Your search keyword '"Viarouge, C."' showing total 33 results

1. Schmallenberg virus: experimental infection in goats and bucks

Author

Laloy, E., primary, Riou, M., additional, Barc, C., additional, Belbis, G., additional, Bréard, E., additional, Breton, S., additional, Cordonnier, N., additional, Crochet, D., additional, Delaunay, R., additional, Moreau, J., additional, Pozzi, N., additional, Raimbourg, M., additional, Sarradin, P., additional, Trapp, S., additional, Viarouge, C., additional, Zientara, S., additional, and Ponsart, C., additional

Published

2015

2. Development and Validation of an ELISA for the Detection of Bluetongue Virus Serotype 4-Specific Antibodies.

Author

Bréard E, Turpaud M, Beaud G, Postic L, Fablet A, Beer M, Sailleau C, Caignard G, Viarouge C, Hoffmann B, Vitour D, and Zientara S

Subjects

Animals, Antibodies, Viral blood, Bluetongue virology, Europe, Recombinant Proteins genetics, Serogroup, Sheep, Vaccinia virus immunology, Bluetongue diagnosis, Bluetongue virus isolation & purification, Enzyme-Linked Immunosorbent Assay methods

Abstract

In this article, we describe the development and evaluation of a double antigen sandwich enzyme-linked immunosorbent assay (ELISA) able to detect serotype 4-specific antibodies from BTV-4 infected or vaccinated animals using a recombinant BTV-4 VP2 protein. The coding sequence of VP2 was inserted into a pVote plasmid by recombination in the Gateway ® cloning system. Vaccinia virus (VacV) was used as a vector for the expression of the recombinant VP2. After production in BSR cells, recombinant VP2 was purified by immunoprecipitation using a FLAG tag and then used both as the coated ELISA antigen and as the HRP-tagged conjugate. The performance of the ELISA was evaluated with 1186 samples collected from BTV negative, infected or vaccinated animals. The specificity and sensitivity of the BTV-4 ELISA were above the expected standards for the detection of anti-BTV-4 VP2 antibodies in animals reared in Europe or in the Mediterranean basin. Cross-reactions were observed with reference sera for serotypes 10 and 20, and to a lesser extent with serotypes 12, 17 and 24, due to their genetic proximity to serotype 4. Nevertheless, these serotypes have never been detected in Europe and the Mediterranean area. This ELISA, which requires only the production of a recombinant protein, can be used to detect BTV serotype 4-specific antibodies and is therefore an attractive alternative diagnostic method to serum neutralization.

Published

2021

3. The VP3 Protein of Bluetongue Virus Associates with the MAVS Complex and Interferes with the RIG-I-Signaling Pathway.

Author

Pourcelot M, Amaral Moraes R, Fablet A, Bréard E, Sailleau C, Viarouge C, Postic L, Zientara S, Caignard G, and Vitour D

Subjects

Adaptor Proteins, Signal Transducing genetics, Bluetongue genetics, Bluetongue virology, Bluetongue virus genetics, DEAD Box Protein 58 genetics, HeLa Cells, Host-Pathogen Interactions, Humans, Interferon Regulatory Factor-3 genetics, Interferon Regulatory Factor-3 metabolism, Interferon-beta genetics, Interferon-beta metabolism, Protein Binding, Receptors, Immunologic genetics, Signal Transduction, Viral Core Proteins genetics, Adaptor Proteins, Signal Transducing metabolism, Bluetongue metabolism, Bluetongue virus metabolism, DEAD Box Protein 58 metabolism, Receptors, Immunologic metabolism, Viral Core Proteins metabolism

Abstract

Bluetongue virus (BTV), an arbovirus transmitted by Culicoides biting midges, is a major concern of wild and domestic ruminants. While BTV induces type I interferon (alpha/beta interferon [IFN-α/β]) production in infected cells, several reports have described evasion strategies elaborated by this virus to dampen this intrinsic, innate response. In the present study, we suggest that BTV VP3 is a new viral antagonist of the IFN-β synthesis. Indeed, using split luciferase and coprecipitation assays, we report an interaction between VP3 and both the mitochondrial adapter protein MAVS and the IRF3-kinase IKKε. Overall, this study describes a putative role for the BTV structural protein VP3 in the control of the antiviral response.

Published

2021

4. The Genome Segments of Bluetongue Virus Differ in Copy Number in a Host-Specific Manner.

Author

Moreau Y, Gil P, Exbrayat A, Rakotoarivony I, Bréard E, Sailleau C, Viarouge C, Zientara S, Savini G, Goffredo M, Mancini G, Loire E, and Gutierrez S

Subjects

Animals, Bluetongue transmission, Ceratopogonidae virology, DNA Copy Number Variations, Gene Dosage, Host Specificity, Insect Vectors virology, Sheep, Bluetongue virology, Bluetongue virus genetics, Genome, Viral genetics

Abstract

Genome segmentation is mainly thought to facilitate reassortment. Here, we show that segmentation can also allow differences in segment abundance in populations of bluetongue virus (BTV). BTV has a genome consisting in 10 segments, and its cycle primarily involves periodic alternation between ruminants and Culicoides biting midges. We have developed a reverse transcription-quantitative PCR (RT-qPCR) approach to quantify each segment in wild BTV populations sampled in both ruminants and midges during an epizootic. Segment frequencies deviated from equimolarity in all hosts. Interestingly, segment frequencies were reproducible and distinct between ruminants and biting midges. Beyond a putative regulatory role in virus expression, this phenomenon could lead to different evolution rates between segments. IMPORTANCE The variation in viral gene frequencies remains a largely unexplored aspect of within-host genetics. This phenomenon is often considered to be specific to multipartite viruses. Multipartite viruses have segmented genomes, but in contrast to segmented viruses, their segments are each encapsidated alone in a virion. A main hypothesis explaining the evolution of multipartism is that, compared to segmented viruses, it facilitates the regulation of segment abundancy, and the genes the segments carry, within a host. These differences in gene frequencies could allow for expression regulation. Here, we show that wild populations of a segmented virus, bluetongue virus (BTV), also present unequal segment frequencies. BTV cycles between ruminants and Culicoides biting midges. As expected from a role in expression regulation, segment frequencies tended to show specific values that differed between ruminants and midges. Our results expand previous knowledge on gene frequency variation and call for studies on its role and conservation beyond multipartite viruses., (Copyright © 2020 Moreau et al.)

Published

2020

5. "Frozen evolution" of an RNA virus suggests accidental release as a potential cause of arbovirus re-emergence.

