Studies into host macrophage transcriptional control by the African Swine Fever Virus protein A238L

African swine fever virus (ASFV) is a large double-stranded DNA virus which causes a lethal haemorrhagic fever in domestic pigs. This virus primarily infects cells from the monocyte/macrophage lineage and its ability to manipulate the function of these cells is key to the pathogenesis of this disease. ASFV encodes several proteins involved in immune evasion. One of these proteins, A238L, has been shown to inhibit host macrophage gene transcription. This protein has been shown to interact with several cellular proteins involved in signal transduction: a serine/threonine protein phosphatase, calcinerurin (CaN), the transcription factor NF-кB, and most recently the transcriptional co-activator CREB binding protein (CBP/P300). However its exact mechanism of action is not fully understood. Previous work has been limited to the investigation of individual signaling pathways and/or the expression of individual host genes. The aim of this study was to investigate the global effect of A238L on host macrophage gene transcription and also to carry out further investigation into the mechanism by which this protein functions. To determine the global effect of A238L on host macrophage gene transcription differential gene expression between porcine cells expressing A238L and control cells was examined using a porcine oligonucleotide microarray. These results demonstrated that A238L was a potent inhibitor of host macrophage gene expression. Functional characterisation of the annotated genes showed that a large proportion of A238L down-regulated genes are typically induced in response to cell stress. Significantly, genes regulated by the I kappa B kinase (IKK), mitogen-activated protein kinase (MAPK) and janus kinase/signal transducers and activators of transcription (JAK/STAT) signaling pathways were all shown to be down regulated by A238L. Genes associated with the MAPK pathways were particularly enriched. The transcription of A238L-regulated genes is controlled by numerous different transcription factors, including NF-кB. All of the transcription factors identified interact with the transcription co-activator CBP/P300. This provides a common link between these factors, and indicates that A238L may target CBP/P300 to inhibit gene transcription. This observation supports recent work demonstrating that A238L interacts with and inhibits CBP/P300 function. To explore the potential mechanisms involved in the nuclear localisation of A238L, ASFV-infected Vero cells, expressing A238L under the control of its own promoter, were examined under a range of conditions using confocal microscopy. The results demonstrated that A238L was actively imported into the nucleus and exported by a CRM 1 mediated pathway, although a pool of A238L protein remained in the cytoplasm. Sequence analysis of A238L identified the presence of two putative nuclear localisation signals (NLS-1 and NLS-2). NLS-2 was located within A238L’s CaN docking motif. Mutation of these motifs indicated that both NLS-1 and NLS-2 are active and exhibit functional redundancy. Mutation of the CaN docking motif alone, in the presence of intact NLS-2, resulted in a dramatic increase in the nuclear localisation of A238L. These results are consistent with a model in which A238L functions within both the nucleus and the cytoplasm and suggest that binding of CaN to A238L masks NLS-2, contributing to the cytoplasmic retention of A238L

Blood-feeding, susceptibility to infection with Schmallenberg virus and phylogenetics of Culicoides (Diptera: Ceratopogonidae) from the United Kingdom

BACKGROUND: Culicoides biting midges (Diptera: Ceratopogonidae) are responsible for the biological transmission of internationally important arboviruses of livestock. In 2011, a novel Orthobunyavirus was discovered in northern Europe causing congenital malformations and abortions in ruminants. From field studies, Culicoides were implicated in the transmission of this virus which was subsequently named Schmallenberg virus (SBV), but to date no assessment of susceptibility to infection of field populations under standardised laboratory conditions has been carried out. We assessed the influence of membrane type (chick skin, collagen, Parafilm M®) when offered in conjunction with an artificial blood-feeding system (Hemotek, UK) on field-collected Culicoides blood-feeding rates. Susceptibility to infection with SBV following blood-feeding on an SBV-blood suspension provided via either (i) the Hemotek system or via (ii) a saturated cotton wool pledglet was then compared. Schmallenberg virus susceptibility was defined by RT-qPCR of RNA extractions of head homogenates and related to Culicoides species and haplotype identifications based on the DNA barcode region of the mitochondrial cytochrome c oxidase 1 (cox1) gene. RESULTS: Culicoides blood-feeding rates were low across all membrane types tested (7.5% chick skin, 0.0% for collagen, 4.4% Parafilm M®, with 6029 female Culicoides being offered a blood meal in total). Susceptibility to infection with SBV through membrane blood-feeding (8 of 109 individuals tested) and pledglet blood-feeding (1 of 94 individuals tested) was demonstrated for the Obsoletus complex, with both C. obsoletus (Meigen) and C. scoticus Downes & Kettle susceptible to infection with SBV through oral feeding. Potential evidence of cryptic species within UK populations was found for the Obsoletus complex in phylogenetic analyses of cox1 DNA barcodes of 74 individuals assessed from a single field-site. CONCLUSIONS: Methods described in this study provide the means to blood-feed Palaearctic Culicoides for vector competence studies and colonisation attempts. Susceptibility to SBV infection was 7.3% for membrane-fed members of the subgenus Avaritia and 1.1% for pledglet-fed. Both C. obsoletus and C. scoticus were confirmed as being susceptible to infection with SBV, with potential evidence of cryptic species within UK Obsoletus complex specimens, however the implications of cryptic diversity in the Obsoletus complex on arbovirus transmission remains unknow

