Variations in the Ssegment of Rift Valley fever virus with special reference to the nonstructural NSs coding region

Aitken, Susan Claire

04 May 2009

Rift Valley fever virus (RVFV) is a Phlebovirus member of the Bunyaviridae family and it is the causative agent of Rift Valley fever (RVF), a mosquito-borne viral zoonotic disease that poses a significant threat to domestic ruminants and human health in Africa. The RVFV is an encapsulated, negative-sense, single-stranded RNA virus with a tripartite segmented genome, containing L (large), M (medium) and S (small) segments. The S segment codes for two proteins, namely the nucleocapsid (N) protein and non-structural protein (NSs). There is evidence that the NSs protein is involved in virulence by blocking the expression of the interferon beta (IFN-β) promoter. It has been recently demonstrated that the SAP30-NSs-YY1 multiprotein complex represses the IFN-β promoter. Consequently, the interferon expression is blocked, allowing virus to replicate. A total of 45 isolates of RVFV recovered over a period of 53 years in 14 African countries, Madagascar and Saudi Arabia were characterized by full sequencing of the S segment of the virus. This data was added to another 27 strains of RVFV available on GenBank for phylogenetic analysis using MEGA4, giving a total of 72 strains analyzed. Alignments were made of the entire S segment, the NSs gene, the N gene, and their deduced amino acid sequences. The laboratory strains, clone 13, MP12 and Smithburn, were also included in the alignments. Two isolates were passaged ten times through two different amplification systems to asses the potential for sequence variation to occur in the original material through routine laboratory manipulations. Sequencing data was generated from the virus RNA present in the original clinical specimens and from the extracted RNA from the tenth passage of virus in each amplification system. The results showed 100% homology for each respective isolate, demonstrating that the RVFV S segment remained stable during ten serial passages in different propagation systems. Phylogenetic analysis was conducted on the naturally occurring RVFV strains (n = 72) and the findings indicate that circulating strains are compartmentalized and belong to one of three major lineages, namely Egyptian, western African, and central, eastern and southern African. The strains clustered in the Egyptian lineage had an average p-distance of 1.0%, the western African strains 0.9%, and the central, southern and eastern African strains 2.0%. The overall average p-distance was 2.5%, with a range from 0 to 4.1%. For the N gene, the range was from 0 to 4.2%, with an average of 2.2%. For the N protein, the range was from 0 to 2%, with an average of 0.2%. The NSs gene had a range of 0 to 4.6%, with an average of 2.4%. The NSs protein had a range of 0 to 3.8%, with an average of 1.7%. The intergenic region (IGR) had a range of 0 to 9.2%, with an average of 4.8%. Results of the study suggest that RVF outbreaks can result from either the rapid spread of a single strain over vast distances or from an increased activity of a strain circulating at an endemic level within an area/region during prolonged dry periods. Sequencing alignment showed that the length of the S segment ranged from 1690 to 1692 nucleotides. This difference in length was due to insertions and deletions found in the IGR, which is also the region with the most sequence divergence (4.8%). Both the NSs and N genes had neither insertions nor deletions, and were both found to be stable, though the NSs gene was slightly more variable than the N gene (2.5% versus 2.2%) The deduced amino acid sequences of the NSs protein were considerably more variable than that of the N protein (1.7% versus 0.2%). Alignment of the NSs protein demonstrated that the 5 cysteine residues at positions 39, 40, 150, 179 and 195, are highly conserved among the isolates analyzed. These residues are important for conservation of the three-dimensional structure of the protein and the formation of filamentous structures observed in cells infected with natural strains of RVFV. The NSs protein is now implicated as the major factor of virulence and that its pathogenicity is associated with the blocking of interferon production. Therefore, any amino acid changes that result in changes to the filamentous structure of the NSs protein might impact on the binding kinetics between the NSs protein, SAP30 (Sin3A Associated Protein 30) and YY1 (Yin Yang-1). There were 6 amino acid changes in the NSs-SAP30 binding domain, with one being unique to the live-attenuated Smithburn vaccine strain. Generated sequencing data contributes to global phylogenetic characterization of RVFV isolates and and molecular epidemiology of the virus. In addition, findings of this study will further aid investigation on reassortment events occurring between strains of RVFV and genetically related viruses, the role of the NSs protein in the replicative cycle of the virus, the pathogenic effects of the NSs protein within the RVFV-infected host cells, and might help to identify molecular basis of RVFV virulence.

