In-depth health surveillance and clinical nutrition in farmed Atlantic salmon: a strategic attempt to detect and mitigate an HSMI outbreak.

Fish health personnel have limited tools in combatting viral diseases such as heart and skeletal muscle inflammation (HSMI) in open net-pen farmed Atlantic salmon. In this study, we aimed to predict HSMI by intensified health monitoring and apply clinical nutrition to mitigate the condition. We followed a commercial cohort (G1) of Atlantic salmon that was PRV-1 naïve when transferred to a sea cage at a location where HSMI outbreaks commonly occur. The fish in the other cages (G2-G6) at the location had a different origin than G1 and were PRV-1 positive prior to sea transfer. By continuous analysis of production data and sequentially (approximately every fourth week) performing autopsy, RT-qPCR (for PRV-1 and selected immune genes), blood and histological analysis of 10 fish from G1 and G2, we identified the time of PRV-1 infection in G1 and predicted the onset of HSMI prior to any clinical signs of disease. Identical sequences across partial genomes of PRV-1 isolates from G1 and G2 suggest the likely transfer from infected cages to G1. The isolates were grouped into a genogroup known to be of high virulence. A commercial health diet was applied during the HSMI outbreak, and the fish had low mortality and an unaffected appetite. In conclusion, we show that fish health and welfare can benefit from in-depth health monitoring. We also discuss the potential health value of clinical nutrition as a mean to mitigate HSMI.

Isolation and characterisation of two cDNAs encoding transglutaminase from Atlantic cod (Gadus morhua).

Two cDNAs encoding transglutaminase (TG) were identified in a subtractive cDNA library prepared from the head kidney of poly I:C stimulated Atlantic cod (Gadus morhua). Full-length TG-1 and TG-2 cDNA were cloned from the head kidney by a reverse-transcription polymerase chain reaction (RT-PCR) and rapid amplification of cDNA ends (RACE). The deduced amino acid (aa) sequence for TG-1 was 695 aa with an estimated molecular mass of 78.3 kDa, while TG-2 was a 698 aa protein with an estimated molecular mass of 78.8 kDa. The two proteins were named TG-1 and TG-2 and both possess transglutaminase/protease-like homologous domains (TGc) and full conservation of amino acids cysteine, histidine, and aspartate residues that form the catalytic triad. Sequence analysis showed high similarity (93.1%) with Alaska pollock TG, and the TGs were grouped together with TGs from chum salmon, Japanese flounder, Nile tilapia, and red sea bream in addition to Alaska pollock in phylogenetic analysis. Interestingly, they showed different tissue distribution with highest constitutive expression in reproductive and immunological organs, indicating important roles in these organs. Furthermore, the up-regulation of TG-1 and TG-2 in head kidney after stimulating Atlantic cod with poly I:C suggested a role of TGs in immune response in Atlantic cod.

Genomic analysis of the host response to nervous necrosis virus in Atlantic cod (Gadus morhua) brain.

Genome sequencing combined with transcriptome profiling promotes exploration of defence against pathogens and discovery of immune genes. Based on sequences from the recently released genome of Atlantic cod, a genome-wide oligonucleotide microarray (ACIQ-1) was designed and used for analyses of gene expression in the brain during infection with nervous necrosis virus (NNV). A challenge experiment with NNV was performed with Atlantic cod juveniles and brain samples from virus infected and uninfected fish were used for microarray analysis. Expression of virus induced genes increased at 5 days post challenge and persisted at stable level to the last sampling at 25 days post challenge. A large fraction of the up-regulated genes (546 features) were known or expected to have immune functions and most of these have not previously been characterized in Atlantic cod. Transcriptomic changes induced by the virus involved strong activation of genes associated with interferon and tumour necrosis factor related responses and acute inflammation. Up-regulation of genes involved in adaptive immunity suggested a rapid recruitment of B and T lymphocytes to the NNV infected brain. QPCR analyses of 15 candidate genes of innate immunity showed rapid induction by poly(I:C) in Atlantic cod larvae cells suggesting an antiviral role. Earliest and greatest expression changes after poly I:C stimulation was observed for interferon regulatory factors IRF4 and IRF7. Comparative studies between teleost species provided new knowledge about the evolution of innate antiviral immunity in fish. A number of genes is present or responds to viruses only in fish. Innate immunity of Atlantic cod is characterized by selective expansion of several medium-sized multigene families with ribose binding domains. An interesting finding was the high representation of three large gene families among the early antiviral genes, including tripartite motif proteins (TRIM) and proteins with PRY-SPRY and NACHT domains. The latter two with respectively 52 and 114 members in Atlantic cod have gone through expansions in different groups of fish. These proteins most likely have ligand binding properties and their propagation could be linked to the loss of MHC class II in the Atlantic cod genome.