Studies into host macrophage transcriptional control by the African Swine Fever Virus protein A238L

African swine fever virus (ASFV) is a large double-stranded DNA virus which causes a lethal haemorrhagic fever in domestic pigs. This virus primarily infects cells from the monocyte/macrophage lineage and its ability to manipulate the function of these cells is key to the pathogenesis of this disease. ASFV encodes several proteins involved in immune evasion. One of these proteins, A238L, has been shown to inhibit host macrophage gene transcription. This protein has been shown to interact with several cellular proteins involved in signal transduction: a serine/threonine protein phosphatase, calcinerurin (CaN), the transcription factor NF-кB, and most recently the transcriptional co-activator CREB binding protein (CBP/P300). However its exact mechanism of action is not fully understood. Previous work has been limited to the investigation of individual signaling pathways and/or the expression of individual host genes. The aim of this study was to investigate the global effect of A238L on host macrophage gene transcription and also to carry out further investigation into the mechanism by which this protein functions. To determine the global effect of A238L on host macrophage gene transcription differential gene expression between porcine cells expressing A238L and control cells was examined using a porcine oligonucleotide microarray. These results demonstrated that A238L was a potent inhibitor of host macrophage gene expression. Functional characterisation of the annotated genes showed that a large proportion of A238L down-regulated genes are typically induced in response to cell stress. Significantly, genes regulated by the I kappa B kinase (IKK), mitogen-activated protein kinase (MAPK) and janus kinase/signal transducers and activators of transcription (JAK/STAT) signaling pathways were all shown to be down regulated by A238L. Genes associated with the MAPK pathways were particularly enriched. The transcription of A238L-regulated genes is controlled by numerous different transcription factors, including NF-кB. All of the transcription factors identified interact with the transcription co-activator CBP/P300. This provides a common link between these factors, and indicates that A238L may target CBP/P300 to inhibit gene transcription. This observation supports recent work demonstrating that A238L interacts with and inhibits CBP/P300 function. To explore the potential mechanisms involved in the nuclear localisation of A238L, ASFV-infected Vero cells, expressing A238L under the control of its own promoter, were examined under a range of conditions using confocal microscopy. The results demonstrated that A238L was actively imported into the nucleus and exported by a CRM 1 mediated pathway, although a pool of A238L protein remained in the cytoplasm. Sequence analysis of A238L identified the presence of two putative nuclear localisation signals (NLS-1 and NLS-2). NLS-2 was located within A238L’s CaN docking motif. Mutation of these motifs indicated that both NLS-1 and NLS-2 are active and exhibit functional redundancy. Mutation of the CaN docking motif alone, in the presence of intact NLS-2, resulted in a dramatic increase in the nuclear localisation of A238L. These results are consistent with a model in which A238L functions within both the nucleus and the cytoplasm and suggest that binding of CaN to A238L masks NLS-2, contributing to the cytoplasmic retention of A238L.EThOS - Electronic Theses Online ServiceGBUnited Kingdo

Blood-feeding, susceptibility to infection with Schmallenberg virus and phylogenetics of Culicoides (Diptera: Ceratopogonidae) from the United Kingdom

