we investigated the roles of Staufen1 in skeletal muscle biology and their implications for disease. Our data demonstrated that Staufen1 is required during the early stages of muscle development, however its expression must remain low in postnatal skeletal muscle. Interestingly, the overexpression of Staufen1 impaired myogenesis through the regulation of c-myc translation. Since the function of c-myc in oncogenesis is well described, we investigated the role of Staufen1 in cancer biology. In particular, we determined novel functions of Staufen1 in rhabdomyosarcoma tumorigenesis, thus providing the first direct evidence for Staufen1’s involvement in cancer. Moreover, based on Staufen1’s role in myogenic differentiation and in myotonic dystrophy type I, we generated muscle-specific transgenic mice to examine the impact of sustained Staufen1 expression in postnatal skeletal muscle. Staufen1 transgenic mice developed a myopathy characterized by histological and functional abnormalities via atrogene induction and the regulation of PTEN mRNAs. In parallel, we further investigated Staufen1-regulated alternative splicing and our data demonstrated that Staufen1 regulates multiple alternative splicing events in normal and myotonic dystrophy type I skeletal muscles, both beneficial and detrimental for the pathology. Collectively, these findings uncover several novel functions of Staufen1 in skeletal muscle biology and highlight Staufen1’s role as a disease modifier in DM1.

RNA-binding Proteins

Staufen1

Skeletal Muscle

Myotonic Dystrophy Type I

Rhabdomyosarcoma

Alternative Splicing

Étude in vivo de la fonction biologique de la protéine de liaison aux ARN Mex-3B / In vivo study of the biological functions of the RNA-binding protein Mex-3B

Le Borgne, Maïlys

20 September 2012

La protéine de liaison aux ARN MEX-3 est un régulateur essentiel du développement embryonnaire chez le nématode Caenorhabditis elegans. Une famille de quatre gènes homologues à hMex-3 (dénommés hMex-3A, 3B, 3C et 3D) a été identifiée chez les mammifères par notre équipe. Afin de mieux comprendre la fonction physiologique in vivo des protéines Mex-3, nous avons invalidé le gène Mex-3B chez la souris. Cette approche expérimentale a révélé que Mex-3B est un acteur majeur de la spermatogenèse. Les souris mâles nullizygotes présentent une obstruction des tubes séminifères conduisant à une réduction importante du nombre des spermatozoïdes produits. L’ablation de Mex-3B ciblée à la cellule de Sertoli, cellule somatique essentielle à la fonction de l’épithélium séminifère, a permis d’établir que le phénotype testiculaire a pour origine une perturbation des propriétés biologiques de cette cellule. En effet, les cellules de Sertoli déficientes pour Mex-3B présentent des défauts de la phagocytose qui conduisent à une élimination défectueuse des corps résiduels au cours de la spemiogenèse. L’exploration des mécanismes moléculaires impliqués a montré que Mex-3B contrôle la phagocytose via la régulation de l’activité et de la localisation membranaire de Rap1GAP, une protéine qui régule négativement la petite protéine G Rap1. En accord avec ces données, l’absence de Mex-3B provoque une déstabilisation de la barrière hémato-testiculaire due à un défaut de localisation à la membrane plasmique des molécules de jonction connexine 43 et N-Cadhérine, protéines dont la translocation et la stabilité dépendent de Rap1. En conclusion, mes travaux de thèse ont permis de mettre en évidence un rôle clé de Mex-3B dans le contrôle spatial de la voie de signalisation Rap1 au cours de la spermatogenèse / The RNA binding-protein MEX-3 is a post-transcriptional regulator involved in early embryogenesis of the nematode Caenorhabditis elegans. We have recently reported the characterization of a novel family of four mammalian genes homologous to hMex-3 (called hMex-3A, 3B, 3C and 3D). To gain insight into the biological functions of these proteins in vivo, we disrupted the Mex-3B gene in mice. Using this experimental approach, we found that Mex-3B is as a major regulator of spermatogenesis. We observed that male Mex-3B null mice hypofertile and present an obstruction of seminiferous epithelium. Phagocytic properties of Sertoli cells were impaired, thus impeding the clearance of residual bodies released during spermiogenesis. Exploration of the underlying molecular mechanisms revealed that Mex-3B regulates phagocytosis through the activation and the transport at the peripheral membrane of Rap1GAP, a protein that downregulates the small G protein Rap1. Consistently, the Rap1-dependent recruitment of the junction proteins, connexin 43 and N-Cadherin at the cell surface was compromised in Mex-3B deficient mice. In conclusion, my work highlights a key role gor Mex-3B in the spatial control of Rap1 signaling during spermatogenesis