Rift Valley fever virus

NSs protein

Etude du facteur de virulence NSs du virus Schmallenberg / Study of the NSs virulence factor of Schmallenberg virus

Gouzil, Julie

27 January 2016

Introduction : En 2011, un arbovirus émergent appelé virus Schmallenberg (SBV) et appartenant à la famille des Bunyaviridae a été identifié en Allemagne et s’est répandu en Europe. Le SBV infecte les ruminants domestiques et sauvages. Chez l’adulte, la virémie est transitoire et l’infection est souvent inapparente. En revanche, chez les femelles gestantes, le SBV peut franchir la barrière transplacentaire et infecter le fœtus, pouvant provoquer des avortements et des malformations du système nerveux central. Parmi les protéines virales synthétisées par le SBV, la protéine non-structurale NSs est un facteur de virulence majeur. Elle entraîne notamment la dégradation de sa sous-unité Rpb1 de l’ARN polymérase II pour inhiber la transcription cellulaire. Ce travail a pour but d’étudier les propriétés biochimiques et fonctionnelles de NSs et d’identifier les déterminants moléculaires régissant ses principales activités.Méthodes et résultats: L’analyse in silico de la séquence peptidique de NSs réalisée à l’aide d’algorithmes de prédiction a permis de designer plusieurs de mutants de délétion de la protéine. L’observation de la localisation cellulaire des mutants dans plusieurs modèles humains et ovins confirme la prédiction d’une distribution principalement nucléaire pour NSs. De façon intéressante, une séquence interne à la protéine (33-51) sert de motif d’adressage spécifique au niveau des nucléoles (NoLS) et nous avons pu démontrer la co-localisation de NSs avec plusieurs protéines nucléolaires. De plus, l’infection de cellules humaines et ovines par le SBV entraîne la translocation de protéines nucléolaires (B23 et fibrillarine) vers le nucléoplasme, témoignant d’un stress nucléolaire viro-induit. Pour évaluer l’impact de la localisation nucléolaire de NSs sur ce phénomène, un virus recombinant dont NSs a été délétée de son motif d’adressage nucléolaire (SBVΔNoLS) a été produit par génétique inverse. Le SBVΔNoLS n’induit plus de redistribution de B23 confirmant le rôle de NSs dans l’induction d’un stress nucléolaire au cours de l’infection. Ces résultats ont été confirmés dans des cellules souches neurales humaines, qui constituent un modèle pertinent par rapport aux lésions provoquées par le SBV dans le système nerveux.En parallèle de ce travail, nous avons recherché des partenaires cellulaires de NSs par la méthode du double-hybride en levures. Huit partenaires cellulaires de NSs ont été découverts, dont la chaîne légère de la dynéine de type 1 (Tctex-1) et la Major Vault Protein (MVP), qui sont toutes les deux impliquées dans le transport de protéines grâce à leur association aux microtubules. Une des hypothèses avancées est que ces protéines pourraient servir de cargos pour promouvoir le transport nucléo-cytoplasmique de NSs.Conclusions et perspectives : Ce travail de thèse a permis de démontrer que la protéine NSs du SBV est localisée principalement dans le noyau cellulaire et dans les nucléoles, grâce à une séquence d’adressage spécifique. L’infection virale induit un stress nucléolaire dépendant de NSs, qui a pu être reproduit dans un modèle de cellules souches neurales humaines. Les perturbations nucléolaires induites par NSs pourraient contribuer au blocage de la transcription cellulaire observé au cours de l’infection et, de manière subséquente, moduler la réponse antivirale de la cellule et/ou induire la mort cellulaire en lien avec la pathogenèse virale. Ainsi, ces perturbations des nucléoles pourraient être à l’origine d’une dégénérescence des neurones et des anomalies développementales observées chez les fœtus infectés. Au niveau moléculaire, nous souhaitons préciser l’implication de la protéine nucléolaire B23, relocalisée vers le nucléoplasme en cours d’infection, et/ou d’autres composants du nucléole dans l’initiation de ce processus. Enfin, l’hypothèse d’un transport rétrograde actif de NSs du cytoplasme vers le noyau médié par son interaction avec MVP ou Tctex1 est en cours d’investigation. / Introduction: