Project description:Alcelaphine gammaherpesvirus 1 (AlHV-1) is a member of the Gammaherpesvirinae subfamily and establishes asymptomatic latent infection in its natural host species, the wildebeest. Cross-species transmission to various ruminant species including cattle can occur, resulting in the induction of malignant catarrhal fever (MCF), a deadly peripheral T cell lymphoproliferative disease. Here, we experimentally infected calves to confirm that AlHV-1 latency-associated gene expression is essential for persistent infection of CD8+ T cells and MCF development. Then, deep sequencing of the T cell receptor repertoire revealed an oligoclonal expansion of peripheral CD8+ T cells during bovine MCF, associated with transcriptomic and epigenetic changes identified by (sc)RNA-seq and ATAC-seq analyses which indicated a mixed effector/memory and exhaustion phenotype of infected cells in vivo. Analysis of the viral genome transcription identified viral genomic regions being expressed in infected CD8+ T cells, such as the region predicted to encode the gene A10. A10 encodes a transmembrane signaling protein displaying multiple tyrosine residues, with predicted ITAM and SH3 motifs. We could demonstrate that impaired expression of A10 did not affect AlHV-1 replication in vitro but rendered AlHV-1 unable to induce MCF in the rabbit experimental model, and we showed that A10 is phosphorylated in T lymphocytes in vitro and affects T cell signaling. Finally, while AlHV-1 viruses expressing mutated forms of A10 devoid of ITAM and/or SH3 motifs could induce MCF, an A10 knock-in viral mutant unable to phosphorylate tyrosine residues resulted in the absence of MCF development. Overall, we identified AlHV-1-induced phenotypic changes in CD8+ T cells during MCF and demonstrated that A10 expression in infected CD8+ T lymphocytes results in the dysregulation of T cell signaling and MCF.

Project description:Alcelaphine gammaherpesvirus 1 (AlHV-1) is a member of the Gammaherpesvirinae subfamily and establishes asymptomatic latent infection in its natural host species, the wildebeest. Cross-species transmission to various ruminant species including cattle can occur, resulting in the induction of malignant catarrhal fever (MCF), a deadly peripheral T cell lymphoproliferative disease. Here, we experimentally infected calves to confirm that AlHV-1 latency-associated gene expression is essential for persistent infection of CD8+ T cells and MCF development. Then, deep sequencing of the T cell receptor repertoire revealed an oligoclonal expansion of peripheral CD8+ T cells during bovine MCF, associated with transcriptomic and epigenetic changes identified by (sc)RNA-seq and ATAC-seq analyses which indicated a mixed effector/memory and exhaustion phenotype of infected cells in vivo. Analysis of the viral genome transcription identified viral genomic regions being expressed in infected CD8+ T cells, such as the region predicted to encode the gene A10. A10 encodes a transmembrane signaling protein displaying multiple tyrosine residues, with predicted ITAM and SH3 motifs. We could demonstrate that impaired expression of A10 did not affect AlHV-1 replication in vitro but rendered AlHV-1 unable to induce MCF in the rabbit experimental model, and we showed that A10 is phosphorylated in T lymphocytes in vitro and affects T cell signaling. Finally, while AlHV-1 viruses expressing mutated forms of A10 devoid of ITAM and/or SH3 motifs could induce MCF, an A10 knock-in viral mutant unable to phosphorylate tyrosine residues resulted in the absence of MCF development. Overall, we identified AlHV-1-induced phenotypic changes in CD8+ T cells during MCF and demonstrated that A10 expression in infected CD8+ T lymphocytes results in the dysregulation of T cell signaling and MCF.

Project description:Alcelaphine herpesvirus 1 (AlHV-1) is a ?-herpesvirus (?-HV) carried asymptomatically by wildebeest. Upon cross-species transmission, AlHV-1 induces an acute and fatal lymphoproliferative disease named malignant catarrhal fever (MCF) in many ruminants, including cattle and the rabbit model. Latency has been shown to be essential for MCF induction. However, the mechanisms causing the activation and proliferation of infected CD8+ T cells are unknown. Many ?-HVs express microRNAs (miRNAs). These small noncoding RNAs can suppress host or viral target genes involved in various pathways and are thought to facilitate viral infection and/or mediate activation and proliferation of infected lymphocytes. AlHV-1 genome has been predicted to encode a large number of miRNAs. However, their precise contribution in viral infection and pathogenesis in vivo remains unknown. Here, we have cloned small RNAs and sequenced 36 potential miRNAs expressed in a lymphoblastoid cell line propagated from a calf infected with AlHV-1 and developing MCF. Among the sequenced candidate miRNAs, 32 were expressed on the reverse strand of the genome in two main clusters. The expression of these 32 viral miRNAs was further validated using Northern blot and qRT-PCR in lymphoid organs of MCF-developing calves or rabbits. To determine the concerted contribution in MCF of 28 viral miRNAs clustered in the non-protein-coding region of the AlHV-1 genome, a recombinant virus was produced. The absence of these 28 miRNAs did not affect viral growth in vitro nor MCF induction in rabbits, demonstrating that AlHV-1 miRNAs clustered in the non-protein-coding genomic region are not essential for MCF induction. Small RNA sequencing from total RNA from AlHV-1-infected bovine lymphoblastoid cell line propagated with interleukin 2

