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Covadonga Alonso - One of the best experts on this subject based on the ideXlab platform.
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ictv virus taxonomy profile Asfarviridae
Journal of General Virology, 2018Co-Authors: Covadonga Alonso, Linda K Dixon, Manuel V Borca, Yolanda Revilla, Fernando Rodriguez, Jose M EscribanoAbstract:The family Asfarviridae includes the single species African swine fever virus, isolates of which have linear dsDNA genomes of 170–194 kbp. Virions have an internal core, an internal lipid membrane, an icosahedral capsid and an outer lipid envelope. Infection of domestic pigs and wild boar results in an acute haemorrhagic fever with transmission by contact or ingestion, or by ticks of the genus Ornithodoros. Indigenous pigs act as reservoirs in Africa, where infection is endemic, and from where introductions occur periodically to Europe. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Asfarviridae, which is available at www.ictv.global/report/Asfarviridae.
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african swine fever virus a review
Viruses, 2017Co-Authors: Inmaculada Galindo, Covadonga AlonsoAbstract:African swine fever (ASF) is a highly contagious viral disease of swine which causes high mortality, approaching 100%, in domestic pigs. ASF is caused by a large, double stranded DNA virus, ASF virus (ASFV), which replicates predominantly in the cytoplasm of macrophages and is the only member of the Asfarviridae family, genus Asfivirus. The natural hosts of this virus include wild suids and arthropod vectors of the Ornithodoros genus. The infection of ASFV in its reservoir hosts is usually asymptomatic and develops a persistent infection. In contrast, infection of domestic pigs leads to a lethal hemorrhagic fever for which there is no effective vaccine. Identification of ASFV genes involved in virulence and the characterization of mechanisms used by the virus to evade the immune response of the host are recognized as critical steps in the development of a vaccine. Moreover, the interplay of the viral products with host pathways, which are relevant for virus replication, provides the basic information needed for the identification of potential targets for the development of intervention strategies against this disease.
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Investigations of Pro- and Anti-Apoptotic Factors Affecting African Swine Fever Virus Replication and Pathogenesis
MDPI AG, 2017Co-Authors: Linda K Dixon, Pedro J. Sánchez-cordón, Inmaculada Galindo, Covadonga AlonsoAbstract:African swine fever virus (ASFV) is a large DNA virus that replicates predominantly in the cell cytoplasm and is the only member of the Asfarviridae family. The virus causes an acute haemorrhagic fever, African swine fever (ASF), in domestic pigs and wild boar resulting in the death of most infected animals. Apoptosis is induced at an early stage during virus entry or uncoating. However, ASFV encodes anti-apoptotic proteins which facilitate production of progeny virions. These anti-apoptotic proteins include A179L, a Bcl-2 family member; A224L, an inhibitor of apoptosis proteins (IAP) family member; EP153R a C-type lectin; and DP71L. The latter acts by inhibiting activation of the stress activated pro-apoptotic pathways pro-apoptotic pathways. The mechanisms by which these proteins act is summarised. ASF disease is characterised by massive apoptosis of uninfected lymphocytes which reduces the effectiveness of the immune response, contributing to virus pathogenesis. Mechanisms by which this apoptosis is induced are discussed
Bernard La Scola - One of the best experts on this subject based on the ideXlab platform.
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The Kaumoebavirus LCC10 Genome Reveals a Unique Gene Strand Bias among “Extended Asfarviridae”
Viruses, 2021Co-Authors: Khalil Geballa-koukoulas, Julien Andreani, Bernard La Scola, Guillaume BlancAbstract:The Kaumoebavirus LCC10 Genome Reveals a Unique Gene Strand Bias among "Extended Asfarviridae".
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Comparative Genomics Unveils Regionalized Evolution of the Faustovirus Genomes
Viruses, 2020Co-Authors: Khalil Geballa-koukoulas, Julien Andreani, Bernard La Scola, Hadjer Boudjemaa, Guillaume BlancAbstract:Faustovirus is a recently discovered genus of large DNA virus infecting the amoeba Vermamoeba vermiformis, which is phylogenetically related to Asfarviridae. To better understand the diversity and evolution of this viral group, we sequenced six novel Faustovirus strains, mined published metagenomic datasets and performed a comparative genomic analysis. Genomic sequences revealed three consistent phylogenetic groups, within which genetic diversity was moderate. The comparison of the major capsid protein (MCP) genes unveiled between 13 and 18 type-I introns that likely evolved through a still-active birth and death process mediated by intron-encoded homing endonucleases that began before the Faustovirus radiation. Genome-wide alignments indicated that despite genomes retaining high levels of gene collinearity, the central region containing the MCP gene together with the extremities of the chromosomes evolved at a faster rate due to increased indel accumulation and local rearrangements. The fluctuation of the nucleotide composition along the Faustovirus (FV) genomes is mostly imprinted by the consistent nucleotide bias of coding sequences and provided no evidence for a single DNA replication origin like in circular bacterial genomes.