Author

Pascall DJ, Nomikou K, Bréard E, Zientara S, Filipe ADS, Hoffmann B, Jacquot M, Singer JB, De Clercq K, Bøtner A, Sailleau C, Viarouge C, Batten C, Puggioni G, Ligios C, Savini G, van Rijn PA, Mertens PPC, Biek R, and Palmarini M

Subjects

Animals, Biological Evolution, Bluetongue epidemiology, Bluetongue virus genetics, Disease Outbreaks, Europe epidemiology, France, Livestock virology, Mutation, Phylogeny, Bluetongue virology, Bluetongue virus physiology, Genome, Viral

Abstract

The mechanisms underlying virus emergence are rarely well understood, making the appearance of outbreaks largely unpredictable. Bluetongue virus serotype 8 (BTV-8), an arthropod-borne virus of ruminants, emerged in livestock in northern Europe in 2006, spreading to most European countries by 2009 and causing losses of billions of euros. Although the outbreak was successfully controlled through vaccination by early 2010, puzzlingly, a closely related BTV-8 strain re-emerged in France in 2015, triggering a second outbreak that is still ongoing. The origin of this virus and the mechanisms underlying its re-emergence are unknown. Here, we performed phylogenetic analyses of 164 whole BTV-8 genomes sampled throughout the two outbreaks. We demonstrate consistent clock-like virus evolution during both epizootics but found negligible evolutionary change between them. We estimate that the ancestor of the second outbreak dates from the height of the first outbreak in 2008. This implies that the virus had not been replicating for multiple years prior to its re-emergence in 2015. Given the absence of any known natural mechanism that could explain BTV-8 persistence over this long period without replication, we hypothesise that the second outbreak could have been initiated by accidental exposure of livestock to frozen material contaminated with virus from approximately 2008. Our work highlights new targets for pathogen surveillance programmes in livestock and illustrates the power of genomic epidemiology to identify pathways of infectious disease emergence., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

6. Experimental infection of calves with seven serotypes of Epizootic Hemorrhagic Disease virus: production and characterization of reference sera.

Author

Sailleau C, Breard E, Viarouge C, Belbis G, Lilin T, Vitour D, and Zientara S

Subjects

Animals, Antibodies, Neutralizing analysis, Cattle, Enzyme-Linked Immunosorbent Assay veterinary, RNA, Viral analysis, Real-Time Polymerase Chain Reaction veterinary, Reoviridae Infections virology, Serogroup, Cattle Diseases virology, Hemorrhagic Disease Virus, Epizootic physiology, Reoviridae Infections veterinary

Abstract

The aim of this study was to produce reference sera against the seven serotypes of Epizootic hemorrhagic disease virus (EHDV‑1, EHDV‑2, EHDV‑4, EHDV‑5, EHDV‑6, EHDV‑7, and EHDV‑8). In a high containment unit, seven Prim 'Holstein calves were inoculated at day 0 (D0) with the selected strains (1 EHDV serotype per calf ). Blood samples (EDTA and whole blood) were periodically taken from D0 until the end of the experiment (D31). Sera were tested with two commercially available EHDV competitive ELISAs (c‑ELISA). Viral genome was detected from EDTA blood samples using in‑house real‑time RT‑PCR. Sera taken on D31 post infection (pi) were tested and characterized by serum neutralization test (SNT) and virus neutralization test (VNT) (for calibration of reference sera). Viral RNA was first detected at D2 pi in five calves. All infected animals were RT‑PCR positive at D7 pi. Seroconversion was observed between D10 and D23 pi depending on the EHDV serotype. SNT and VNT have allowed to determine the neutralizing antibody titers of each serum and the potential cross‑reactions between serotypes. The two c‑ELISA used in this study showed similar results. The calibrated sera are now available for the serological identification of an EHDV isolated on tissue culture or to be used as positive control in seroneutralization assay.

Published

2019

7. Red deer ( Cervus elaphus ) Did Not Play the Role of Maintenance Host for Bluetongue Virus in France: The Burden of Proof by Long-Term Wildlife Monitoring and Culicoides Snapshots.

Author

Rossi S, Balenghien T, Viarouge C, Faure E, Zanella G, Sailleau C, Mathieu B, Delécolle JC, Ninio C, Garros C, Gardès L, Tholoniat C, Ariston A, Gauthier D, Mondoloni S, Barboiron A, Pellerin M, Gibert P, Novella C, Barbier S, Guillaumat E, Zientara S, Vitour D, and Bréard E

Subjects

Animals, Animals, Domestic virology, Antibodies, Neutralizing, Antibodies, Viral, Bluetongue epidemiology, Bluetongue transmission, Bluetongue virology, Bluetongue virus immunology, Ceratopogonidae classification, Disease Outbreaks, Female, France epidemiology, Livestock virology, Male, Ruminants virology, Vector Borne Diseases virology, Animals, Wild virology, Bluetongue virus physiology, Ceratopogonidae virology, Deer virology, Disease Reservoirs virology

Abstract

Bluetongue virus (BTV) is a Culicoides -borne pathogen infecting both domestic and wild ruminants. In Europe, the Red Deer ( Cervus elaphus ) (RD) is considered a potential BTV reservoir, but persistent sylvatic cycle has not yet been demonstrated. In this paper, we explored the dynamics of BTV1 and BTV8 serotypes in the RD in France, and the potential role of that species in the re-emergence of BTV8 in livestock by 2015 (i.e., 5 years after the former last domestic cases). We performed 8 years of longitudinal monitoring (2008-2015) among 15 RD populations and 3065 individuals. We compared Culicoides communities and feeding habits within domestic and wild animal environments (51,380 samples). Culicoides diversity (>30 species) varied between them, but bridge-species able to feed on both wild and domestic hosts were abundant in both situations. Despite the presence of competent vectors in natural environments, BTV1 and BTV8 strains never spread in RD along the green corridors out of the domestic outbreak range. Decreasing antibody trends with no PCR results two years after the last domestic outbreak suggests that seropositive young RD were not recently infected but carried maternal antibodies. We conclude that RD did not play a role in spreading or maintaining BTV in France.

Published

2019

8. Novel Function of Bluetongue Virus NS3 Protein in Regulation of the MAPK/ERK Signaling Pathway.

Author

Kundlacz C, Pourcelot M, Fablet A, Amaral Da Silva Moraes R, Léger T, Morlet B, Viarouge C, Sailleau C, Turpaud M, Gorlier A, Breard E, Lecollinet S, van Rijn PA, Zientara S, Vitour D, and Caignard G

Subjects

Animals, Bluetongue virus pathogenicity, Cell Line, DNA-Binding Proteins, Humans, Interferons metabolism, Phosphorylation, Protein Binding, Protein Transport, Proto-Oncogene Proteins B-raf genetics, Proto-Oncogene Proteins B-raf metabolism, Transcription Factors, Virulence Factors, Virus Replication, Bluetongue metabolism, Bluetongue virology, Bluetongue virus physiology, Host-Pathogen Interactions, MAP Kinase Signaling System, Viral Nonstructural Proteins metabolism