Protéine de liaison aux ARN

ARNm

Spermatogenèse

Polarité cellulaire

RNA binding-protein

MRNA

Spermatogenesis

Cell polarity

572.633

Rôle du domaine de type prion de Imp dans la régulation des granules RNP neuronaux / Role of the Prion-like domain of Imp in neuronal RNP granule regulation

Vijayakumar, Jeshlee Cyril

13 November 2018

Les ARNms des cellules eucaryotes sont liés à des protéines de liaison aux ARNs (RBPs) et empaquetés au sein d’assemblages macro-moléculaires appelés granules RNP. Dans les cellules neuronales, les granules RNP de transport sont impliqués dans le transport d’ARNms spécifiques jusqu’aux axones et dendrites, ainsi que dans leur traduction locale en réponse à des signaux externes. Bien que peu de choses soient connues sur l’assemblage et la régulation de ces granules in vivo, des résultats récents ont indiqué que la présence de domaines de type prion (PLDs) dans les RBPs facilite les interactions protéines-protéines et protéines-ARN, favorisant ainsi la condensation de complexes solubles en granules RNP. La RBP conservée Imp est un composant central de granules RNP qui sont transportés dans les axones lors du remodelage neuronal chez la drosophile. De plus, la fonction de Imp est nécessaire au remodelage des axones lors de la maturation du système nerveux de drosophile. Une analyse de la séquence de la protéine Imp a révélé qu’en plus de quatre domaines de liaison aux ARNs, Imp contient un domaine C-terminal désordonné enrichi en Glutamines et Serines, deux propriétés caractéristiques des domaines PLDs. Lors de ma thèse, j’ai étudié la fonction de ce PLD dans le contexte de l’assemblage et du transport des granules RNP. J’ai observé en culture de cellules que les granules Imp s’assemblent en absence de PLD, bien que leur nombre et leur taille soient augmentés. Des protéines présentant une séquence PLD mélangée, au contraire, s’accumulent dans des granules au nombre et à la taille normale, indiquant que l’état désordonné de ce domaine, et non sa séquence primaire, est essentiel à l’homéostasie des granules. De plus, des expériences de FRAP réalisées en culture de cellule et in vivo ont révélé que le domaine PLD de Imp favorise la dynamique des granules. In vivo, ce domaine est nécessaire et suffisant à l’accumulation axonale de Imp. Comme montré par une analyse en temps réel, l’absence de domaine PLD aboutit également à une diminution du nombre de granules axonaux motiles. Fonctionnellement, le domaine PLD de Imp est essentiel au remodelage neuronal car des protéines sans ce domaine ne sont pas capables de supprimer les défauts de repousse axonale observés après inactivation de imp. Enfin, la génération d’un variant de Imp dans lequel le domaine PLD a été déplacé en N-terminus a montré que les fonctions du PLD dans le transport des granules et dans leur assemblage sont découplées, et que la modulation des propriétés des granules Imp médiée par le domaine PLD n’est pas nécessaire au remodelage neuronal in vivo. En conclusion, mes résultats ont montré que le domaine PLD de Imp n’est pas nécessaire à l’assemblage des granules RNP Imp, mais régule leur nombre et leur dynamique. De plus, mon travail a mis en évidence une fonction inattendue pour un domaine PLD dans le transport axonal et le remodelage des neurones lors de la maturation du système nerveux. / Eukaryotic mRNAs are bound by RNA Binding Proteins (RBP) and packaged into diverse range of macromolecular assemblies named RNP granules. In neurons, transport RNP granules are implicated in the transport of specific mRNAs to axons or dendrites, and in their local translation in response to external cues. Although little is known about the assembly and regulation of these granules in vivo, growing evidence indicates that the presence of Prion Like domains (PLD) within RBPs favours multivalent protein–protein and protein-RNA interactions, promoting the transition of soluble complexes into RNP granules. The conserved RBP Imp is as a core component of RNP granules that are actively transported to axons upon neuronal remodelling in Drosophila. Furthermore, Imp function was shown to be required for axonal remodelling during Drosophila nervous system maturation. Analyses of the domain architecture of the Imp protein revealed that, in addition to four RNA binding domains (RBD), Imp contains a Cterminal domain showing a striking enrichment in Glutamines and Serines, which is one of the characteristics of a PLD. During my PhD, I explored the function of the PLD in the context of granule assembly and transport. In cultured cells, I observed that Imp granules assembled in the absence of the PLD, however their number and size were increased. Proteins with scrambled PLD sequence accumulated in granules of normal size and number, implying that the degree of disorder of this domain, and not its sequence, is essential for granule homeostasis. Moreover, FRAP experiments, performed on cultured cells and in vivo, revealed that Imp PLD is important to maintain the turnover of these granules. In vivo, this domain is both necessary and sufficient for efficient transport of Imp granules to axons. These defects are associated with a reduction on the number of motile granules in axons. Furthermore, mutant forms lacking the PLD do not rescue the axon remodelling defects observed upon imp loss of function. Finally, a swapping experiment in which I moved Imp PLD from the C-terminus to the N-terminus of the protein revealed that the functions of Imp PLD in granule transport and homeostasis are uncoupled, and that PLD-dependent modulation of Imp granule properties is dispensable in vivo. Together, my results show that Imp PLD of is not required for the assembly of RNP granules, but rather regulates granule number and dynamics. Furthermore, my work uncovered an unexpected in vivo function for a PLD in axonal transport and remodelling during nervous system maturation.