Atlantic salmon type I IFN subtypes show differences in antiviral activity and cell-dependent expression: evidence for high IFNb/IFNc-producing cells in fish lymphoid tissues.

This work reveals distinct roles of the two-cysteine-containing type I IFNs, IFNa and IFNd, and the four-cysteine-containing IFNb and IFNc in antiviral immunity of Atlantic salmon. IFNa and IFNc showed similar antiviral activities and ability to induce antiviral genes, IFNb was less active, and IFNd showed no activity. Expression of IFNs was compared by treatment of cells or fish with the dsRNA polyinosinic-polycytidylic acid [poly(I:C)], which induces IFNs via the viral RNA receptors MDA5 and TLR3/TLR22 and with the imidazoquinoline R848, which induces IFNs via TLR7. Poly(I:C) strongly induced IFNa in cell lines, whereas the other IFNs showed little response, indicating that IFNa is the main IFN subtype induced through the RIG-I/MDA5 pathway. In contrast, IFNb and IFNc are the main IFNs induced through the TLR7 pathway because R848 induced high transcript levels of IFNb and IFNc and low transcript levels of IFNa in the head kidney and spleen. IFNd was constitutively expressed in cells and organs but showed no response to poly(I:C) or R848. Fluorescence in situ hybridization studies showed that poly(I:C) induced IFNa and IFNc in a variety of cells in the head kidney, spleen, gills, liver, and heart, whereas R848 induced coexpression of IFNb and IFNc in distinct cells in head kidney and spleen. These cells are likely to be specialized high IFN producers because they were few in numbers despite high IFNb/IFNc transcript levels in the same organs. High IFN expression in response to TLR7 ligation is a feature shared by mammalian plasmacytoid dendritic cells.

Regulation and function of interferon regulatory factors of Atlantic salmon.

Transcription factors of the interferon regulatory factor (IRF) family are major regulators of the early immune responses against viral infections. In particular, IRF1, IRF2, IRF3 and IRF7 of mammals are known to regulate the expression of type I interferons (IFNs), which constitute the obligate cytokines for antiviral defense. We therefore cloned the coding sequence of Atlantic salmon (As) IRF1, IRF2, IRF3 and IRF7B. Expression profiles were studied in Atlantic salmon TO cells after poly I:C (dsRNA) transfection, treatment with recombinant salmon IFNa1 and infection with infectious salmon anemia virus (ISAV). The main findings were that AsIRF1 was earliest up-regulated by all stimuli, while AsIRF3 and AsIRF7 had a similar activation profile induced at a slightly later time point. The ability to induce the Atlantic salmon IFNa1 promoter was measured in a luciferase reporter assay. The results showed that AsIRF1, AsIRF3 and AsIRF7B were able to induce the promoter in a dose-dependent manner. AsIRF2 repressed the promoter, while AsIRF7A and a splicing variant (AsIRF3D) lacking the interaction domain had almost no effect. Combination of AsIRF1 and AsIRF3 had a synergistic stimulatory effect on the promoter compared to each of the two IRFs alone. Overall, our findings suggest that AsIRF3 is the main regulator of salmon IFNa1 production along with AsIRF1, which is less potent. This confirms a similar role for salmon IRF3 as mammalian IRF3 to be one of the main IRFs eliciting salmon IFNa1 production. Surprisingly, AsIRF7A and AsIRF7B seemed to have a lesser role in salmon IFNa1 induction, which may indicate that these factors have a larger role in activating other IFN genes or interferon stimulatory genes of Atlantic salmon.