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kaumoebavirus a new virus that clusters with faustoviruses and Asfarviridae
Viruses, 2016Co-Authors: Leena H Bajrai, Catherine Robert, Samia Benamar, Anthony Levasseur, Esam I. Azhar, Bernard La ScolaAbstract:In this study, we report the isolation of a new giant virus found in sewage water from the southern area of Jeddah (Saudi Arabia), with morphological and genomic resemblance to Faustoviruses. This new giant virus, named Kaumoebavirus, was obtained from co-culture with Vermamoeba vermiformis, an amoeboid protozoa considered to be of special interest to human health and the environment. This new virus has ~250 nm icosahedral capsids and a 350,731 bp DNA genome length. The genome of Kaumoebavirus has a coding density of 86%, corresponding to 465 genes. Most of these genes (59%) are closely related to genes from members of the proposed order Megavirales, and the best matches to its proteins with other members of the Megavirales are Faustoviruses (43%) and Asfarviruses (23%). Unsurprisingly, phylogenetic reconstruction places Kaumoebavirus as a distant relative of Faustoviruses and Asfarviruses.
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faustoviruses comparative genomics of new megavirales family members
Frontiers in Microbiology, 2016Co-Authors: Samia Benamar, Dorine G Reteno, Noemie Labas, Victor Bandaly, Didier Raoult, Bernard La ScolaAbstract:An emerging interest for the giant virus discovery process, genome sequencing and analysis has allowed an expansion of the number of known Megavirales members. Using the protist Vermamoeba sp. as cell support, a new giant virus named Faustovirus has been isolated. In this study, we describe the genome sequences of nine Faustoviruses and build a genomic comparison in order to have a comprehensive overview of genomic composition and diversity among this new virus family. The average sequence length of these viruses is 467,592.44 bp (ranging from 455,803 bp to 491,024 bp), making them the fourth largest Megavirales genome after Mimiviruses, Pandoraviruses and Pithovirus sibericum. Faustovirus genomes displayed an average G+C content of 37.14 % (ranging from 36.22% to 39.59%) which is close to the G+C content range of the Asfarviridae genomes (38%). The proportion of best matches and the phylogenetic analysis suggest a shared origin with Asfarviridae without belonging to the same family. The core-gene-based phylogeny of Faustoviruses study has identified four lineages. These results were confirmed by the analysis of amino acids and COGs category distribution. The diversity of the gene composition of these lineages is mainly explained by gene deletion or acquisition and some exceptions for gene duplications. The high proportion of best matches from Bacteria and Phycodnaviridae on the pan-genome and unique genes may be explained by an interaction occurring after the separation of the lineages. The Faustovirus core-genome appears to consolidate the surrounding of 207 genes whereas the pan-genome is described as an open pan-genome, its enrichment via the discovery of new Faustoviruses is required to better seize all the genomic diversity of this family.
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faustovirus an asfarvirus related new lineage of giant viruses infecting amoebae
Journal of Virology, 2015Co-Authors: Dorine G Reteno, Jacques Bou Khalil, Nicholas Armstrong, Julien Andreani, Samia Benamar, Michael G. Rossmann, Thomas Klose, Philippe Colson, Bernard La ScolaAbstract:Giant viruses are protist-associated viruses belonging to the proposed order Megavirales; almost all have been isolated from Acanthamoeba spp. Their isolation in humans suggests that they are part of the human virome. Using a high-throughput strategy to isolate new giant viruses from their original protozoan hosts, we obtained eight isolates of a new giant viral lineage from Vermamoeba vermiformis, the most common free-living protist found in human environments. This new lineage was proposed to be the faustovirus lineage. The prototype member, faustovirus E12, forms icosahedral virions of ≈200 nm that are devoid of fibrils and that encapsidate a 466-kbp genome encoding 451 predicted proteins. Of these, 164 are found in the virion. Phylogenetic analysis of the core viral genes showed that faustovirus is distantly related to the mammalian pathogen African swine fever virus, but it encodes ≈3 times more mosaic gene complements. About two-thirds of these genes do not show significant similarity to genes encoding any known proteins. These findings show that expanding the panel of protists to discover new giant viruses is a fruitful strategy. IMPORTANCE By using Vermamoeba, a protist living in humans and their environment, we isolated eight strains of a new giant virus that we named faustovirus. The genomes of these strains were sequenced, and their sequences showed that faustoviruses are related to but different from the vertebrate pathogen African swine fever virus (ASFV), which belongs to the family Asfarviridae. Moreover, the faustovirus gene repertoire is ≈3 times larger than that of ASFV and comprises approximately two-thirds ORFans (open reading frames [ORFs] with no detectable homology to other ORFs in a database).
Hiroyuki Ogata - One of the best experts on this subject based on the ideXlab platform.
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Remarkable sequence similarity between the dinoflagellate-infecting marine girus and the terrestrial pathogen African swine fever virus
Virology Journal, 2009Co-Authors: Hiroyuki Ogata, Kensuke Toyoda, Natsuko Nakayama, Jean-michel Claverie, Yuji Tomaru, Yoko Shirai, Keizo NagasakiAbstract:Heterocapsa circularisquama DNA virus (HcDNAV; previously designated as HcV) is a giant virus (girus) with a ~356-kbp double-stranded DNA (dsDNA) genome. HcDNAV lytically infects the bivalve-killing marine dinoflagellate H. circularisquama, and currently represents the sole DNA virus isolated from dinoflagellates, one of the most abundant protists in marine ecosystems. Its morphological features, genome type, and host range previously suggested that HcDNAV might be a member of the family Phycodnaviridae of Nucleo-Cytoplasmic Large DNA Viruses (NCLDVs), though no supporting sequence data was available. NCLDVs currently include two families found in aquatic environments (Phycodnaviridae, Mimiviridae), one mostly infecting terrestrial animals (Poxviridae), another isolated from fish, amphibians and insects (Iridoviridae), and the last one (Asfarviridae) exclusively represented by the animal pathogen African swine fever virus (ASFV), the agent of a fatal hemorrhagic disease in domestic swine. In this study, we determined the complete sequence of the type B DNA polymerase (PolB) gene of HcDNAV. The viral PolB was transcribed at least from 6 h post inoculation (hpi), suggesting its crucial function for viral replication. Most unexpectedly, the HcDNAV PolB sequence was found to be closely related to the PolB sequence of ASFV. In addition, the amino acid sequence of HcDNAV PolB showed a rare amino acid substitution within a motif containing highly conserved motif: YSDTDS was found in HcDNAV PolB instead of YGDTDS in most dsDNA viruses. Together with the previous observation of ASFV-like sequences in the Sorcerer II Global Ocean Sampling metagenomic datasets, our results further reinforce the ideas that the terrestrial ASFV has its evolutionary origin in marine environments.