Drosophile

Protéine de liaison à l’ARN

Granule neuronale

RNP transport

Drosophila

RNA binding proteins

Neuronal granules

RNP transport

Emerging role of RNA-binding proteins in sporadic and rapid progressive Alzheimer’s disease

Younas, Neelam

14 January 2020

No description available.

610

Molecular Medicine

RNA-binding motifs of hnRNP K are critical for induction of antibody diversification by activation-induced cytidine deaminase / hnRNP KのRNA結合モチーフはAIDによる抗体多様性に必須である

Yin, Ziwei

27 July 2020

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第22698号 / 医科博第113号 / 新制||医科||8(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 竹内 理, 教授 椛島 健治, 教授 河本 宏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

activation-induced cytidine deaminase

RNA-binding motifs

DNA breaks

IgH

491

Investigating the Role of RNA-Binding Protein 5 in the Life Cycle Differentiation of Trypanosoma Brucei

Anaguano Pillajo, David

25 October 2018

Trypanosomatid parasites such as Trypanosoma brucei have unusual mechanisms of gene expression including polycistronic transcription, mitochondrial RNA editing and trans-splicing. Additionally, these protists rely mainly on post-transcriptional regulation where RNA-binding proteins (RBP) have shown to play a major role. RBP6 and RBP10 are two examples of RBPs that play crucial roles in procyclic and bloodstream form parasites differentiation respectively, by post-transcriptional regulation. Over-expression of RBP6 is enough to promote differentiation into metacyclic trypomastigotes that are infective to mice. However, continuous expression is required, and this pattern does not reflect the natural expression in the tsetse fly or the influence of other RNA-binding proteins. RBP5 is a RBP with a single RNA-recognition motif similar to RBP6 and RBP10, whose expression is upregulated during the life stages within the salivary glands of tsetse flies. We hypothesize the RBP5 facilitates metacyclogenesis in the tsetse fly. To evaluate possible contributions to T. brucei differentiation, we will over-express RBP5 in procyclic cells alone and in combination with RBP6. Initial screening of cells over-expressing PTP-tagged RBP5 resulted in parasites with a moderate growing defect, and the scoring of nuclei and kinetoplasts in fixed cells showed a progressive accumulation of cells with 2 nuclei and 2 kinetoplasts (2N2K) and appearance of multinucleated cells. On the other hand, over-expression of non-tagged RBP5 generated a more severe growing defect, starting immediately after the first day of induction. The scoring of nuclei and kinetoplasts resulted in a drastic increase of 2N2K cells and a greater appearance of multinucleated cells, which suggests an irregular cell cycle progression. When developing the dual over-expression system, our cells over-expressing RBP6 were not able to differentiate into any stage, and when over-expressing RBP5 and RBP6 coordinately, no differentiation process was observed either. Together these data suggest that RBP5 might be a regulator of genes involved in the initiation of cytokinesis in T. brucei parasites, however a role in metacyclogenesis cannot be discarded since we were not able to obtain metacyclic parasites. This study helped us to get a better understanding of the post-transcriptional regulatory mechanisms that repress and regulate T. brucei cell cycle progression.