Abstract

Bluetongue virus (BTV) is an arbovirus transmitted by blood-feeding midges to a wide range of wild and domestic ruminants. In this report, we showed that BTV, through its nonstructural protein NS3 (BTV-NS3), is able to activate the mitogen-activated protein kinase/extracellular signal-regulated kinase (MAPK/ERK) pathway, as assessed by phosphorylation levels of ERK1/2 and the translation initiation factor eukaryotic translation initiation factor 4E (eIF4E). By combining immunoprecipitation of BTV-NS3 and mass spectrometry analysis from both BTV-infected and NS3-transfected cells, we identified the serine/threonine-protein kinase B-Raf (BRAF), a crucial player in the MAPK/ERK pathway, as a new cellular interactor of BTV-NS3. BRAF silencing led to a significant decrease in the MAPK/ERK activation by BTV, supporting a model wherein BTV-NS3 interacts with BRAF to activate this signaling cascade. This positive regulation acts independently of the role of BTV-NS3 in counteracting the induction of the alpha/beta interferon response. Furthermore, the intrinsic ability of BTV-NS3 to bind BRAF and activate the MAPK/ERK pathway is conserved throughout multiple serotypes/strains but appears to be specific to BTV compared to other members of Orbivirus genus. Inhibition of MAPK/ERK pathway with U0126 reduced viral titers, suggesting that BTV manipulates this pathway for its own replication. Altogether, our data provide molecular mechanisms that unravel a new essential function of NS3 during BTV infection. IMPORTANCE Bluetongue virus (BTV) is responsible of the arthropod-borne disease bluetongue (BT) transmitted to ruminants by blood-feeding midges. In this report, we found that BTV, through its nonstructural protein NS3 (BTV-NS3), interacts with BRAF, a key component of the MAPK/ERK pathway. In response to growth factors, this pathway promotes cell survival and increases protein translation. We showed that BTV-NS3 enhances the MAPK/ERK pathway, and this activation is BRAF dependent. Treatment of MAPK/ERK pathway with the pharmacologic inhibitor U0126 impairs viral replication, suggesting that BTV manipulates this pathway for its own benefit. Our results illustrate, at the molecular level, how a single virulence factor has evolved to target a cellular function to increase its viral replication., (Copyright © 2019 American Society for Microbiology.)

Published

2019

9. Bluetongue Virus in France: An Illustration of the European and Mediterranean Context since the 2000s.

Author

Kundlacz C, Caignard G, Sailleau C, Viarouge C, Postic L, Vitour D, Zientara S, and Breard E

Subjects

Animals, Bluetongue prevention & control, Bluetongue virus classification, Communicable Diseases, Emerging epidemiology, Communicable Diseases, Emerging virology, Europe epidemiology, France epidemiology, Mediterranean Region epidemiology, Public Health Surveillance, Serogroup, Bluetongue epidemiology, Bluetongue virology, Bluetongue virus physiology

Abstract

Bluetongue (BT) is a non-contagious animal disease transmitted by midges of the Culicoides genus. The etiological agent is the BT virus (BTV) that induces a variety of clinical signs in wild or domestic ruminants. BT is included in the notifiable diseases list of the World Organization for Animal Health (OIE) due to its health impact on domestic ruminants. A total of 27 BTV serotypes have been described and additional serotypes have recently been identified. Since the 2000s, the distribution of BTV has changed in Europe and in the Mediterranean Basin, with continuous BTV incursions involving various BTV serotypes and strains. These BTV strains, depending on their origin, have emerged and spread through various routes in the Mediterranean Basin and/or in Europe. Consequently, control measures have been put in place in France to eradicate the virus or circumscribe its spread. These measures mainly consist of assessing virus movements and the vaccination of domestic ruminants. Many vaccination campaigns were first carried out in Europe using attenuated vaccines and, in a second period, using exclusively inactivated vaccines. This review focuses on the history of the various BTV strain incursions in France since the 2000s, describing strain characteristics, their origins, and the different routes of spread in Europe and/or in the Mediterranean Basin. The control measures implemented to address this disease are also discussed. Finally, we explain the circumstances leading to the change in the BTV status of France from BTV-free in 2000 to an enzootic status since 2018.

Published

2019

10. Bluetongue virus and epizootic hemorrhagic disease virus survey in cattle of the Galapagos Islands.

Author

Vinueza RL, Cruz M, Bréard E, Viarouge C, and Zanella G

Subjects

Animals, Antibodies, Viral blood, Bluetongue diagnosis, Bluetongue virology, Cattle, Cattle Diseases diagnosis, Cattle Diseases virology, Ecuador epidemiology, Enzyme-Linked Immunosorbent Assay veterinary, Prevalence, Reoviridae Infections diagnosis, Reoviridae Infections epidemiology, Reoviridae Infections virology, Bluetongue epidemiology, Bluetongue virus isolation & purification, Cattle Diseases epidemiology, Hemorrhagic Disease Virus, Epizootic isolation & purification, Reoviridae Infections veterinary

Abstract

Bluetongue virus (BTV) and epizootic hemorrhagic disease virus (EHDV) have both been reported in mainland Ecuador, but their occurrence was unknown in the Galapagos Islands, an Ecuadorian province. We aimed to detect BTV or EHDV in cattle from the 3 main cattle-producing Galapagos Islands at a between-herd design prevalence of 20% and a within-herd design prevalence of 15%. Blood samples were collected from 410 cattle in 33 farms and tested for antibodies against BTV and EHDV by competitive ELISAs. All results were negative, suggesting that BTV and EHDV are not present in the Galapagos Islands.

Published

2019

11. Ring trial 2016 for Bluetongue virus detection by real-time RT-PCR in France.

Author

Sailleau C, Viarouge C, Breard E, Vitour D, and Zientara S

Abstract

Since the unexpected emergence of BTV-8 in Northern Europe and the incursion of BTV-8 and 1 in France in 2006-2007, molecular diagnosis has considerably evolved. Several real-time RT-PCR (rtRT-PCR) methods have been developed and published, and are currently being used in many countries across Europe for BTV detection and typing. In France, the national reference laboratory (NRL) for orbiviruses develops and validates 'ready-to-use' kits with private companies for viral RNA detection. The regional laboratories network that was set up to deal with a heavy demand for analyses has used these available kits. From 2007, ring tests were organized to monitor the performance of the French laboratories. This study presents the results of 63 regional laboratories in the ring trial organized in 2016. Blood samples were sent to the laboratories. Participants were asked to use the rtRT-PCR methods in place in their laboratory, for detection of all BTV serotypes and specifically BTV-8. The French regional laboratories are able to detect and genotype BTV in affected animals. Despite the use of several methods (i.e. RNA extraction and different commercial rtRT-PCRs), the network is homogeneous. The ring trial demonstrated that the French regional veterinary laboratories have reliable and robust BTV diagnostic tools for BTV genome detection.