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Taxonomic distribution of large DNA viruses in the sea
Genome Biology, 2008Co-Authors: Adam Monier, Jean-michel Claverie, Hiroyuki OgataAbstract:Background Viruses are ubiquitous and the most abundant biological entities in marine environments. Metagenomics studies are increasingly revealing the huge genetic diversity of marine viruses. In this study, we used a new approach - 'phylogenetic mapping' - to obtain a comprehensive picture of the taxonomic distribution of large DNA viruses represented in the Sorcerer II Global Ocean Sampling Expedition metagenomic data set. Results Using DNA polymerase genes as a taxonomic marker, we identified 811 homologous sequences of likely viral origin. As expected, most of these sequences corresponded to phages. Interestingly, the second largest viral group corresponded to that containing mimivirus and three related algal viruses. We also identified several DNA polymerase homologs closely related to Asfarviridae, a viral family poorly represented among isolated viruses and, until now, limited to terrestrial animal hosts. Finally, our approach allowed the identification of a new combination of genes in 'viral-like' sequences. Conclusion Albeit only recently discovered, giant viruses of the Mimiviridae family appear to constitute a diverse, quantitatively important and ubiquitous component of the population of large eukaryotic DNA viruses in the sea.
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Taxonomic distribution of large DNA viruses in the sea.
Genome Biology, 2008Co-Authors: Adam Monier, Jean-michel Claverie, Hiroyuki OgataAbstract:Viruses are ubiquitous and the most abundant biological entities in marine environments. Metagenomics studies are increasingly revealing the huge genetic diversity of marine viruses. In this study, we used a new approach - 'phylogenetic mapping' - to obtain a comprehensive picture of the taxonomic distribution of large DNA viruses represented in the Sorcerer II Global Ocean Sampling Expedition metagenomic data set. Using DNA polymerase genes as a taxonomic marker, we identified 811 homologous sequences of likely viral origin. As expected, most of these sequences corresponded to phages. Interestingly, the second largest viral group corresponded to that containing mimivirus and three related algal viruses. We also identified several DNA polymerase homologs closely related to Asfarviridae, a viral family poorly represented among isolated viruses and, until now, limited to terrestrial animal hosts. Finally, our approach allowed the identification of a new combination of genes in 'viral-like' sequences. Albeit only recently discovered, giant viruses of the Mimiviridae family appear to constitute a diverse, quantitatively important and ubiquitous component of the population of large eukaryotic DNA viruses in the sea.
Bernard Jennifer - One of the best experts on this subject based on the ideXlab platform.
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Ornithodoros tick vector competence characterization for African swine fever virus and study of two vector competence determinants : virus strain – vector relationship and tick saliva influence on domestic pig infection
2015Co-Authors: Bernard JenniferAbstract:La peste porcine africaine (PPA) est une maladie hémorragique contagieuse dévastatrice pour l’élevage porcin pour laquelle aucun traitement ni vaccin ne sont disponibles. Cette infection est due à un virus à ADN, unique membre de la famille des Asfarviridae, qui se transmet directement entre suidés ou via un vecteur, la tique du genre Ornithodoros. Le rôle de ces tiques dans le cycle épidémiologique de la PPA consiste principalement à maintenir le virus dans les populations de suidés sauvages en Afrique. Elles ont aussi été identifiées à l’origine de certains cas de résurgence de la maladie dans des bâtiments d’élevage porcin, notamment dans la péninsule ibérique, lors des années 1970-80. La PPA, éradiquée fin des années 1980 en Europe (à l’exception de la Sardaigne), a été de nouveau introduite en 2007 d’abord en Géorgie pour progresser jusqu’à atteindre l’Est de l’Union Européenne. La question de la compétence vectorielle des tiques Ornithodores pour le virus de la PPA et des déterminants qui influencent cette compétence est posée dans l’évaluation des risques d’endémisation et/ou de dispersion de la maladie en Europe et ailleurs. Le premier chapitre de cette thèse vise à caractériser la compétence vectorielle des tiques Ornithodores pour le virus de la PPA et faire ressortir les patrons généraux qui la qualifient. Pour cela, a été réalisée une revue systématique des études ayant testé la compétence vectorielle d’une ou plusieurs espèces de tiques pour une ou plusieurs souches virales de PPA durant ces 50 dernières années. Au final, il en ressort une forte variabilité de résultats selon les couples tique-virus. En outre, il semble difficile de comparer ces résultats et d’établir des « profils types » du fait de l’évaluation partielle de la compétence vectorielle pour de nombreux couples tique-virus et de la diversité des méthodologies utilisées pour tester et mesurer la compétence. Pour autant chaque modalité d’étude révèle une partie des mécanismes et des adaptations auxquels sont soumis les couples tique–virus et suggère l’effet de certains déterminants dont deux sont traités dans les deux autres chapitres de la thèse. Le second chapitre de la thèse traite de l’adaptation tique-virus, par l’étude expérimentale de l’infection des tiques O. erraticus, O. porcinus et O. moubata à l’aide