RNA-binding protein

RBP5

Trypanosoma brucei

over-expression

cell cycle

cytokinesis

Molecular Biology

Parasitology

The dynamic RNA-binding behavior of SR proteins

Brugiolo, Mattia

12 October 2015

In the cell, the genetic information encoded in the DNA is transcribed to RNA. All RNAs that are transcribed in the cell are initially produced as precursor RNAs, which have to undergo various steps of processing to obtain their mature form. The maturation and processing for all RNA classes requires the activity of multiple RNA binding proteins (RBPs). An important family of RBPs that is involved in RNA maturation and processing is the SR-protein family. SR proteins are important for the regulation of a multitude of processes that include: splicing, transcription, export, RNA stabilization, translation and ncRNA processing. As of yet, there have been no comprehensive studies that describe how SR proteins dynamically regulate the maturation of RNAs. The results presented in this thesis provide new insights into the function and activity of SR proteins during RNA maturation. My experiments greatly expand the knowledge surrounding the action of RNA-binding proteins in vivo and in different cell compartments. To study the action of two different SR proteins in different cell compartments, I developed a new technique that combines cell fractionation and iCLIP, which I named FRACKING. For the first time, this method allowed me to collect information regarding the subcellular location where the RNA-protein interactions are taking place, giving a dynamic picture of the in vivo binding of SR proteins and of RNA binding proteins (RBP) in general. By using FRACKING on two heavily shuttling SR proteins, SRSF3 and SRSF7, I showed that both SR proteins are very dynamic in their binding behavior with RNAs. My research showed that both SRSF3 and SRSF7 strongly associate with RNAs during transcription (co-transcriptionally) and that they often remain bound to these transcripts until they are exported to the cytoplasm. The functions of SRSF3 and SRSF7 are closely related to their binding location on the target RNAs. I identified a subset of highly conserved introns that associated with SR proteins and are retained in their transcripts. These intron-retaining isoforms, contrary to textbook knowledge, are exported to the cytoplasm. I showed, for the first time, that SRSF3 and SRSF7 strongly interact with snoRNAs in the chromatin, and that this snoRNA-SR-protein binding behavior is distinct between SRSF3 and SRSF7. SRSF3 binds to the mature snoRNA sequence, and also to the surrounding intronic sequences, pointing towards a possible activity in guiding snoRNA maturation. Whereas SRSF7 associates to mature snoRNA sequences. Taken together, my study identified a dynamic pool of interactions for two SR proteins, in different cell compartments and discovered new activities for the two SR proteins. Importantly, this study challenges textbook knowledge on splicing and export of mRNAs by identifying a subset of transcripts that can be exported even when they retain introns.

info:eu-repo/classification/ddc/570

ddc:570

RNA, iCLIP, SRSF3, SRSF7

RNA-binding, iCLIP, SRSF3, SRSF7

The Role of Human Antigen R (HuR) in Pathological Cardiac Remodeling

Green, Lisa

24 May 2022

No description available.

Organismal Biology

Cardiac fibrosis

HuR

fibroblast

RNA binding protein

Cardiac hypertrophy

Wisp1