Atlantic cod (Gadus morhua L.) possesses three homologues of ISG15 with different expression kinetics and conjugation properties.

Two new interferon stimulated gene 15 (ISG15) family members were identified in a subtractive cDNA library constructed from a mixture of head kidney and spleen of Atlantic cod (Gadus morhua) stimulated with polyinosinic:polycytidylic acid (poly I:C). Two full-length Atlantic cod (Ac) ISG15-2 and AcISG15-3 cDNAs were cloned with rapid amplification of cDNA ends (RACE). The cDNA sequence of AcISG15-2 encodes a 16.9kDa protein and AcISG15-3 encodes a 18.4kDa protein, both of which possess the characteristic structural features of two tandem ubiquitin-like domains and the LRGG motif necessary for conjugation. Furthermore, the AcISG15-3 protein is expressed with a C-terminal extension in common with the human ISG15 protein. Gene expression analysis using quantitative reverse transcriptase PCR (RT-qPCR) showed that AcISG15-1, AcISG15-2, and AcISG15-3 transcripts were up-regulated in head kidney after poly I:C stimulation, suggesting that these proteins may be involved in the cod immune response. However, transient expression of myc-tagged AcISG15 proteins revealed differences in their abilities to form conjugates in vitro. We show that AcISG15-2 forms covalent conjugates to a range of cellular protein as a response to poly I:C, recombinant Atlantic salmon IFNa1 (rSasaIFNa1) and infectious pancreatic necrosis virus (IPNV), whereas conjugation was absent for AcISG15-1 and AcISG15-3. Thus, these results suggest there are three ISG15 homologues in Atlantic cod and that the three proteins may play different roles in innate immunity.

Structural and functional studies of an IRF-7-like gene from Atlantic salmon.

Interferon regulatory factor 7 (IRF-7) plays a crucial role in virus-induced activation of interferon-alpha/beta transcription in mammals. This work describes a structural and functional homologue of mammalian IRF-7 from Atlantic salmon. The cloned gene encodes a putative protein of 415 amino acids (aa), which groups with mammalian IRF-7 and other fish IRF-7-like proteins in a phylogenetic analysis of vertebrate IRFs. Using an IFN promoter-luciferase assay we showed that salmon IRF-7 gave increased promoter activity after poly I:C stimulation. Transcript levels of IRF-7 were measured by real-time RT-PCR and compared to those of signal transducer and activator of transcription 1 (STAT1), which is important for transcriptional activation of IFN stimulated genes. Recombinant salmon IFN-alpha1 and poly I:C proved to be potent inducers of IRF-7 in Atlantic salmon TO cells, and poly I:C also induced the gene in head kidney and liver of Atlantic salmon. STAT1 was also induced by IFN, but was only weakly induced by poly I:C stimulation in vitro. Differences in transcription kinetics between IRF-7 and STAT1 thus indicate that the genes are regulated through different pathways. Finally, infection of TO cells with infectious salmon anemia virus (ISAV) induced early synthesis of STAT1 mRNA, whereas IRF-7 transcripts were upregulated much later. This indicates that ISAV has mechanisms to antagonize IRF-7 transcription and thus also the IFN system in Atlantic salmon.

Induction of interferon system genes in Atlantic salmon by the imidazoquinoline S-27609, a ligand for Toll-like receptor 7.