de deux souches de génotype II du virus de la PPA, et par un essai de transmission du virus des tiques aux porcs. Des souches du génotype II ont été choisies car ce génotype circule actuellement en Europe et risque d’infecter les tiques européennes O. erraticus s’il se propage jusqu’en péninsule ibérique. Alors qu’O. erraticus est capable de s’infecter et de transmettre différentes souches virales du génotype I, sa compétence à transmettre la souche Georgia2007/1 (génotype II) n’a pour l’instant pas été démontrée. Toutefois, nos études suggèrent que les résultats de compétence dépendent aussi des conditions d’expérimentation telles que la nature des colonies de tiques utilisées ou encore le titre viral utilisé pour infecter les tiques. Le dernier chapitre de la thèse porte sur l’effet de la salive de tique sur l’étape de transmission du virus de la PPA par la tique au porc. Durant le repas de sang, la salive est un élément essentiel qui va permettre l’accroche et le gorgement durable de la tique sur son hôte, avec des propriétés immuno-modulatrices importantes agissant directement sur l’hôte. Ainsi a été réalisée une étude expérimentale in vivo faisant intervenir la tique O. porcinus et le virus Ambat02 (génotype II) et testant l’effet local et systémique chez le porc d’un extrait de glandes salivaires de tique co-inoculé ou non avec le virus de la PPA, versus la piqûre naturelle de tiques non infectées. Les résultats de cette expérience nous montrent que la salive de tique est capable de moduler au niveau local le recrutement de cellules immunitaires dans la peau du porc et potentiellement influencer l’infection locale chez le porc.African swine fever (ASF) is a contagious hemorrhagic disease with disastrous financial consequences for pig industry, as no vaccine or treatment exists. This infection is caused by a DNA virus, only member of the Asfarviridae family that can be directly transmitted between swine or by a non-compulsory vector, the Ornithodoros tick. Ornithodoros ticks play a role in the persistence of the disease within wild and domestic suids in Africa. They were also involved in resurgences of outbreaks in some pig farms in the Iberian Peninsula in 1970-1980. ASF, eradicated in Europe at the end of the 1980’s except in Sardinia, was reintroduced in Georgia in 2007 then spread towards the Eastern European Union. The question of the tick vector competence for ASF virus (ASFV) and its related determinants is of importance in the risk assessment of endemisation/spread of the disease in Europe or elsewhere.The first chapter of this thesis aims to characterize Ornithodoros tick vector competence for ASFV and to highlight a common pattern to qualify it. For this purpose, a systematic review of the studies carried out on the vector competence of one or more tick species for one or more ASFV, was performed on the last 50 years publications. A high variability of the results obtained for different couples “tick-virus” was highlighted. As most of the papers describe partial evaluation of the vector competence and because of the high number of methods used to perform these assessments, it was definitively very difficult to compare these results, and to propose common patterns. However, each of these studies revealed a part of the mechanisms that participated to the adaptation in the couple “tick-virus”, and suggested the importance of different determinants, out of them, two were experimentally assessed as described in the two other chapters.The second chapter of this thesis describes the adaptation “tick-virus” through the experimental infection of three different ticks, O. erraticus, O. porcinus and O. moubata by two ASFV strains belonging to the genotype II. O erraticus’s competence is known for ASFV strains belonging to the genotype I but has never demonstrated the ASFV Georgia 2007/1 strain (genotype II) and currently circulating in Europe. However, the experiments we performed, suggest that many experimental conditions could influence the results obtained on vector competence as the tick colony or the virus dose used for the tick infection.The third chapter describes the effect of the tick saliva on the ASFV transmission from the tick to the pig. Tick saliva contains important immunomodulatory molecules that interfere with the pig immune system permitting complete engorgement of the tick on its host. The host-vector and pathogen interactions were studied through an in vivo experimentation involving pig, O porcinus tick and ASFV Ambat02 strain (genotype II). The local and systemic effects on the pig immune responses were assessed with the ASFV alone or combined with tick gland extract, versus a healthy tick bite. Data analysis highlighted the tick saliva role on skin immune cell recruitment and its potential effect on local infection
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Caractérisation de la compétence vectorielle des tiques Ornithodores pour le virus de la peste porcine africaine et étude de deux déterminants : la relation souche virale – vecteur et l’influence de la salive de tiques sur l’infection chez le porc do
