57 research outputs found

    Insights into the RNA polymerase activity of the dengue virus NS5

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    Le virus de la dengue cause une maladie de type grippal qui peut dans certains cas évoluer vers des fièvreshémorragiques mortelles. Mon projet de thèse porte sur la réplication de ce virus. Je focalise sur la compréhension du mécanisme d'action de la protéine NS5 de ce virus. La protéine contient 2 domaines : 1) domaine méthyltransférase, essentiel pour la traduction des protéines virales, 2) domaine polymérase, synthétisant le génome ARN du virus. Premièrement, nous avons démontré que la polymérase joue un rôle principal dans la conservation de l'extrémité 3' et 5' du génome et de l'anti-génome. Puis, j'ai caractérisé l'influence du domaine méthyltransférase sur l'activité polymérase de la protéine NS5. J'ai développé un système d'études mécanistiques en utilisant des techniques biochimiques de cinétique pré-stationnaire pour la protéine NS5, et obtenu des paramètres cinétiques et thermodynamiques de cette protéine envers ses substrats. Avec ce même système, j'ai pu tester des activités de la polymérase NS5 avec des ARN coiffés et triphosphates de différente longueur, mimant les séquences à l'extrémité 5' du génome du virus de la dengue. L'activité polymérase de NS5 est influencée par la présence de la coiffe de l'ARN, ce qui m'a permis de proposer une distance physique correspondant à environ 13 nucléotides entre les sites actifs domaines méthyltransférase et polymérase. Mes travaux ouvrent la voie à la détermination de la structure 3D de NS5 avec ses ARN et des nucléotides 5'-triphosphate.Elucider son mécanisme d'action, c'est être capable d'inhiber son action et donc de pouvoir proposer des molécules capables d'arrêter la prolifération virale lors d'une infection.Dengue virus causes dengue fever, which may evolve towards life-threatening hemorrhagic fever. My research projectfocuses on dengue replication, and more precisely on the mechanism of NS5 at the molecular/atomic level. NS5 is a bifunctionalenzyme containing two domains: 1) a methyltransferase domain essential for translation of viral proteins, 2) apolymerase domain synthesizing the viral RNA genome. First, we demonstrated the main role of the polymerase in theconservation of 5' and 3' ends of dengue genome and anti-genome RNAs. Next, I showed the influence of themethyltransferase domain on the activity of the polymerase domain. I also developed a system allowing mechanistic studiesusing pre-steady state kinetics to characterize NS5 in depth. I have made use of this system to determine the catalyticparameters of NS5 towards its substrates. Using the same pre-steady state system, I was able to test the polymerase activityof NS5 with capped and uncapped 5'-triphosphate RNAs of different lengths corresponding to the 5'-end of the dengue RNAgenome. The polymerase activity of NS5 is significantly affected by the presence of the 5'-cap, which allowed me to designan experimental set-up pointing to a minimal physical distance of around 13 nucleotides between the methyltransferase andpolymerase active sites. My work will be useful to characterize the biophysics of NS5 in complex with its RNA and NTPsubstrates, and then to determine the crystal structure of such complex at play during viral RNA synthesis. Knowing thedetailed NS5 mechanism paves the way to inhibit its action and thus design drugs aiming at stopping a viral infection

    Structural and Functional Basis of the Fidelity of Nucleotide Selection by Flavivirus RNA-Dependent RNA Polymerases

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    Viral RNA-dependent RNA polymerases (RdRps) play a central role not only in viral replication, but also in the genetic evolution of viral RNAs. After binding to an RNA template and selecting 5′-triphosphate ribonucleosides, viral RdRps synthesize an RNA copy according to Watson-Crick base-pairing rules. The copy process sometimes deviates from both the base-pairing rules specified by the template and the natural ribose selectivity and, thus, the process is error-prone due to the intrinsic (in)fidelity of viral RdRps. These enzymes share a number of conserved amino-acid sequence strings, called motifs A–G, which can be defined from a structural and functional point-of-view. A co-relation is gradually emerging between mutations in these motifs and viral genome evolution or observed mutation rates. Here, we review our current knowledge on these motifs and their role on the structural and mechanistic basis of the fidelity of nucleotide selection and RNA synthesis by Flavivirus RdRps