Published

2017

12. Nonstructural Protein NSs of Schmallenberg Virus Is Targeted to the Nucleolus and Induces Nucleolar Disorganization.

Author

Gouzil J, Fablet A, Lara E, Caignard G, Cochet M, Kundlacz C, Palmarini M, Varela M, Breard E, Sailleau C, Viarouge C, Coulpier M, Zientara S, and Vitour D

Subjects

Animals, Cell Line, Transformed, Cell Nucleolus metabolism, Cell Nucleolus ultrastructure, Choroid Plexus cytology, Choroid Plexus metabolism, Choroid Plexus virology, Chromosomal Proteins, Non-Histone genetics, Chromosomal Proteins, Non-Histone metabolism, Ependymoglial Cells metabolism, Ependymoglial Cells ultrastructure, Gene Expression Regulation, HeLa Cells, Humans, Mutation, Nuclear Proteins genetics, Nuclear Proteins metabolism, Nucleophosmin, Orthobunyavirus genetics, Orthobunyavirus metabolism, Protein Sorting Signals, Protein Transport, Proteolysis, RNA Polymerase II genetics, RNA Polymerase II metabolism, Sheep, Signal Transduction, Transcription, Genetic, Viral Nonstructural Proteins genetics, Viral Nonstructural Proteins metabolism, Cell Nucleolus virology, Ependymoglial Cells virology, Host-Pathogen Interactions, Orthobunyavirus pathogenicity, RNA Polymerase II chemistry, Viral Nonstructural Proteins chemistry

Abstract

Schmallenberg virus (SBV) was discovered in Germany in late 2011 and then spread rapidly to many European countries. SBV is an orthobunyavirus that causes abortion and congenital abnormalities in ruminants. A virus-encoded nonstructural protein, termed NSs, is a major virulence factor of SBV, and it is known to promote the degradation of Rpb1, a subunit of the RNA polymerase II (Pol II) complex, and therefore hampers global cellular transcription. In this study, we found that NSs is mainly localized in the nucleus of infected cells and specifically appears to target the nucleolus through a nucleolar localization signal (NoLS) localized between residues 33 and 51 of the protein. NSs colocalizes with nucleolar markers such as B23 (nucleophosmin) and fibrillarin. We observed that in SBV-infected cells, B23 undergoes a nucleolus-to-nucleoplasm redistribution, evocative of virus-induced nucleolar disruption. In contrast, the nucleolar pattern of B23 was unchanged upon infection with an SBV recombinant mutant with NSs lacking the NoLS motif (SBVΔNoLS). Interestingly, unlike wild-type SBV, the inhibitory activity of SBVΔNoLS toward RNA Pol II transcription is impaired. Overall, our results suggest that a putative link exists between NSs-induced nucleolar disruption and its inhibitory function on cellular transcription, which consequently precludes the cellular antiviral response and/or induces cell death., Importance: Schmallenberg virus (SBV) is an emerging arbovirus of ruminants that spread in Europe between 2011 and 2013. SBV induces fetal abnormalities during gestation, with the central nervous system being one of the most affected organs. The virus-encoded NSs protein acts as a virulence factor by impairing host cell transcription. Here, we show that NSs contains a nucleolar localization signal (NoLS) and induces disorganization of the nucleolus. The NoLS motif in the SBV NSs is absolutely necessary for virus-induced inhibition of cellular transcription. To our knowledge, this is the first report of nucleolar functions for NSs within the Bunyaviridae family., (Copyright © 2016 Gouzil et al.)

Published

2016

13. Schmallenberg Virus in Zoo Ruminants, France and the Netherlands.

Author

Laloy E, Braud C, Bréard E, Kaandorp J, Bourgeois A, Kohl M, Meyer G, Sailleau C, Viarouge C, Zientara S, and Chai N

Subjects

Animals, France epidemiology, Mice, Netherlands epidemiology, Animal Diseases epidemiology, Animal Diseases virology, Animals, Zoo virology, Bunyaviridae Infections veterinary, Orthobunyavirus classification, Orthobunyavirus genetics, Orthobunyavirus isolation & purification, Ruminants virology

Published

2016

14. Bluetongue virus serotype 27: detection and characterization of two novel variants in Corsica, France.

Author

Schulz C, Bréard E, Sailleau C, Jenckel M, Viarouge C, Vitour D, Palmarini M, Gallois M, Höper D, Hoffmann B, Beer M, and Zientara S

Subjects

Animals, Asymptomatic Diseases, Cluster Analysis, France, Genome, Viral, Goats, Phylogeny, RNA, Viral genetics, Sequence Analysis, DNA, Sequence Homology, Bluetongue virology, Bluetongue virus classification, Bluetongue virus isolation & purification, Serogroup

Abstract

During the compulsory vaccination programme against bluetongue virus serotype 1 (BTV-1) in Corsica (France) in 2014, a BTV strain belonging to a previously uncharacterized serotype (BTV-27) was isolated from asymptomatic goats. The present study describes the detection and molecular characterization of two additional distinct BTV-27 variants found in goats in Corsica in 2014 and 2015. The full coding genome of these two novel BTV-27 variants show high homology (90-93 % nucleotide/93-95 % amino acid) with the originally described BTV-27 isolate from Corsican goats in 2014. These three variants constitute the novel serotype BTV-27 ('BTV-27/FRA2014/v01 to v03'). Phylogenetic analyses with the 26 other established BTV serotypes revealed the closest relationship to BTV-25 (SWI2008/01) (80 % nucleotide/86 % amino acid) and to BTV-26 (KUW2010/02) (73-74 % nucleotide/80-81 % amino acid). However, highest sequence homologies between individual segments of BTV-27/FRA2014/v01-v03 with BTV-25 and BTV-26 vary. All three variants share the same segment 2 nucleotype with BTV-25. Neutralization assays of anti-BTV27/FRA2014/v01-v03 sera with a reassortant virus containing the outer capsid proteins of BTV-25 (BTV1VP2/VP5 BTV25) further confirmed that BTV-27 represents a distinct BTV serotype. Relationships between the variants and with BTV-25 and BTV-26, hypotheses about their origin, reassortment events and evolution are discussed.

Published

2016

15. Complete Genome Sequence of Bluetongue Virus Serotype 8, Which Reemerged in France in August 2015.

Author

Bréard E, Sailleau C, Quenault H, Lucas P, Viarouge C, Touzain F, Fablet A, Vitour D, Attoui H, Zientara S, and Blanchard Y

Abstract

We announce here the complete genome sequence (coding and noncoding) of the bluetongue virus (BTV) serotype 8, isolated from a ram in Allier department, France, 2015. Sequence analysis confirms the reemergence of the BTV-8 strain that previously circulated in France until 2009 and other European countries until 2010., (Copyright © 2016 Bréard et al.)

Published

2016

16. Turnover Rate of NS3 Proteins Modulates Bluetongue Virus Replication Kinetics in a Host-Specific Manner.

Author

Ftaich N, Ciancia C, Viarouge C, Barry G, Ratinier M, van Rijn PA, Breard E, Vitour D, Zientara S, Palmarini M, Terzian C, and Arnaud F

Subjects

Amino Acid Sequence, Animals, Aorta metabolism, Aorta pathology, Aorta virology, Bluetongue virus chemistry, Bluetongue virus metabolism, Cell Line, Transformed, Ceratopogonidae, Choroid Plexus metabolism, Choroid Plexus pathology, Choroid Plexus virology, Cricetulus, Endothelial Cells metabolism, Endothelial Cells pathology, Host Specificity, Mice, Molecular Sequence Data, Primary Cell Culture, Protein Stability, Proteolysis, Reverse Genetics, Sheep, Signal Transduction, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins metabolism, Virus Release genetics, Bluetongue virus genetics, Endothelial Cells virology, Gene Expression Regulation, Viral, Genome, Viral, Viral Nonstructural Proteins genetics, Virus Replication genetics