HAL CCSD, 2015Co-Authors: Bernard JenniferAbstract:African swine fever (ASF) is a contagious hemorrhagic disease with disastrous financial consequences for pig industry, as no vaccine or treatment exists. This infection is caused by a DNA virus, only member of the Asfarviridae family that can be directly transmitted between swine or by a non-compulsory vector, the Ornithodoros tick. Ornithodoros ticks play a role in the persistence of the disease within wild and domestic suids in Africa. They were also involved in resurgences of outbreaks in some pig farms in the Iberian Peninsula in 1970-1980. ASF, eradicated in Europe at the end of the 1980’s except in Sardinia, was reintroduced in Georgia in 2007 then spread towards the Eastern European Union. The question of the tick vector competence for ASF virus (ASFV) and its related determinants is of importance in the risk assessment of endemisation/spread of the disease in Europe or elsewhere.The first chapter of this thesis aims to characterize Ornithodoros tick vector competence for ASFV and to highlight a common pattern to qualify it. For this purpose, a systematic review of the studies carried out on the vector competence of one or more tick species for one or more ASFV, was performed on the last 50 years publications. A high variability of the results obtained for different couples “tick-virus” was highlighted. As most of the papers describe partial evaluation of the vector competence and because of the high number of methods used to perform these assessments, it was definitively very difficult to compare these results, and to propose common patterns. However, each of these studies revealed a part of the mechanisms that participated to the adaptation in the couple “tick-virus”, and suggested the importance of different determinants, out of them, two were experimentally assessed as described in the two other chapters.The second chapter of this thesis describes the adaptation “tick-virus” through the experimental infection of three different ticks, O. erraticus, O. porcinus and O. moubata by two ASFV strains belonging to the genotype II. O erraticus’s competence is known for ASFV strains belonging to the genotype I but has never demonstrated the ASFV Georgia 2007/1 strain (genotype II) and currently circulating in Europe. However, the experiments we performed, suggest that many experimental conditions could influence the results obtained on vector competence as the tick colony or the virus dose used for the tick infection.The third chapter describes the effect of the tick saliva on the ASFV transmission from the tick to the pig. Tick saliva contains important immunomodulatory molecules that interfere with the pig immune system permitting complete engorgement of the tick on its host. The host-vector and pathogen interactions were studied through an in vivo experimentation involving pig, O porcinus tick and ASFV Ambat02 strain (genotype II). The local and systemic effects on the pig immune responses were assessed with the ASFV alone or combined with tick gland extract, versus a healthy tick bite. Data analysis highlighted the tick saliva role on skin immune cell recruitment and its potential effect on local infection.La peste porcine africaine (PPA) est une maladie hémorragique contagieuse dévastatrice pour l’élevage porcin pour laquelle aucun traitement ni vaccin ne sont disponibles. Cette infection est due à un virus à ADN, unique membre de la famille des Asfarviridae, qui se transmet directement entre suidés ou via un vecteur, la tique du genre Ornithodoros. Le rôle de ces tiques dans le cycle épidémiologique de la PPA consiste principalement à maintenir le virus dans les populations de suidés sauvages en Afrique. Elles ont aussi été identifiées à l’origine de certains cas de résurgence de la maladie dans des bâtiments d’élevage porcin, notamment dans la péninsule ibérique, lors des années 1970-80. La PPA, éradiquée fin des années 1980 en Europe (à l’exception de la Sardaigne), a été de nouveau introduite en 2007 d’abord en Géorgie pour progresser jusqu’à atteindre l’Est de l’Union Européenne. La question de la compétence vectorielle des tiques Ornithodores pour le virus de la PPA et des déterminants qui influencent cette compétence est posée dans l’évaluation des risques d’endémisation et/ou de dispersion de la maladie en Europe et ailleurs. Le premier chapitre de cette thèse vise à caractériser la compétence vectorielle des tiques Ornithodores pour le virus de la PPA et faire ressortir les patrons généraux qui la qualifient. Pour cela, a été réalisée une revue systématique des études ayant testé la compétence vectorielle d’une ou plusieurs espèces de tiques pour une ou plusieurs souches virales de PPA durant ces 50 dernières années. Au final, il en ressort une forte variabilité de résultats selon les couples tique-virus. En outre, il semble difficile de comparer ces résultats et d’établir des « profils types » du fait de l’évaluation partielle de la compétence vectorielle pour de nombreux couples tique-virus et de la diversité des méthodologies utilisées pour tester et mesurer la compétence. Pour autant chaque modalité d’étude révèle une partie des mécanismes et des adaptations auxquels sont soumis les couples tique–virus et suggère l’effet de certains déterminants dont deux sont traités dans les deux autres chapitres de la thèse. Le second chapitre de la thèse traite de l’adaptation tique-virus, par l’étude expérimentale de l’infection des tiques O. erraticus, O. porcinus et O. moubata à l’aide de deux souches de génotype II du virus de la PPA, et par un essai de transmission du virus des tiques aux porcs. Des souches du génotype II ont été choisies car ce génotype circule actuellement en Europe et risque d’infecter les tiques européennes O. erraticus s’il se propage jusqu’en péninsule ibérique. Alors qu’O. erraticus est capable de s’infecter et de transmettre différentes souches virales du génotype I, sa compétence à transmettre la souche Georgia2007/1 (génotype II) n’a pour l’instant pas été démontrée. Toutefois, nos études suggèrent