    Substrate selectivity of Dengue and Zika virus NS5 polymerase towards 2′-modified nucleotide analogues

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    International audienceIn targeting the essential viral RNA-dependent RNA-polymerase (RdRp), nucleotide analogues play a major role in antiviral therapies. In the Flaviviridae family, the hepatitis C virus (HCV) can be eradicated from chronically infected patients using a combination of drugs which generally include the 2'-modified uridine analogue Sofosbuvir, delivered as nucleotide prodrug. Dengue and Zika viruses are emerging flaviviruses whose RdRp is closely related to that of HCV, yet no nucleoside drug has been clinically approved for these acute infections. We have purified dengue and Zika virus full-length NS5, the viral RdRps, and used them to assemble a stable binary complex made of NS5 and virus-specific RNA primer/templates. The complex was used to assess the selectivity of NS5 towards nucleotide analogues bearing modifications at the 2'-position. We show that dengue and Zika virus RdRps exhibit the same discrimination pattern: 2'-O-Me > 2'-C-Me-2'-F > 2'-C-Me nucleoside analogues, unlike HCV RdRp for which the presence of the 2'-F is beneficial rendering the discrimination pattern 2'-O-Me > 2'-C-Me ≥ 2'-C-Me-2'-F. Both 2'-C-Me and 2'-C-Me-2'-F analogues act as non-obligate RNA chain terminators. The dengue and Zika NS5 nucleotide selectivity towards 2'-modified NTPs mirrors potency of the corresponding analogues in infected cell cultures

    Stratégies de formation de la structure coiffe chez les virus à ARN

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    La plupart des virus utilisent la machinerie de traduction dépendante de la coiffe pour assurer l’expression de leurs ARN messagers (ARNm). L’addition d’une structure coiffe à l’extrémité 5’ des ARNm viraux est par conséquent une étape essentielle pour la réplication de nombreux virus. En effet, la coiffe protège les ARNm de la dégradation par les nucléases cellulaires et neutralise la détection des ARNm viraux par les mécanismes de l’immunité innée. L’acquisition de la coiffe des ARN viraux se fait soit en utilisant les enzymes cellulaires de formation de la coiffe de la cellule infectée ou en subtilisant la coiffe des ARNm de la cellule infectée, soit par des machineries enzymatiques virales dédiées. De nombreuses enzymes virales impliquées dans la synthèse de la coiffe ont récemment été caractérisées du point de vue structural et fonctionnel. Ces études ont révélé des mécanismes de synthèse originaux qui ouvrent la voie pour le développement d’inhibiteurs spécifiques à potentiel antiviral

    Dengue Virus NS5 Transcribes Metabolite-Capped, RIG-I Sensitive vRNAs

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    International audienceEukaryotic nuclear and mitochondrial RNA polymerases (RNAPs) can cap RNAs by initiating with the non-canonical initiating nucleotide (NCIN) nicotinamide adenine dinucleotide (both NAD+ and NADH). Similarly, recently Dengue viral RNAs (vRNA) have been observed with NCIN caps, but how these vRNAs are capped is unknown. Here we show directly that Dengue virus's (DENV) RNAP NS5 can utilize both NAD+ and NADH, as well as flavin adenine dinucleotide and dephospho-coenzyme A, as initiating nucleotides during RNA transcription in place of DENV's well-conserved initiating adenine. In addition, we demonstrate that NCIN-capped dsRNAs can bind to the innate immune receptor RIG-I with KD's between 3 and 6 nM. RIG-I can also use these NCIN-capped dsRNAs to initiate robust interferon production. Taken with the previously published results that NAD+-capped mRNAs cannot be translated, we propose that NCIN-capped DENV vRNA represents a newly discovered mechanism of metabolite-mediated immunity that generates translation-deficient, highly immunogenic vRNAs