Abstract

Unlabelled: Bluetongue virus (BTV) is an arbovirus transmitted to livestock by midges of the Culicoides family and is the etiological agent of a hemorrhagic disease in sheep and other ruminants. In mammalian cells, BTV particles are released primarily by virus-induced cell lysis, while in insect cells they bud from the plasma membrane and establish a persistent infection. BTV possesses a ten-segmented double-stranded RNA genome, and NS3 proteins are encoded by segment 10 (Seg-10). The viral nonstructural protein 3 (NS3) plays a key role in mediating BTV egress as well as in impeding the in vitro synthesis of type I interferon in mammalian cells. In this study, we asked whether genetically distant NS3 proteins can alter BTV-host interactions. Using a reverse genetics approach, we showed that, depending on the NS3 considered, BTV replication kinetics varied in mammals but not in insects. In particular, one of the NS3 proteins analyzed harbored a proline at position 24 that leads to its rapid intracellular decay in ovine but not in Culicoides cells and to the attenuation of BTV virulence in a mouse model of disease. Overall, our data reveal that the genetic variability of Seg-10/NS3 differentially modulates BTV replication kinetics in a host-specific manner and highlight the role of the host-specific variation in NS3 protein turnover rate., Importance: BTV is the causative agent of a severe disease transmitted between ruminants by biting midges of Culicoides species. NS3, encoded by Seg-10 of the BTV genome, fulfills key roles in BTV infection. As Seg-10 sequences from various BTV strains display genetic variability, we assessed the impact of different Seg-10 and NS3 proteins on BTV infection and host interactions. In this study, we revealed that various Seg-10/NS3 proteins alter BTV replication kinetics in mammals but not in insects. Notably, we found that NS3 protein turnover may vary in ovine but not in Culicoides cells due to a single amino acid residue that, most likely, leads to rapid and host-dependent protein degradation. Overall, this study highlights that genetically distant BTV Seg-10/NS3 influence BTV biological properties in a host-specific manner and increases our understanding of how NS3 proteins contribute to the outcome of BTV infection., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015

17. Benefits of PCR and decentralization of diagnosis in regional laboratories in the management of Bluetongue in France.

Author

Zientara S, Sailleau C, Bréard E, Viarouge C, Doceul V, and Vitour D

Subjects

Animals, Europe, France, Laboratories organization & administration, Politics, Bluetongue diagnosis, Bluetongue virology, Bluetongue virus isolation & purification, Polymerase Chain Reaction veterinary

Abstract

Since 1998, Bluetongue virus (BTV) serotypes 1, 2, 4, 6, 8, 9, 11 and 16 have spread throughout Europe. In 2006, BTV serotype 8 (BTV‑8) emerged unexpectedly in Northern Europe, in countries such as Belgium, France, Germany, Luxembourg, and the Netherlands, to spread rapidly in the following year throughout the rest of Europe. In 2007, BTV‑1 spread in Southern Europe, in Spain and in South of France. In 2008, 2 more BTV serotypes were detected in Northern Europe: BTV‑6 in the Netherlands and in Germany, and BTV‑11 in Belgium. The European incursion of BTV has caused considerable economic losses, including direct losses from mortality and reduced production, as well as indirect losses generated by ensuing bans on trade of ruminants between infected and non-infected areas. Given the significance of the disease, all affected countries have established control and eradication measures that have evolved together with the availability of detection and prevention tools such as Polymerase Chain Reaction (PCR) tests and vaccines, respectively. This paper describes how the French National Reference Laboratory for BT has managed diagnosis during the fast and massive spread of BTV‑1 and 8 in 2007 and 2008.

Published

2015

18. Duplex Real-Time RT-PCR Assays for the Detection and Typing of Epizootic Haemorrhagic Disease Virus.

Author

Viarouge C, Breard E, Zientara S, Vitour D, and Sailleau C

Subjects

Animals, Cattle, DNA Primers metabolism, DNA Probes metabolism, Reproducibility of Results, Sensitivity and Specificity, Serogroup, Hemorrhagic Disease Virus, Epizootic classification, Hemorrhagic Disease Virus, Epizootic genetics, Real-Time Polymerase Chain Reaction methods, Reverse Transcriptase Polymerase Chain Reaction methods

Abstract

Epizootic haemorrhagic disease virus (EHDV) may cause severe clinical episodes in some species of deer and sometimes in cattle. Laboratory diagnosis provides a basis for the design and timely implementation of disease control measures. There are seven distinct EHDV serotypes, VP2 coding segment 2 being the target for serotype specificity. This paper reports the development and validation of eight duplex real-time RT-PCR assays to simultaneously amplify the EHDV target (S9 for the pan-EHDV real-time RT-PCR assay and S2 for the serotyping assays) and endogenous control gene Beta-actin. Analytical and diagnostic sensitivity and specificity, inter- and intra-assay variation and efficiency were evaluated for each assay. All were shown to be highly specific and sensitive.

Published

2015

19. Complete coding genome sequence of putative novel bluetongue virus serotype 27.

Author

Jenckel M, Bréard E, Schulz C, Sailleau C, Viarouge C, Hoffmann B, Höper D, Beer M, and Zientara S

Abstract

We announce the complete coding genome sequence of a novel bluetongue virus (BTV) serotype (BTV-n = putative BTV-27) detected in goats in Corsica, France, in 2014. Sequence analysis confirmed the closest relationship between sequences of the novel BTV serotype and BTV-25 and BTV-26, recently discovered in Switzerland and Kuwait, respectively., (Copyright © 2015 Jenckel et al.)

Published

2015

20. Novel bluetongue virus in goats, Corsica, France, 2014.

Author

Zientara S, Sailleau C, Viarouge C, Höper D, Beer M, Jenckel M, Hoffmann B, Romey A, Bakkali-Kassimi L, Fablet A, Vitour D, and Bréard E

Subjects

Animals, Bluetongue virus genetics, France epidemiology, Genotype, Phylogeny, Public Health Surveillance, RNA, Viral, Bluetongue epidemiology, Bluetongue virology, Bluetongue virus classification, Goats virology

Abstract

During 2000-2013, 4 genotypes of bluetongue virus (BTV) were detected in Corsica, France. At the end of 2013, a compulsory BTV-1 vaccination campaign was initiated among domestic ruminants; biological samples from goats were tested as part of a corresponding monitoring program. A BTV strain with nucleotide sequences suggestive of a novel serotype was detected.

Published

2014

21. Expression of VP7, a Bluetongue virus group specific antigen by viral vectors: analysis of the induced immune responses and evaluation of protective potential in sheep.