que les résultats de compétence dépendent aussi des conditions d’expérimentation telles que la nature des colonies de tiques utilisées ou encore le titre viral utilisé pour infecter les tiques. Le dernier chapitre de la thèse porte sur l’effet de la salive de tique sur l’étape de transmission du virus de la PPA par la tique au porc. Durant le repas de sang, la salive est un élément essentiel qui va permettre l’accroche et le gorgement durable de la tique sur son hôte, avec des propriétés immuno-modulatrices importantes agissant directement sur l’hôte. Ainsi a été réalisée une étude expérimentale in vivo faisant intervenir la tique O. porcinus et le virus Ambat02 (génotype II) et testant l’effet local et systémique chez le porc d’un extrait de glandes salivaires de tique co-inoculé ou non avec le virus de la PPA, versus la piqûre naturelle de tiques non infectées. Les résultats de cette expérience nous montrent que la salive de tique est capable de moduler au niveau local le recrutement de cellules immunitaires dans la peau du porc et potentiellement influencer l’infection locale chez le porc
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Caractérisation de la compétence vectorielle des tiques Ornithodores pour le virus de la peste porcine africaine et étude de deux déterminants : la relation souche virale - vecteur et l'influence de la salive de tiques sur l'infection chez le porc do
Université de Montpellier, 2015Co-Authors: Bernard JenniferAbstract:La peste porcine africaine (PPA) est une maladie hémorragique contagieuse dévastatrice pour l'élevage porcin pour laquelle aucun traitement ni vaccin ne sont disponibles. Cette infection est due à u n virus à ADN, unique membre de la famille des Asfarviridae, qui se transmet directement entre suidés ou via un vecteur, la tique du genre Ornithodoros. Le rôle de ces tiques dans le cycle épidémiologique de la PPA consiste principalement à maintenir le virus dans les populations de suidés sauvages en Afrique. Elles ont aussi été identifiées à l'origine de certains cas de résurgence de la maladie dans des bâtiments d'élevage porcin, notamment dans la péninsule ibérique, lors des années 1970 -80. La PPA, éradiquée fin des années 1980 en Europe (à l'exception de la Sardaigne), a été de nouveau introduite en 2007 en Géorgie pour progresser jusqu'à l'Est de l'Union Européenne. La question de la compétence vectorielle des tiques Ornithodoros pour le virus de la PPA et des déterminants qui influencent cette compétence est posée dans l'évaluation des risques d'endémisation et/ou de dispersion de la maladie. Le premier chapitre de cette thèse vise à caractériser la compétence vectorielle des tiques Ornithodoros pour le virus de la PPA et faire ressortir les patrons généraux qui la qualifient. Pour cela, a été réalisée une revue systématique des études ayant testé la compétence vectorielle d'une ou plusieurs espèces de tiques pour une ou plusieurs souches vira les de PPA durant ces 50 dernières a n nées. Au final, il en ressort une forte variabilité de résultats selon les couples tique-virus. En outre, il semble difficile de comparer ces résultats et d'établir des "profils types" du fait de l'évaluation partielle de la compétence vectorielle pour de nombreux couples tique-virus et de la diversité des méthodologies utilisées pour tester et mesurer la compétence. Pour autant chaque modalité d'étude révèle une partie des mécanismes et des adaptations auxquels sont sou mis les couples tique-virus et suggère l'effet de certains déterminants dont deux sont traités dans les deux autres chapitres de la thèse. Le second chapitre de la thèse traite de l'adaptation tique-virus, par l'étude expérimentale de l'infection des tiques O. erraticus, O. porcinus et O. moubata à l'aide de deux souches de génotype Il du virus de la PPA, et par un essai de transmission du virus des tiques aux porcs. Des souches du génotype Il ont été choisies car ce génotype circule actuellement en Europe et risque d'infecter les tiques européennes O. erraticus s'il se propage jusqu'en péninsule ibérique. Alors qu'O. erraticus est capable de s'infecter et de transmettre différentes souches virales du génotype 1, sa compétence à transmettre la souche Georgia2007/1 (génotype Il) n'a pour l'instant pas été démontrée. Toutefois, nos études suggèrent que les résultats de compétence dépendent aussi des conditions d'expérimentation telles que la nature des colonies de tiques utilisées ou encore le titre viral utilisé pour infecter les tiques. Le dernier chapitre de la thèse porte sur l'effet de la salive de tique sur l'étape de transmission du virus de la PPA par la tique au porc. Durant le repas de sang, la salive est un élément essentiel qui va permettre l'accroche et le gorgement durable de la tique sur son hôte, avec des propriétés immunomodulatrices importantes agissant directement sur l'hôte. Ainsi a été réalisée une étude expérimentale in vivo faisant intervenir la tique O. porcinus et le virus Ambat02 (génotype II) et testant l'effet local et systémique chez le porc d'un extrait de glandes salivaires de tique co-inoculé ou non avec le virus de la PPA, versus la piqûre naturelle de tiques non infectées. Les résultats de cette expérience nous montrent que la salive de tique est capable de moduler au niveau local le recrutement de cellules immunitaires dans la peau du porc et potentiellement influencer l'infection locale chez le porc. (Résumé d'auteur
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Is Ornithodoros erraticus able to transmit the Georgia2007/1 African Swine Fever virus isolate to domestic pigs?