Project description:Alcelaphine herpesvirus 1 (AlHV-1) is a γ-herpesvirus (γ-HV) carried asymptomatically by wildebeest. Upon cross-species transmission, AlHV-1 induces an acute and fatal lymphoproliferative disease named malignant catarrhal fever (MCF) in many ruminants, including cattle and the rabbit model. Latency has been shown to be essential for MCF induction. However, the mechanisms causing the activation and proliferation of infected CD8+ T cells are unknown. Many γ-HVs express microRNAs (miRNAs). These small noncoding RNAs can suppress host or viral target genes involved in various pathways and are thought to facilitate viral infection and/or mediate activation and proliferation of infected lymphocytes. AlHV-1 genome has been predicted to encode a large number of miRNAs. However, their precise contribution in viral infection and pathogenesis in vivo remains unknown. Here, we have cloned small RNAs and sequenced 36 potential miRNAs expressed in a lymphoblastoid cell line propagated from a calf infected with AlHV-1 and developing MCF. Among the sequenced candidate miRNAs, 32 were expressed on the reverse strand of the genome in two main clusters. The expression of these 32 viral miRNAs was further validated using Northern blot and qRT-PCR in lymphoid organs of MCF-developing calves or rabbits. To determine the concerted contribution in MCF of 28 viral miRNAs clustered in the non-protein-coding region of the AlHV-1 genome, a recombinant virus was produced. The absence of these 28 miRNAs did not affect viral growth in vitro nor MCF induction in rabbits, demonstrating that AlHV-1 miRNAs clustered in the non-protein-coding genomic region are not essential for MCF induction.

Project description:Wildebeests carry asymptomatically Alcelaphine herpesvirus 1 (AlHV-1), a M-NM-3-herpesvirus inducing a lethal lymphoproliferative disease named malignant catarrhal fever (MCF) in a number of susceptible species of the Artiodactyla order, including cattle. The local population welfare in eastern Africa is directly endangered by the important but underestimated impact of this disease on their livelihood. Although AlHV-1 genomic DNA is detected in abundance in tissues during MCF, no infectious viral particles and very low viral protein expression levels are observed. This suggests that AlHV-1 might be latent during MCF. Here, we studied the implication of AlHV-1 latency during MCF. We first examined the expression of poly-adenylated RNA from infected (multiplicity of infection, moi = 0.01) MDBK cells at 72h pi. This late time point was chosen as we expect the majority of viral genes to be expressed. The expression was obtained from two-color dye-swap analyses of 4 independent biological repeats. To determine cellular and viral gene expression during MCF, we extracted RNA from the inguinal LN (iLN) of each calf for analysis on a custom designed array. The arbitrary choice of the iLN as the selected tissue was based on the fact that AlHV-1 viral genomic load are the highest in the LN. Cellular and viral RNA transcription profiles were analyzed with two-color dye-swap analyses of 4 independent biological repeats. Cellular and viral gene expression were analysed in Mock- and AlHV-1-infected MDBK cells (in vitro) as well as in the inguinal lymphnodes of Mock- and AlHV-1-infected calves (in vivo). Each experiment (in vitro and in vivo) was carried out with 4 biological replicates for each conditon (mock- and AlHV-1-infected). The 4 samples for each experiment were hybridized in a one-to-one dye-swap design without pooling the Mock-infected samples, and yielding 8 arrays per experiment.