In 2011, an emerging arbovirus named Schmallenberg virus (SBV), and belonging to the Bunyaviridae family, was discovered in Germany. Then, SBV has rapidly spread to Europe infecting wild and domestic ruminants. Adult infection is basically mild and associated with a short viremia (2-5 days). However, in case of pregnant females’ infection, SBV has the ability to cross the placental barrier to infect the foetuses, which can lead to stillbirth and central nervous system developmental abnormalities (arthrogyposis, hydranencephaly). Among bunyavirus-encoded proteins, the non-structural protein NSs has been shown to be an important virulence factor. Indeed, it is able to degrade the Rpb1 subunit of RNA polymerase II, leading to the inhibition of cellular transcription. The work of my thesis aimed to study biochemical and functional properties of NSs and to identify the molecular patterns ruling its main activities.Methods and results: An in silico amino acids sequence analysis was used to predict some common features of NSs and to help the design of several NSs mutants. As predicted by several algorithms, NSs and its mutants are mainly localised to cell nucleus in different cell types (from human and ovine origin). Interestingly, we highlighted an internal sequence (residues 33 to 51) containing a nucleolar localisation signal (NoLS), and have shown that NSs co-localises with several nucleolar proteins. Moreover, infections of human and ovine cell lines with SBV lead to re-localisation of nucleolar proteins to nucleoplasm (B23 and fibrillarin), demonstrating a viral-induced nucleolar stress. To assess the role of the NSs nucleolar localisation in this phenomenon, a recombinant virus, with a mutated version of NSs devoid of its NolS motif (SBVΔNoLS), was constructed by reverse genetic. Infection with SBVΔNoLS does not induce nucleolar stress, suggesting that the nucleolar stress induced by SBV occurs only if NSs is addressed to the nucleolus. Moreover, these results have been confirmed in human neural stem cells, which coud be a more relevant cellular model to mimic SBV infection in foetuses.Another way to study NSs functions was to identify its cellular partners by means of a yeast-two hybrid screen and using NSs as bait. Eight putative interactors of NSs have been discovered, including the dynein light chain type 1 (Tctex-1) and the Major Vault protein (MVP). These proteins are involved in cellular protein transport, notably by their associations with the microtubules network. Thus, NSs might interact with Tctex-1 and MVP to favour its shuttling from cell cytoplasm to the nucleus.Conclusions and perspectives: Altogether, these data indicate that SBV-NSs protein is mainly localised into cell nucleus and nucleolus, by means of its internal NoLS contained in the 33-51 NSs domain. SBV infection induces a nucleolar stress, particularly in human neural stem cells. NSs-induced nucleolar disruption could promote NSs inhibitory function on cellular transcription, and subsequently modulate cellular antiviral state and/or induce cell death. Regarding the pathogenesis in SBV-infected foetuses, nucleolar stress could be responsible for neurons degeneration and subsequent developmental abnormalities. At molecular level, our aim is to define the role of nucleolar protein B23 on viral replication, which is strongly relocalised to the nucleoplasm during SBV infection. Finally, hypothesis of NSs retrograde transport from cell cytoplasm to nucleus and the possible contributions of MVP and/or Tctex-1 needs to be further investigate.

Virus Schmallenberg

Facteur de virulence

Protéine NSs

Nucléoles

Schmallenberg virus

Virulence factor

NSs protein

Nucleolus

610

Characterisation of the immune modulatory effect of wild type Rift Valley fever virus strains / Charakterisierung des immunmodulatorischen Effektes von Wild-Typ Rift-Tal-Fieber-Virus-Stämmen

Lo, Modou Moustapha

26 October 2010

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Rift-Tal-Fieber-Virus

NSs-Protein

Interferonsystem

Dendritische Zellen

Rift Valley Fever Virus

NSs protein

Interferon system

Dendritic cells

42.32

44.43