'CIRAD (Centre de Cooperation Internationale en Recherche Agronomique Pour le Developpement)', 2015Co-Authors: Bernard Jennifer, Vial Laurence, Hutet Evelyne, Paboeuf Frédéric, Michaud Vincent, Boinas Fernando, Le Potier Marie-frédériqueAbstract:Objective: African swine fever, one of the most devastating diseases affecting wild and domestic swine, is due to a large DNA virus, only member of the Asfarviridae family. After ASF introduction in Georgia in 2007, the disease became endemic in the Caucasian region of the Russian Federation and spread towards the Western regions of Europe entering in EU Members States at the beginning of 2014. As no vaccine or antiviral are available to fight against this infection, the only tools to control it are preventive measures based on early detection and actual knowledge of the epidemiological risks. In African sub-Saharan countries, ASF persistence is described to be related to different and complex epidemiological scenarii involving domestic and wild suids and soft tick vectors of the genus Ornithodoros. In EU, one species of Ornithodoros, O. erraticus, is known to be able to maintain and/or transmit some ASFV isolates classified in the genotype I. Recently, the Pirbright Institute also demonstrated that O. erraticus was able to amplify the Georgia2007/1 ASFV (genotype II), at least during 3 months. The objective of the current study was to evaluate the in- vitro and in-vivo transmissibility of the Georgia 2007/1 ASFV by infected O. erraticus ticks. Methods: The Georgia 2007/1 ASFV strain belonging to the genotype II, kindly provided by L. Dixon (OIE reference lab), was grown on porcine pulmonary alveolar macrophages to the titre of 106to 107 HAD50 , then diluted 100-fold into pig blood for tick infection or 1000-fold in medium for intradermal inoculation to pigs. Ticks were captured in Portugal by F. Boinas and mass reared at CIRAD for one year and a half to obtain a stable and mature population. During this period, several techniques of artificial feeding were tested to optimize the method. In December 2014, 60 adults or last nymphal stages -group A- coming both from field and 1st generation laboratory were artificially engorged on pig blood supplemented with Georgia 2007/1 at a final titre of 104.5 HAD50/mL blood. Two other groups of ASFV-free ticks –group B with 60 individuals and group C with 30 individuals- were reared to be used for a second infection directly on infected pigs (group B) and as control group (group C), respectively. Moreover to confirm the possibility to infect ticks through artificial blood meal, another group of 10 ticks was also engorged and tested for virus multiplication three months later. Fifteen other females were also infected and secondarily engorged on ASFV-free pig blood to test in-vitro transmission through virus isolation on second blood meal. Considering that it is difficult to obtain ASFV titres with in-vitro cultivation as high as in infected pigs developing ASFV clinical signs, it seems important to compare ASFV transmissibility between ticks artificially infected in laboratory and ticks directly infected on ASFV-infected pigs and conclude on possible dose effect. In March 2015, 18 Large-White pigs obtained from a high sanitary level field herd were distributed to 4 groups at Anses-Ploufragan high security facilities. Two negative control groups of 3 pigs were either intra-dermally inoculated with MEM or bitten by group C of 30 healthy ticks. One group of 6 pigs was intra-dermally inoculated with 103 HAD50 ASFV while the last group of 6 pigs was bitten by group A of 60 ticks previously infected through artificial blood meal and dispatched in 10 ticks/pig. Pots of 10 ticks were placed on one ear held there with adhesive tape, then removed after 3 hours. After removal, ticks were numbered in two batches: engorged and unengorged ticks. Finally, as soon as the 6 pigs intra-dermally inoculated with ASFV showed fever and high viremiae, group B of 60 ASFV-free ticks were proposed to engorge on their opposite ear. These ticks would be proposed to secondarily engorge on membrane feeding or healthy pigs three months later. Post tick feeding or intradermal inoculation, clinical examination and rectal temperatures were recorded daily, until the animals were euthanized or for a minimum period of 18 days. Except on D1 pi, serum and EDTA blood samples were daily collected from all the pigs during the first week pi, then twice a week during the 2 following weeks, and at the day of euthanasia for virological and serological assays. Organ samples were collected during necropsy. The animal experiment protocol was approved by the French national ethics committee ComEth Anses/ENVA/UPEC (10/03/15-9). Results: Ten ticks from the original batch of ticks that were artificially fed on infectious blood were tested by virus titration. Out of them, 8 were positive with a titre ranging from 102 to 104.2 HAD50/tick and 2 ticks clearly amplified the virus regarding the estimated amount of virus originally ingested (minimum of 1 log superior). After feeding on pigs, the mean level of engorged ticks was of 62%, whatever the group of pigs. The experiment, currently running, confirmed the high virulence of the Georgia strain as all the 6 intra-dermally inoculated pigs displayed typical symptoms of ASF including lost of appetite and hyperthermia from D3 pi. The 6 pigs were euthanized from D5 to D7. The group of the 6 pigs bitten by the infected ticks was still healthy at 18 days post feeding, as well as the two negative control groups. However, among the 15 female ticks secondarily engorged on ASFV-free pig blood, no heamadsorption effect was observed after two passages on alveolar macrophage culture using blood-meal leftovers. Further investigations are needed to confirm the presence of ASF Virus. The final experimental infection of pigs through tick bite using ticks previously engorged on viremic pigs should allow concluding on the ability of O. erraticus to transmit Georgia2007/1 and a possible dose effect on this transmissibility. The results will be presented and discuss during the symposium. Conclusion: The objective of this study was to experimentally assess the ability of the European O. erraticus tick to transmit the Georgia 2007/1 ASFV currently circulating in North-Eastern EU. First results showed that ticks artificially infected in laboratory did not induce ASF clinical signs in pigs by biting. However, virus titration in ticks seems to show that the virus is present in the arthropod. Further in-vitro and in-vivo investigations are running to explore the hypothesis of a dose effect. The expected results should clarify the potential epidemiological role of O. erraticus ticks in transmission and re-emergence of ASFV in the field, in case of the spread of current active foci from North-Eastern EU. (Résumé d'auteur
Michael G. Rossmann - One of the best experts on this subject based on the ideXlab platform.