Imidazoquinolines represented by imiquimod and its derivative S-27609, have previously been shown to have potent antiviral and antitumor activity in several mammalian models. Much of the antiviral properties of imidazoquinolines have been ascribed to induction of IFN-alpha in peripheral blood mononuclear cells most notably plasmacytoid dendritic cells. Toll-like receptor (TLR) 7 has been identified as the receptor for imiquimod and S-27609 in mammals. In this work we show that S-27609 induces expression of IFN-alpha1/alpha2, Mx, ISG15 and IFN-gamma in organs of Atlantic salmon, which suggests that salmon responds to S-27609 through a TLR7-like receptor. The kinetics of gene expression in liver and head kidney induced by S-27609 was compared with that induced by the double-stranded RNA poly I:C, which is a ligand for TLR3 and the RNA helicase MDA5. In liver, S-27609 and poly I:C both induced transcripts for IFN-alpha1/alpha2, Mx and ISG15 with a peak at about 24h. In head kidney, poly I:C induced IFN-alpha1/alpha2 and Mx with one peak at about 24h. In contrast, S-27609 induced a biphasic increase of IFN-alpha1/alpha2 and Mx transcripts in head kidney with a minor peak at 14-24h and another increase starting at 72h. The other major difference in gene induction by the two stimulants was that S-27609 induced much lower levels of IFN-alpha1/alpha2 than poly I:C during the early time stages (14-48h) both in liver and head kidney. The difference in induction of IFN-alpha1/alpha2 by S-27609 and poly I:C may be a consequence of different cell targets for the two stimulants where S-27609 primarily induces IFNs through immune cells whereas poly I:C induces IFNs in most nucleated cells.

Molecular and functional characterization of two infectious salmon anaemia virus (ISAV) proteins with type I interferon antagonizing activity.

In this study we characterize two proteins encoded by the two smallest genomic segments of the piscine orthomyxovirus infectious salmon anaemia virus (ISAV). Both proteins, encoded by the un-spliced ORF from genomic segment 7 (s7ORF1) and the larger ORF from segment 8 (s8ORF2), are involved in modulation of the type I interferon (IFN) response. The data suggests that the s7ORF1 protein is collinearly encoded, non-structural, contains no nuclear localisation signals, localises mainly to the cytoplasmic perinuclear area and does not bind single- or double-stranded RNA. On the other hand, genomic segment 8 uses a bicistronic coding strategy and the encoded s8ORF2 protein is a structural component of the viral particle. This protein contains two nuclear localisation signals, has a predominantly nuclear localisation, binds both double-stranded RNA and poly-A tailed single-stranded RNA, but not double-stranded DNA. In poly I:C stimulated salmon cells both ISAV proteins independently down-regulate the type I IFN promoter activity. Thus, ISAV counteracts the type I IFN response by the action of at least two of its gene products, rather than just one, as appears to be the case for other known members of the Orthomyxoviridae.

The Atlantic salmon Z-DNA binding protein kinase phosphorylates translation initiation factor 2 alpha and constitutes a unique orthologue to the mammalian dsRNA-activated protein kinase R.

The translation initiation factor 2 alpha (eIF2alpha)-kinase, dsRNA-activated protein kinase (PKR), constitutes one of the major antiviral proteins activated by viral infection of vertebrates. PKR is activated by viral double-stranded RNA and subsequently phosphorylates the alpha-subunit of translation initiation factor eIF2. This results in overall down regulation of protein synthesis in the cell and inhibition of viral replication. Fish appear to have a PKR-like protein that has Z-DNA binding domains instead of dsRNA binding domains in the regulatory domain, and has thus been termed Z-DNA binding protein kinase (PKZ). We present the cloning of the Atlantic salmon PKZ cDNA and show its upregulation by interferon in Atlantic salmon TO cells and poly inosinic poly cytodylic acid in head kidney. We also demonstrate that recombinant Atlantic salmon PKZ, expressed in Escherichia coli, phosphorylates eIF2alphain vitro. This is the first demonstration that PKZ is able to phosphorylate eIF2alpha. PKZ activity, as measured by phosphorylation of eIF2alpha, was increased after addition of Z-DNA, but not by dsRNA. In addition, we show that wild-type Atlantic salmon PKZ, but not the kinase defective variant K217R, has a direct inhibitory effect on protein synthesis after transient expression in Chinook salmon embryo cells. Overall, the results support a role for PKZ, like PKR, in host defense against virus infection.

