Transcriptomic analysis of responses to infectious salmon anemia virus infection in macrophage-like cells.

The aquatic orthomyxovirus infectious salmon anemia virus (ISAV) is an important pathogen for salmonid aquaculture, however little is known about protective and pathological host responses to infection. We have investigated intracellular responses during cytopathic ISAV infection in the macrophage-like Atlantic salmon kidney (ASK) cell line by microarray analysis (1.8k SFA2.0 immunochip) and a functional assay for glutathione. Gene transcription changed rapidly and consistently with time and with minor differences between two virus isolates. While several pro-inflammatory and antiviral immune genes were induced, genes involved in cell signaling and integrity were down-regulated, suggesting isolation of infected cells from cell-to-cell interaction and responses to external signals. Differential expression of genes regulating cell cycle and apoptosis implied opposite cues from host cell and virus. This was in pace with massive down-regulation of genes involved in biosynthesis and processing of nucleotides and nucleic acids. Significant down-regulation of several genes involved in metabolism of reactive oxygen species suggested increased oxidative stress, which was confirmed by a functional assay showing reduced levels of glutathione during infection. Testing of expression data against a microarray database containing diverse experiments revealed candidate marker genes for ISAV infection. Our findings provide novel insight into cellular host responses and determinants for acute cytopathic ISAV infection.

Genomic survey of early responses to viruses in Atlantic salmon, Salmo salar L.

Viral diseases are one of the main problems and risk factors in aquaculture. At present diseases are diagnosed by detection of pathogens and clinical symptoms. Identification of genes involved in early responses to viruses is important for better knowledge of antiviral defence and development of diagnostic tools. The aim of this study was to search for gene markers common for viral infections in Atlantic salmon based on microarray analyses of a wide range of samples. Gene expression profiles from fish and cell cultures infected with different viruses and treated with the synthetic double-stranded RNA poly(I:C) were compared in order to identify virus responsive genes (VRG). The list of VRG defined in this study contained 117 genes with known or unidentified functions. Several genes, including the most highly ranked one (receptor transporting protein), had not been previously reported to be involved in antiviral defence. VRG were characterized by a rapid induction and low tissue specificity, and their expression levels were related to the viral load. Immunofluorescence analyses of proteins encoded by VRG in cardiac tissue of salmon with the viral disease cardiomyopathy syndrome (CMS) revealed a common expression pattern. In head kidney leukocytes VRG showed comparable or equal responses to CpG and poly(I:C), which mimic respectively bacterial DNA and viral RNA. Most VRG showed highly correlated expression with interferon-a (IFNa). Sequence comparison of salmon VRG with those from other species gave an understanding of the evolution of these genes, which showed a remarkably rapid sequence divergence in comparison with the entire proteome. VRG emerged both before and after separation of teleosts and tetrapods, and among genes found exclusively in fish species there were members of several multigene families: tripartite motif proteins, gig1- and gig2-like proteins. Several VRG, including genes with unknown functions and orthologs to mammalian RNA helicase RIG-I and chemokine C-X-C type 10, were present in cyprinid and salmonid fish but not in the phylogenetically advanced orders, suggesting that they have been lost in the evolution of Teleostei. Apparently, a number of genes involved in antiviral responses in salmon have acquired different functional roles in higher vertebrates.

Formation of autophagosomes and redistribution of LC3 upon in vitro infection with infectious salmon anemia virus.

Autophagy plays an important role in both cellular homeostasis and cellular stress responses, and is also implicated in viral immunity. Here we show that infectious salmon anemia virus (ISAV) induce autophagy (double membrane autophagosomes observed by EM), in cells from Atlantic salmon. In addition, cells transfected with the standard autophagy marker, microtubule-associated protein light chain kinase 3 (LC3) fused to green fluorescent protein (LC3-GFP), displayed the redistribution of fluorescence into the typical punctate pattern seen in cells undergoing autophagy (a marker for autophagosome formation). This redistribution is caused by transformation of the LC3 protein into a membrane bound form due to lipidation of the C-terminal glycine. RT-QPCR analysis of key autophagy protein transcripts (ATG 3, 5, 6, 7, 8, 10, 12) mRNA revealed no major changes in expression of autophagy genes in the first phase of ISAV infection. Treatment of cells with an inhibitor of autophagosome formation, 3-methyladenine, both reduced LC3-GFP puncta formation and viral production, suggesting a role for autophagosomes in ISAV replication. This is the first report of virus-induced autophagy in cells from a fish species.