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pacmanvirus a new giant icosahedral virus at the crossroads between Asfarviridae and faustoviruses
Journal of Virology, 2017Co-Authors: Julien Andreani, Jacques Bou Khalil, Madhumati Sevvana, Fabrizio Di Pinto, Samia Benamar, Thomas Klose, Idir Bitam, Philippe Colson, Michael G. RossmannAbstract:African swine fever virus, a double-stranded DNA virus that infects pigs, is the only known member of the Asfarviridae family. Nevertheless, during our isolation and sequencing of the complete genome of faustovirus, followed by the description of kaumoebavirus, carried out over the past 2 years, we observed the emergence of previously unknown related viruses within this group of viruses. Here we describe the isolation of pacmanvirus, a fourth member in this group, which is capable of infecting Acanthamoeba castellanii. Pacmanvirus A23 has a linear compact genome of 395,405 bp, with a 33.62% G + C content. The pacmanvirus genome harbors 465 genes, with a high coding density. An analysis of reciprocal best hits shows that 31 genes are conserved between African swine fever virus, pacmanvirus, faustovirus, and kaumoebavirus. Moreover, the major capsid protein locus of pacmanvirus appears to be different from those of kaumoebavirus and faustovirus. Overall, comparative and genomic analyses reveal the emergence of a new group or cluster of viruses encompassing African swine fever virus, faustovirus, pacmanvirus, and kaumoebavirus. IMPORTANCE Pacmanvirus is a newly discovered icosahedral double-stranded DNA virus that was isolated from an environmental sample by amoeba coculture. We describe herein its structure and replicative cycle, along with genomic analysis and genomic comparisons with previously known viruses. This virus represents the third virus, after faustovirus and kaumoebavirus, that is most closely related to classical representatives of the Asfarviridae family. These results highlight the emergence of previously unknown double-stranded DNA viruses which delineate and extend the diversity of a group around the asfarvirus members.
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pacmanvirus a new giant icosahedral virus at the crossroads between Asfarviridae and faustoviruses
Journal of Virology, 2017Co-Authors: Julien Andreani, Jacques Bou Khalil, Madhumati Sevvana, Fabrizio Di Pinto, Samia Benamar, Michael G. Rossmann, Thomas Klose, Idir Bitam, Philippe Colson, Didier RaoultAbstract:African swine fever virus, a double-stranded DNA virus that infects pigs, is the only known member of the Asfarviridae family. Nevertheless, during our isolation and sequencing of the complete genome of faustovirus, followed by the description of kaumoebavirus, carried out over the past 2 years, we observed the emergence of previously unknown related viruses within this group of viruses. Here we describe the isolation of pacmanvirus, a fourth member in this group, which is capable of infecting Acanthamoeba castellanii. Pacmanvirus A23 has a linear compact genome of 395,405 bp, with a 33.62% G + C content. The pacmanvirus genome harbors 465 genes, with a high coding density. An analysis of reciprocal best hits shows that 31 genes are conserved between African swine fever virus, pacmanvirus, faustovirus, and kaumoebavirus. Moreover, the major capsid protein locus of pacmanvirus appears to be different from those of kaumoebavirus and faustovirus. Overall, comparative and genomic analyses reveal the emergence of a new group or cluster of viruses encompassing African swine fever virus, faustovirus, pacmanvirus, and kaumoebavirus. IMPORTANCE Pacmanvirus is a newly discovered icosahedral double-stranded DNA virus that was isolated from an environmental sample by amoeba coculture. We describe herein its structure and replicative cycle, along with genomic analysis and genomic comparisons with previously known viruses. This virus represents the third virus, after faustovirus and kaumoebavirus, that is most closely related to classical representatives of the Asfarviridae family. These results highlight the emergence of previously unknown double-stranded DNA viruses which delineate and extend the diversity of a group around the asfarvirus members.
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faustovirus an asfarvirus related new lineage of giant viruses infecting amoebae
Journal of Virology, 2015Co-Authors: Dorine G Reteno, Jacques Bou Khalil, Nicholas Armstrong, Julien Andreani, Samia Benamar, Michael G. Rossmann, Thomas Klose, Philippe Colson, Bernard La ScolaAbstract:Giant viruses are protist-associated viruses belonging to the proposed order Megavirales; almost all have been isolated from Acanthamoeba spp. Their isolation in humans suggests that they are part of the human virome. Using a high-throughput strategy to isolate new giant viruses from their original protozoan hosts, we obtained eight isolates of a new giant viral lineage from Vermamoeba vermiformis, the most common free-living protist found in human environments. This new lineage was proposed to be the faustovirus lineage. The prototype member, faustovirus E12, forms icosahedral virions of ≈200 nm that are devoid of fibrils and that encapsidate a 466-kbp genome encoding 451 predicted proteins. Of these, 164 are found in the virion. Phylogenetic analysis of the core viral genes showed that faustovirus is distantly related to the mammalian pathogen African swine fever virus, but it encodes ≈3 times more mosaic gene complements. About two-thirds of these genes do not show significant similarity to genes encoding any known proteins. These findings show that expanding the panel of protists to discover new giant viruses is a fruitful strategy. IMPORTANCE By using Vermamoeba, a protist living in humans and their environment, we isolated eight strains of a new giant virus that we named faustovirus. The genomes of these strains were sequenced, and their sequences showed that faustoviruses are related to but different from the vertebrate pathogen African swine fever virus (ASFV), which belongs to the family Asfarviridae. Moreover, the faustovirus gene repertoire is ≈3 times larger than that of ASFV and comprises approximately two-thirds ORFans (open reading frames [ORFs] with no detectable homology to other ORFs in a database).