Author

Bouet-Cararo C, Contreras V, Caruso A, Top S, Szelechowski M, Bergeron C, Viarouge C, Desprat A, Relmy A, Guibert JM, Dubois E, Thiery R, Bréard E, Bertagnoli S, Richardson J, Foucras G, Meyer G, Schwartz-Cornil I, Zientara S, and Klonjkowski B

Subjects

Animals, Antibodies, Viral blood, Antibodies, Viral immunology, Antigens, Viral immunology, Bluetongue prevention & control, Bluetongue virology, Bluetongue virus immunology, Cell Line, Cricetinae, Cross Reactions immunology, Dogs, Female, Immunity, Cellular, Immunization, Male, Rabbits, Sheep, T-Lymphocytes immunology, T-Lymphocytes metabolism, Viral Core Proteins immunology, Viral Vaccines genetics, Viral Vaccines immunology, Antigens, Viral genetics, Bluetongue immunology, Bluetongue virus genetics, Gene Expression, Genetic Vectors genetics, Viral Core Proteins genetics

Abstract

Bluetongue virus (BTV) is an economically important Orbivirus transmitted by biting midges to domestic and wild ruminants. The need for new vaccines has been highlighted by the occurrence of repeated outbreaks caused by different BTV serotypes since 1998. The major group-reactive antigen of BTV, VP7, is conserved in the 26 serotypes described so far, and its role in the induction of protective immunity has been proposed. Viral-based vectors as antigen delivery systems display considerable promise as veterinary vaccine candidates. In this paper we have evaluated the capacity of the BTV-2 serotype VP7 core protein expressed by either a non-replicative canine adenovirus type 2 (Cav-VP7 R0) or a leporipoxvirus (SG33-VP7), to induce immune responses in sheep. Humoral responses were elicited against VP7 in almost all animals that received the recombinant vectors. Both Cav-VP7 R0 and SG33-VP7 stimulated an antigen-specific CD4+ response and Cav-VP7 R0 stimulated substantial proliferation of antigen-specific CD8+ lymphocytes. Encouraged by the results obtained with the Cav-VP7 R0 vaccine vector, immunized animals were challenged with either the homologous BTV-2 or the heterologous BTV-8 serotype and viral burden in plasma was followed by real-time RT-PCR. The immune responses triggered by Cav-VP7 R0 were insufficient to afford protective immunity against BTV infection, despite partial protection obtained against homologous challenge. This work underscores the need to further characterize the role of BTV proteins in cross-protective immunity.

Published

2014

22. Spread and impact of the Schmallenberg virus epidemic in France in 2012-2013.

Author

Dominguez M, Gache K, Touratier A, Perrin JB, Fediaevsky A, Collin E, Bréard E, Sailleau C, Viarouge C, Zanella G, Zientara S, Hendrikx P, and Calavas D

Subjects

Animals, Bunyaviridae Infections congenital, Bunyaviridae Infections epidemiology, Cattle, Cattle Diseases congenital, Cattle Diseases epidemiology, Communicable Diseases, Emerging epidemiology, Communicable Diseases, Emerging veterinary, France epidemiology, Goat Diseases congenital, Goat Diseases epidemiology, Goats, Seasons, Sheep, Sheep Diseases congenital, Sheep Diseases epidemiology, Time Factors, Bunyaviridae Infections veterinary, Cattle Diseases virology, Epidemics veterinary, Goat Diseases virology, Orthobunyavirus isolation & purification, Sheep Diseases virology

Abstract

Background: The Schmallenberg virus (SBV) emerged in Europe in 2011 and caused a widespread epidemic in ruminants.In France, SBV emergence was monitored through a national multi-stakeholder surveillance and investigation system. Based on the monitoring data collected from January 2012 to August 2013, we describe the spread of SBV in France during two seasons of dissemination (vector seasons 2011 and 2012) and we provide a large-scale assessment of the impact of this new disease in ruminants., Results: SBV impact in infected herds was primarily due to the birth of stillborns or deformed foetuses and neonates. Congenital SBV morbidity level was on average moderate, although higher in sheep than in other ruminant species. On average, 8% of lambs, 3% of calves and 2% of kids born in SBV-infected herds showed typical congenital SBV deformities. In addition, in infected herds, farmers reported retrospectively a lower prolificacy during the vector season, suggesting a potential impact of acute SBV infection during mating and early stages of gestation., Conclusions: Due to the lack of available control and prevention measures, SBV spread quickly in the naive ruminant population. France continues to monitor for SBV, and updated information is made available online on a regular basis [http://www.plateforme-esa.fr/]. Outbreaks of congenital SBV are expected to occur sporadically from now on, but further epidemics may also occur if immunity at population level declines.

Published

2014

23. Evidence of excretion of Schmallenberg virus in bull semen.

Author

Ponsart C, Pozzi N, Bréard E, Catinot V, Viard G, Sailleau C, Viarouge C, Gouzil J, Beer M, Zientara S, and Vitour D

Subjects

Animals, Bunyaviridae Infections transmission, Bunyaviridae Infections virology, Cattle, Cattle Diseases transmission, Enzyme-Linked Immunosorbent Assay veterinary, Male, Orthobunyavirus isolation & purification, Real-Time Polymerase Chain Reaction veterinary, Receptor, Interferon alpha-beta genetics, Reverse Transcriptase Polymerase Chain Reaction veterinary, Virus Shedding, Bunyaviridae Infections veterinary, Cattle Diseases virology, Orthobunyavirus physiology, Semen virology

Abstract

Schmallenberg virus (SBV) is a novel orthobunyavirus, discovered in Germany in late 2011. It mainly infects cattle, sheep and goats and could lead to congenital infection, causing abortion and fetal abnormalities. SBV is transmitted by biting midges from the Culicoides genus and there is no evidence that natural infection occurs directly between ruminants. Here, we could detect SBV RNA in infected bull semen using qRT-PCR (three bulls out of seven tested positive; 29 positive semen batches out of 136). We also found that highly positive semen batches from SBV infected bulls can provoke an acute infection in IFNAR-/- mice, suggesting the potential presence of infectious virus in the semen of SBV infected bulls.

Published

2014

24. Culicoides midge bites modulate the host response and impact on bluetongue virus infection in sheep.

Author

Pages N, Bréard E, Urien C, Talavera S, Viarouge C, Lorca-Oro C, Jouneau L, Charley B, Zientara S, Bensaid A, Solanes D, Pujols J, and Schwartz-Cornil I

Subjects

Animals, Antibodies, Neutralizing immunology, Bites and Stings genetics, Bites and Stings parasitology, Bites and Stings virology, Blood Cells metabolism, Blood Cells parasitology, Bluetongue genetics, Bluetongue immunology, Bluetongue virology, Body Temperature, Cell Line, Gene Expression Regulation, Host-Parasite Interactions genetics, Immunity, Humoral genetics, Inflammation pathology, Interferons metabolism, Needles, Sheep blood, Sheep immunology, Viremia parasitology, Viremia virology, Bites and Stings immunology, Bluetongue parasitology, Bluetongue virus physiology, Ceratopogonidae physiology, Host-Parasite Interactions immunology, Sheep parasitology, Sheep virology

Abstract

Many haematophagous insects produce factors that help their blood meal and coincidently favor pathogen transmission. However nothing is known about the ability of Culicoides midges to interfere with the infectivity of the viruses they transmit. Among these, Bluetongue Virus (BTV) induces a hemorrhagic fever- type disease and its recent emergence in Europe had a major economical impact. We observed that needle inoculation of BTV8 in the site of uninfected C. nubeculosus feeding reduced viraemia and clinical disease intensity compared to plain needle inoculation. The sheep that developed the highest local inflammatory reaction had the lowest viral load, suggesting that the inflammatory response to midge bites may participate in the individual sensitivity to BTV viraemia development. Conversely compared to needle inoculation, inoculation of BTV8 by infected C. nubeculosus bites promoted viraemia and clinical symptom expression, in association with delayed IFN- induced gene expression and retarded neutralizing antibody responses. The effects of uninfected and infected midge bites on BTV viraemia and on the host response indicate that BTV transmission by infected midges is the most reliable experimental method to study the physio-pathological events relevant to a natural infection and to pertinent vaccine evaluation in the target species. It also leads the way to identify the promoting viral infectivity factors of infected Culicoides in order to possibly develop new control strategies against BTV and other Culicoides transmitted viruses.