    BIOCHEMICAL AND STRUCTURAL CHARACTERIZATION OF L POLYMERASE PROTEIN FROM LCMV

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    International audienceThe Arenaviridae family is composed of negative single-stranded RNA viruses with a bi-segmented genome and includes some of the world’s deadliest human viruses. The lymphocyticchoriomeningitis virus (LCMV) is one of the most studied arenaviruses and is a human pathogen of neglected clinical relevance, causing mild infections to central nervous system disease,congenital malformation, choriomeningitis, and systemic and highly fatal infection in immuno-compromised patients. The only licensed drug for the treatment of human arenavirus infectionis the broad-spectrum antiviral ribavirin, which reduces morbidity and mortality, but displays mixed success in treating the disease and is associated with significant toxicities. Arenaviridaegenome codes for 4 proteins, among which L is the large multi-functional protein including an endonuclease and a RNA polymerase. Among these proteins, the nucleoprotein (NP) is also amajor actor of the viral life cycle involved in polymerization and viral RNA protection and constitutes the last line of defense of the viral genome by degrading dsRNA, a marker of viralinfection. The RNA genome (and complementary) is always encapsulated in a polymer of NP forming the ribonucleoprotein complex RNP. The conserved 5’-3’ end of each segment, thatare complementary to each other, forms a panhandle structure at the end of the viral genome, on which the L polymerase binds, this RNP-L complex constituting the replication-transcription complex (RTC). To gain insights into how this system works, it is essential to characterize the structure of this RNP-L complex using powerful techniques such as crystallographyand Cryo-Electron microscopy, in addition to the characterization of its activity. To do that, we will purify the full-length L polymerase of LCMV and test his activity in RNA synthesis assayswhile studying the structure of the RNP-L complex. These findings will be essential for the development of future antiviral therapy against arenaviruses

    The RNA helicase, nucleotide 5′-triphosphatase, and RNA 5′-triphosphatase activities of Dengue virus protein NS3 are Mg2+-dependent and require a functional Walker B motif in the helicase catalytic core

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    AbstractThe nonstructural protein 3 (NS3) of Dengue virus (DV) is a multifunctional enzyme carrying activities involved in viral RNA replication and capping: helicase, nucleoside 5′-triphosphatase (NTPase), and RNA 5′-triphosphatase (RTPase). Here, a 54-kDa C-terminal domain of NS3 (ΔNS3) bearing all three activities was expressed as a recombinant protein. Structure-based sequence analysis in comparison with Hepatitis C virus (HCV) helicase indicates the presence of a HCV-helicase-like catalytic core domain in the N-terminal part of ΔNS3, whereas the C-terminal part seems to be different. In this report, we show that the RTPase activity of ΔNS3 is Mg2+-dependent as are both helicase and NTPase activities. Mutational analysis shows that the RTPase activity requires an intact NTPase/helicase Walker B motif in the helicase core, consistent with the fact that such motifs are involved in the coordination of Mg2+. The R513A substitution in the C-terminal domain of ΔNS3 abrogates helicase activity and strongly diminishes RTPase activity, indicating that both activities are functionally coupled. DV RTPase seems to belong to a new class of Mg2+-dependent RTPases, which use the active center of the helicase/NTPase catalytic core in conjunction with elements in the C-terminal domain

    The methyltransferase domain of dengue virus protein NS5 ensures efficient RNA synthesis initiation and elongation by the polymerase domain

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    International audienceViral RNA-dependent RNA polymerases (RdRps) responsible for the replication of single-strand RNA virus genomes exert their function in the context of complex replication machineries. Within these replication complexes the polymerase activity is often highly regulated by RNA elements, proteins or other domains of multi-domain polymerases. Here, we present data of the influence of the methyltrans-ferase domain (NS5-MTase) of dengue virus (DENV) protein NS5 on the RdRp activity of the polymerase domain (NS5-Pol). The steady-state polymerase activities of DENV-2 recombinant NS5 and NS5-Pol are compared using different biochemical assays allowing the dissection of the de novo initiation, transition and elongation steps of RNA synthesis. We show that NS5-MTase ensures efficient RdRp activity by stimulating the de novo initiation and the elongation phase. This stimulation is related to a higher affinity of NS5 toward the single-strand RNA template indicating NS5-MTase either completes a high-affinity RNA binding site and/or promotes the correct formation of the template tunnel. Furthermore, the NS5-MTase increases the affinity of the priming nucleotide ATP upon de novo initiation and causes a higher catalytic efficiency of the polymerase upon elongation. The complex stimulation pattern is discussed under the perspective that NS5 adopts several conforma-tions during RNA synthesis
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