Abstract Background Culicoides biting midges (Diptera: Ceratopogonidae) are responsible for the biological transmission of internationally important arboviruses of livestock. In 2011, a novel Orthobunyavirus was discovered in northern Europe causing congenital malformations and abortions in ruminants. From field studies, Culicoides were implicated in the transmission of this virus which was subsequently named Schmallenberg virus (SBV), but to date no assessment of susceptibility to infection of field populations under standardised laboratory conditions has been carried out. We assessed the influence of membrane type (chick skin, collagen, Parafilm M®) when offered in conjunction with an artificial blood-feeding system (Hemotek, UK) on field-collected Culicoides blood-feeding rates. Susceptibility to infection with SBV following blood-feeding on an SBV-blood suspension provided via either (i) the Hemotek system or via (ii) a saturated cotton wool pledglet was then compared. Schmallenberg virus susceptibility was defined by RT-qPCR of RNA extractions of head homogenates and related to Culicoides species and haplotype identifications based on the DNA barcode region of the mitochondrial cytochrome c oxidase 1 (cox1) gene. Results Culicoides blood-feeding rates were low across all membrane types tested (7.5% chick skin, 0.0% for collagen, 4.4% Parafilm M®, with 6029 female Culicoides being offered a blood meal in total). Susceptibility to infection with SBV through membrane blood-feeding (8 of 109 individuals tested) and pledglet blood-feeding (1 of 94 individuals tested) was demonstrated for the Obsoletus complex, with both C. obsoletus (Meigen) and C. scoticus Downes & Kettle susceptible to infection with SBV through oral feeding. Potential evidence of cryptic species within UK populations was found for the Obsoletus complex in phylogenetic analyses of cox1 DNA barcodes of 74 individuals assessed from a single field-site. Conclusions Methods described in this study provide the means to blood-feed Palaearctic Culicoides for vector competence studies and colonisation attempts. Susceptibility to SBV infection was 7.3% for membrane-fed members of the subgenus Avaritia and 1.1% for pledglet-fed. Both C. obsoletus and C. scoticus were confirmed as being susceptible to infection with SBV, with potential evidence of cryptic species within UK Obsoletus complex specimens, however the implications of cryptic diversity in the Obsoletus complex on arbovirus transmission remains unknown

Additional file 1: Table S1. of Blood-feeding, susceptibility to infection with Schmallenberg virus and phylogenetics of Culicoides (Diptera: Ceratopogonidae) from the United Kingdom

GenBank sequences used in the genetic analyses of Obsoletus complex of Culicoides. Includes references listed for GenBank sequences. (DOCX 79 kb

The genome of the biting midge Culicoides sonorensis and gene expression analyses of vector competence for bluetongue virus

BACKGROUND: The new genomic technologies have provided novel insights into the genetics of interactions between vectors, viruses and hosts, which are leading to advances in the control of arboviruses of medical importance. However, the development of tools and resources available for vectors of non-zoonotic arboviruses remains neglected. Biting midges of the genus Culicoides transmit some of the most important arboviruses of wildlife and livestock worldwide, with a global impact on economic productivity, health and welfare. The absence of a suitable reference genome has hindered genomic analyses to date in this important genus of vectors. In the present study, the genome of Culicoides sonorensis, a vector of bluetongue virus (BTV) in the USA, has been sequenced to provide the first reference genome for these vectors. In this study, we also report the use of the reference genome to perform initial transcriptomic analyses of vector competence for BTV. RESULTS: Our analyses reveal that the genome is 189 Mb, assembled in 7974 scaffolds. Its annotation using the transcriptomic data generated in this study and in a previous study has identified 15,612 genes. Gene expression analyses of C. sonorensis females infected with BTV performed in this study revealed 165 genes that were differentially expressed between vector competent and refractory females. Two candidate genes, glutathione S-transferase (gst) and the antiviral helicase ski2, previously recognized as involved in vector competence for BTV in C. sonorensis (gst) and repressing dsRNA virus propagation (ski2), were confirmed in this study. CONCLUSIONS: The reference genome of C. sonorensis has enabled preliminary analyses of the gene expression profiles of vector competent and refractory individuals. The genome and transcriptomes generated in this study provide suitable tools for future research on arbovirus transmission. These provide a valuable resource for these vector lineage, which diverged from other major Dipteran vector families over 200 million years ago. The genome will be a valuable source of comparative data for other important Dipteran vector families including mosquitoes (Culicidae) and sandflies (Psychodidae), and together with the transcriptomic data can yield potential targets for transgenic modification in vector control and functional studies