Published

2014

25. Schmallenberg virus infection among red deer, France, 2010-2012.

Author

Laloy E, Bréard E, Sailleau C, Viarouge C, Desprat A, Zientara S, Klein F, Hars J, and Rossi S

Subjects

Animals, France epidemiology, Geography, Medical, Seroepidemiologic Studies, Serotyping, Animal Diseases epidemiology, Animal Diseases virology, Bunyaviridae Infections veterinary, Deer virology, Orthobunyavirus classification

Abstract

Schmallenberg virus infection is emerging in European domestic and wild ruminants. We investigated the serologic status of 9 red deer populations to describe virus spread from September 2010 through March 2012 among wildlife in France. Deer in 7 populations exhibited seropositivity, with an average seroprevalence of 20%.

Published

2014

26. Schmallenberg virus infection in dogs, France, 2012.

Author

Sailleau C, Boogaerts C, Meyrueix A, Laloy E, Bréard E, Viarouge C, Desprat A, Vitour D, Doceul V, Boucher C, Zientara S, Nicolier A, and Grandjean D

Subjects

Animals, Dog Diseases virology, Dogs, Female, France epidemiology, Bunyaviridae Infections veterinary, Dog Diseases epidemiology, Orthobunyavirus genetics, Orthobunyavirus immunology

Published

2013

27. Epidemiology, molecular virology and diagnostics of Schmallenberg virus, an emerging orthobunyavirus in Europe.

Author

Doceul V, Lara E, Sailleau C, Belbis G, Richardson J, Bréard E, Viarouge C, Dominguez M, Hendrikx P, Calavas D, Desprat A, Languille J, Comtet L, Pourquier P, Eléouët JF, Delmas B, Marianneau P, Vitour D, and Zientara S

Subjects

Animals, Bunyaviridae Infections diagnosis, Bunyaviridae Infections epidemiology, Bunyaviridae Infections etiology, Communicable Diseases, Emerging diagnosis, Communicable Diseases, Emerging epidemiology, Communicable Diseases, Emerging etiology, Europe epidemiology, Orthobunyavirus classification, Orthobunyavirus genetics, Orthobunyavirus pathogenicity, Bunyaviridae Infections veterinary, Communicable Diseases, Emerging veterinary, Orthobunyavirus physiology, Ruminants

Abstract

After the unexpected emergence of Bluetongue virus serotype 8 (BTV-8) in northern Europe in 2006, another arbovirus, Schmallenberg virus (SBV), emerged in Europe in 2011 causing a new economically important disease in ruminants. The virus, belonging to the Orthobunyavirus genus in the Bunyaviridae family, was first detected in Germany, in The Netherlands and in Belgium in 2011 and soon after in the United Kingdom, France, Italy, Luxembourg, Spain, Denmark and Switzerland. This review describes the current knowledge on the emergence, epidemiology, clinical signs, molecular virology and diagnosis of SBV infection.

Published

2013

28. Acute Schmallenberg virus infections, France, 2012.

Author

Sailleau C, Bréard E, Viarouge C, Desprat A, Doceul V, Lara E, Languille J, Vitour D, Attoui H, and Zientara S

Subjects

Acute Disease, Animals, Arbovirus Infections diagnosis, Arbovirus Infections epidemiology, Arbovirus Infections virology, Cattle, Cattle Diseases diagnosis, Cattle Diseases virology, Epidemiological Monitoring, France epidemiology, Molecular Diagnostic Techniques, Polymerase Chain Reaction, Reverse Transcriptase Polymerase Chain Reaction, Arbovirus Infections veterinary, Arboviruses genetics, Cattle Diseases epidemiology

Published

2013

29. Validation of a commercially available indirect ELISA using a nucleocapside recombinant protein for detection of Schmallenberg virus antibodies.

Author

Bréard E, Lara E, Comtet L, Viarouge C, Doceul V, Desprat A, Vitour D, Pozzi N, Cay AB, De Regge N, Pourquier P, Schirrmeier H, Hoffmann B, Beer M, Sailleau C, and Zientara S

Subjects

Animals, Antibodies, Neutralizing immunology, Bunyaviridae Infections veterinary, Cattle, Europe, Fluorescent Antibody Technique, Indirect, Gene Expression, Neutralization Tests, Nucleocapsid Proteins genetics, Orthobunyavirus genetics, ROC Curve, Reagent Kits, Diagnostic, Recombinant Proteins genetics, Recombinant Proteins immunology, Reproducibility of Results, Sheep, Antibodies, Viral immunology, Bunyaviridae Infections diagnosis, Enzyme-Linked Immunosorbent Assay, Nucleocapsid Proteins immunology, Orthobunyavirus immunology

Abstract

A newly developed Enzym Like Immuno Sorbant Assay (ELISA) based on the recombinant nucleocapsid protein (N) of Schmallenberg virus (SBV) was evaluated and validated for the detection of SBV-specific IgG antibodies in ruminant sera by three European Reference Laboratories. Validation data sets derived from sheep, goat and bovine sera collected in France and Germany (n = 1515) in 2011 and 2012 were categorized according to the results of a virus neutralization test (VNT) or an indirect immuno-fluorescence assay (IFA). The specificity was evaluated with 1364 sera from sheep, goat and bovine collected in France and Belgium before 2009. Overall agreement between VNT and ELISA was 98.9% and 98.3% between VNT and IFA, indicating a very good concordance between the different techniques. Although cross-reactions with other Orthobunyavirus from the Simbu serogroup viruses might occur, it is a highly sensitive, specific and robust ELISA-test validated to detect anti-SBV antibodies. This test can be applied for SBV sero-diagnostics and disease-surveillance studies in ruminant species in Europe.

Published

2013

30. Sensing and control of bluetongue virus infection in epithelial cells via RIG-I and MDA5 helicases.

Author

Chauveau E, Doceul V, Lara E, Adam M, Breard E, Sailleau C, Viarouge C, Desprat A, Meyer G, Schwartz-Cornil I, Ruscanu S, Charley B, Zientara S, and Vitour D

Subjects

Animals, Cell Line, DEAD Box Protein 58, DEAD-box RNA Helicases genetics, Gene Expression Profiling, Gene Silencing, Humans, Interferon-Induced Helicase, IFIH1, Interferon-beta genetics, Receptors, Immunologic, Bluetongue virus immunology, DEAD-box RNA Helicases metabolism, Epithelial Cells virology, Host-Pathogen Interactions, Interferon-beta biosynthesis