Project description:Wildebeests carry asymptomatically Alcelaphine herpesvirus 1 (AlHV-1), a γ-herpesvirus inducing a lethal lymphoproliferative disease named malignant catarrhal fever (MCF) in a number of susceptible species of the Artiodactyla order, including cattle. The local population welfare in eastern Africa is directly endangered by the important but underestimated impact of this disease on their livelihood. Although AlHV-1 genomic DNA is detected in abundance in tissues during MCF, no infectious viral particles and very low viral protein expression levels are observed. This suggests that AlHV-1 might be latent during MCF. Here, we studied the implication of AlHV-1 latency during MCF. We first examined the expression of poly-adenylated RNA from infected (multiplicity of infection, moi = 0.01) MDBK cells at 72h pi. This late time point was chosen as we expect the majority of viral genes to be expressed. The expression was obtained from two-color dye-swap analyses of 4 independent biological repeats. To determine cellular and viral gene expression during MCF, we extracted RNA from the inguinal LN (iLN) of each calf for analysis on a custom designed array. The arbitrary choice of the iLN as the selected tissue was based on the fact that AlHV-1 viral genomic load are the highest in the LN. Cellular and viral RNA transcription profiles were analyzed with two-color dye-swap analyses of 4 independent biological repeats.

Project description:Changes in gene expression in lymph node and kidney of cattle infected with alcelaphine herpesvirus-1. All animals in the group infected with AlHV-1 showed clinical signs of Malignant catarrhal fever (MCF) within one month. Diagnosis of MCF in these animals was confirmed by diagnostic PCR. No clinical signs were seen in the control animals, which were subject to post-mortem examination separately from the MCF-affected animals. RNA samples from kidney and lymph node of 4 MCF-affected and 4 control animals that passed the RNA quality criteria were used for array analysis. Quality assessments of probe-level Affymetrix chip data and normalised data were carried out using statistical and graphical methods including MA plots and smoothed histogram plots. The MA-plots showed normalisation was effective; while smoothed histograms indicated there was no systematic bias in the data.

Project description:During infection, virus-specific CD8+ T cells undergo rapid bursts of proliferation and differentiate into effector cells that kill virus infected cells and reduce viral load. This rapid clonal expansion can put T cells at significant risk for replication-induced DNA damage. We found that c-Myc utilizes the E3 ubiquitin ligase, Cul4b, to inextricably link CD8+ T cell expansion to DNA damage response pathways. Following activation, c-Myc increased levels of Cul4b and other members of the CRL4 complex. Despite having abundant c-Myc expression, Cul4b-deficient CD8+ T cells were unable to expand and clear virus. Cul4b-deficient CD8+ T cells accrued DNA damage and succumbed to proliferative catastrophe early after antigen encounter. Mechanistically, Cul4b ablation induced a protracted accumulation of p21 and Cyclin E2 resulting in replication stress. Our data show that, to support cell proliferation, c-Myc must employ Cul4b to maintain genome stability, thereby directly coupling these two interdependent pathways. These data clarify how CD8+ T cells use c-Myc and Cul4b to sustain their potential for extraordinary population expansion, longevity and antiviral responses.

Project description:Coxsackievirus A10 (CV-A10) constitutes one of the major pathogens of hand, foot, and mouth disease (HFMD), which can cause mild to severe illness and even death. Most of these severe and death cases were closely associated with their neurological impairments, but the underlying mechanism of neuropathological injury induced by CV-A10 infection has not been elucidated. MicroRNAs (miRNAs), implicated in the regulation of gene expression in a posttranscriptional manner, play a vital role in the pathogenesis of various central nervous systems (CNS) diseases; thereby they are served as diagnostic biomarkers and are emerging as novel therapeutic targets for CNS injuries. To gain insights in the CV-A10-induced regulation of host miRNA-processing machinery, we employed high-throughput sequencing to identify differentially expressed miRNAs in CV-A10-infected HUVEC cells and further analyzed the potential functions of these miRNAs during CV-A10 infection. The results showed that CV-A10 infection could elicit 189 and 302 significantly differentially expressed miRNAs in HUVEC cells at 24 hpi and 72 hpi, respectively, as compared with the uninfected control.

Project description:CD8+ T cells are essential effectors in anti-viral immunity, recognising short virus-derived peptides presented by MHC class I (pMHCI) on the surface of infected cells. However, the fraction of viral pMHCI on infected cells that are immunogenic has not been shown for any virus. To approach this fundamental question, we used peptide sequencing by high-resolution mass spectrometry to identify nearly 200 vaccinia virus pMHCI presented on infected mouse cells. Next, we screened each peptide for immunogenicity in multiple virus-infected mice, revealing a wide range of immunogenicities. A surprisingly high fraction (>80%) of pMHCI were immunogenic at least one infected animal and around half of these were dominant, which we define as being immunogenic across more than half of the mice screened. The high number of peptides found to be immunogenic and the variability in immunogenicity across mice give us new insight into the specificity of anti-viral CD8+ T cell responses.