Infectious salmon anemia virus is a powerful inducer of key genes of the type I interferon system of Atlantic salmon, but is not inhibited by interferon.

Infectious salmon anemia virus (ISAV) is an aquatic orthomyxovirus causing disease and high mortality in farmed Atlantic salmon (Salmo salar). The virus is thus apparently able to initiate replication without being hampered by the host's immune system. In this work we have studied the role of the type I interferon (IFN) system of Atlantic salmon in protection against ISAV. Real-time RT-PCR was used to study the expression of type I IFN and the IFN stimulated genes Mx and ISG15 in TO cells and live fish in response to infection with ISAV. The in vitro studies showed that ISAV was a powerful inducer of Mx and ISG15 genes in TO cells and that induction started relatively early during infection. In contrast, IFN transcripts were induced later than both Mx and ISG15 transcripts in the ISAV infected cells indicating that Mx and ISG15 are induced through IFN-independent pathways in the early stages of ISAV infection. A cohabitee infection trial with ISAV in Atlantic salmon resulted in high mortality, even though elevated levels of IFN, Mx and ISG15 transcripts in the head kidney and liver were observed. Immunoblotting confirmed the presence of Mx and ISG15 proteins in the liver of infected salmon. In order to evaluate whether the type I IFN system is able to inhibit replication of ISAV, TO cells were stimulated with recombinant salmon IFN-alpha1 (rSasaIFN-alpha1) and subsequently infected with virus. The rSasaIFN-alpha1 showed no protection of TO cells against ISAV, but full protection against IPNV. These data demonstrate that key proteins of the type I IFN system are induced during an ISAV infection, but that they are unable to inhibit the replication of ISAV in vitro and in vivo. ISAV must thus encode genes that enable the virus to counteract IFN induced antiviral proteins of the host.

Promoters of type I interferon genes from Atlantic salmon contain two main regulatory regions.

Recognition of viral nucleic acids by vertebrate host cells results in the synthesis and secretion of type I interferons (IFN-alpha/beta), which induce an antiviral state in neighboring cells. We have cloned the genes and promoters of two type I IFNs from Atlantic salmon. Both genes have the potential to encode IFN transcripts with either a short or a long 5'-untranslated region, apparently controlled by two distinct promoter regions, PR-I and PR-II, respectively. PR-I is located within 116 nucleotides upstream of the short transcript and contains a TATA-box, two interferon regulatory factor (IRF)-binding motifs, and a putative nuclear factor kappa B (NFkappaB)-binding motif. PR-II is located 469-677 nucleotides upstream of the short transcript and contains three or four IRF-binding motifs and a putative ATF-2/c-Jun element. Complete and truncated versions of the promoters were cloned in front of a luciferase reporter gene and analyzed for promoter activity in salmonid cells. Constructs containing PR-I were highly induced after treatment with the dsRNA poly(I:C), and promoter activity appeared to be dependent on NFkappaB. In contrast, constructs containing exclusively PR-II showed poor poly(I:C)-inducible activity. PR-I is thus the main control region for IFN-alpha/beta synthesis in salmon. Two pathogenic RNA viruses, infectious pancreatic necrosis virus and infectious salmon anemia virus, were tested for their ability to stimulate the minimal PR-I, but only the latter was able to induce promoter activity. The established IFN promoter-luciferase assay will be useful in studies of host-virus interactions in Atlantic salmon, as many viruses are known to encode proteins that prevent IFN synthesis by inhibition of promoter activation.