Abstract

Bluetongue virus (BTV), an arthropod-borne member of the Reoviridae family, is a double-stranded RNA virus that causes an economically important livestock disease that has spread across Europe in recent decades. Production of type I interferon (alpha/beta interferon [IFN-α/β]) has been reported in vivo and in vitro upon BTV infection. However, the cellular sensors and signaling pathways involved in this process remain unknown. Here we studied the mechanisms responsible for the production of IFN-β in response to BTV serotype 8. Upon BTV infection of A549 cells, expression of IFN-β and other proinflammatory cytokines was strongly induced at both the protein and mRNA levels. This response appeared to be dependent on virus replication, since exposure to UV-inactivated virus failed to induce IFN-β. We also demonstrated that BTV infection activated the transcription factors IFN regulatory factor 3 and nuclear factor κB. We investigated the role of several pattern recognition receptors in this response and showed that expression of IFN-β was greatly reduced after small-interfering-RNA-mediated knockdown of the RNA helicase encoded by retinoic acid-inducible gene I (RIG-I) or melanoma differentiation-associated gene 5 (MDA5). In contrast, silencing of MyD88, Toll-like receptor 3, or the recently described DexD/H-box helicase DDX1 sensor had no or a weak effect on IFN-β induction, suggesting that the RIG-I-like receptor pathway is specifically engaged for BTV sensing. Moreover, we also showed that overexpression of either RIG-I or MDA5 impaired BTV expression in infected A549 cells. Overall, this indicates that RIG-I and MDA5 can both contribute to the recognition and control of BTV infection.

Published

2012

31. Generation of replication-defective virus-based vaccines that confer full protection in sheep against virulent bluetongue virus challenge.

Author

Matsuo E, Celma CC, Boyce M, Viarouge C, Sailleau C, Dubois E, Bréard E, Thiéry R, Zientara S, and Roy P

Subjects

Animals, Antibodies, Neutralizing blood, Antibodies, Viral blood, Bluetongue virus genetics, Bluetongue virus isolation & purification, Cell Culture Techniques, Defective Viruses genetics, Defective Viruses isolation & purification, Female, Male, Reassortant Viruses genetics, Reassortant Viruses immunology, Reassortant Viruses isolation & purification, Sheep, Viral Vaccines genetics, Viral Vaccines isolation & purification, Viremia prevention & control, Bluetongue prevention & control, Bluetongue virus immunology, Defective Viruses immunology, Viral Vaccines immunology

Abstract

The reverse genetics technology for bluetongue virus (BTV) has been used in combination with complementing cell lines to recover defective BTV-1 mutants. To generate a potential disabled infectious single cycle (DISC) vaccine strain, we used a reverse genetics system to rescue defective virus strains with large deletions in an essential BTV gene that encodes the VP6 protein (segment S9) of the internal core. Four VP6-deficient BTV-1 mutants were generated by using a complementing cell line that provided the VP6 protein in trans. Characterization of the growth properties of mutant viruses showed that each mutant has the necessary characteristics for a potential vaccine strain: (i) viral protein expression in noncomplementing mammalian cells, (ii) no infectious virus generated in noncomplementing cells, and (iii) efficient replication in the complementing VP6 cell line. Further, a defective BTV-8 strain was made by reassorting the two RNA segments that encode the two outer capsid proteins (VP2 and VP5) of a highly pathogenic BTV-8 with the remaining eight RNA segments of one of the BTV-1 DISC viruses. The protective capabilities of BTV-1 and BTV-8 DISC viruses were assessed in sheep by challenge with specific virulent strains using several assay systems. The data obtained from these studies demonstrated that the DISC viruses are highly protective and could offer a promising alternative to the currently available attenuated and killed virus vaccines and are also compliant as DIVA (differentiating infected from vaccinated animals) vaccines.

Published

2011

32. Colostral antibody induced interference of inactivated bluetongue serotype-8 vaccines in calves.

Author

Vitour D, Guillotin J, Sailleau C, Viarouge C, Desprat A, Wolff F, Belbis G, Durand B, Bakkali-Kassimi L, Breard E, Zientara S, and Zanella G

Subjects

Animals, Bluetongue immunology, Bluetongue virology, Cattle, Cattle Diseases virology, Enzyme-Linked Immunosorbent Assay veterinary, Female, Immunity, Humoral, Neutralization Tests veterinary, Vaccines, Inactivated administration & dosage, Vaccines, Inactivated immunology, Viral Vaccines administration & dosage, Antibodies, Viral analysis, Bluetongue prevention & control, Bluetongue virus immunology, Cattle Diseases prevention & control, Colostrum immunology, Viral Vaccines immunology

Abstract

Since its introduction into northern Europe in 2006, bluetongue has become a major threat to animal health. While the efficacy of commercial vaccines has been clearly demonstrated in livestock, little is known regarding the effect of maternal immunity on vaccinal efficacy. Here, we have investigated the duration and amplitude of colostral antibody-induced immunity in calves born to dams vaccinated against bluetongue virus serotype 8 (BTV-8) and the extent of colostral antibody-induced interference of vaccination in these calves. Twenty-two calf-cow pairs were included in this survey. The median age at which calves became seronegative for BTV was 84 and 112 days as assayed by seroneutralisation test (SNT) and VP7 BTV competitive ELISA (cELISA), respectively. At the mean age of 118 days, 13/22 calves were immunized with inactivated BTV-8 vaccine. In most calves vaccination elicited a weak immune response, with seroconversion in only 3/13 calves. The amplitude of the humoral response to vaccination was inversely proportional to the maternal antibody level prior to vaccination. Thus, the lack of response was attributed to the persistence of virus-specific colostral antibodies that interfered with the induction of the immune response. These data suggest that the recommended age for vaccination of calves born to vaccinated dams needs to be adjusted in order to optimize vaccinal efficacy.

Published

2011

33. Exchanging the active site between phytases for altering the functional properties of the enzyme.

Author

Lehmann M, Lopez-Ulibarri R, Loch C, Viarouge C, Wyss M, and van Loon AP

Subjects

6-Phytase genetics, Amino Acid Sequence, Amino Acid Substitution, Aspergillus niger enzymology, Aspergillus niger genetics, Binding Sites, Consensus Sequence, DNA Primers, Enzyme Stability, Escherichia coli, Hydrogen-Ion Concentration, Kinetics, Models, Molecular, Molecular Sequence Data, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Thermodynamics, 6-Phytase chemistry, 6-Phytase metabolism

Abstract

By using a novel consensus approach, we have previously managed to generate a fully synthetic phytase, consensus phytase-1, that was 15-26 degrees C more thermostable than the parent fungal phytases used in its design (Lehmann et al., 2000). We now sought to use the backbone of consensus phytase-1 and to modify its catalytic properties. This was done by replacing a considerable part of the active site (i.e., all the divergent residues) with the corresponding residues of Aspergillus niger NRRL 3135 phytase, which displays pronounced differences in specific activity, substrate specificity, and pH-activity profile. For the new protein termed consensus phytase-7, a major - although not complete - shift in catalytic properties was observed, demonstrating that rational transfer of favorable catalytic properties from one phytase to another is possible by using this approach. Although the exchange of the active site was associated with a 7.6 degrees C decrease in unfolding temperature (Tm) as measured by differential scanning calorimetry, consensus phytase-7 still was >7 degrees C more thermostable than all wild-type ascomycete phytases known to date. Thus, combination of the consensus approach with the selection of a "preferred" active site allows the design of a thermostabilized variant of an enzyme family of interest that (most closely) matches the most favorable catalytic properties found among its family members.

Published

2000