Comparison of the responses of different recombinant fish type I interferons against betanodavirus infection in grouper.

The nervous necrosis virus (NNV) is an aquatic virus that can infect more than 30 species including the grouper, which is a valuable fish species in Taiwan. NNV causes up to 90-100% mortality in the aquaculture industry. Interferons (IFNs) are a family of cytokines that stimulate the expression of numerous proteins to protect the host against viruses and possess very unique specific characteristics in fish. The cross-reactivity of heterologous IFNs on grouper cells and larvae has not been well-studied to date. To evaluate and compare the anti-NNV effect of different fish IFNs in grouper, we successfully synthesized, subcloned, expressed and purified several fish type I IFNs in the present study: grouper (gIFN), salmon (sIFN), seabass (sbIFN) and tilapia (tpIFN). The gIFN and sIFN proteins up-regulated myxovirus resistance protein (Mx) gene expression in grouper kidney (GK) cells, but similar effects were not observed for sbIFN and tpIFN. Following co- and pre-treatment with the 4 types of IFNs with NNV infection in GK cells, sIFN exhibited the strongest antiviral ability to suppress NNV gene replication (especially at 24 h) and significantly reduced the cytopathic effect (CPE) at 72 h, followed by gIFN. Unsurprisingly, sbIFN and tpIFN had no significant effect on CPE but slightly suppressed NNV gene replication. The cytotoxicity of these four fish IFNs on GK cells was also examined for the first time. In the in vivo test, we confirmed that gIFN and sIFN had a significant protective effect against NNV when administered by intraperitoneal (IP) injection and the oral route in Malabar grouper (Epinephelus malabaricus) larvae. This study compared the protective effects of IFNs from various fish species against NNV and demonstrated crosstalk between sIFN and grouper cells for the first time. These results provide information concerning the efficacy of fish IFNs for possible therapeutic applications.

Modulatory effect of CpG oligodeoxynucleotide on a DNA vaccine against nervous necrosis virus in orange-spotted grouper (Epinephelus coioides).

We report the development of a DNA vaccine pcMGNNV2 against nervous necrosis virus (NNV), a leading cause of mass mortality in grouper larvae. In addition, the modulatory effect of CpG oligodeoxynucleotide (ODN), a Toll-like receptor 9 agonist, on the DNA vaccine was evaluated. The DNA vaccine alone elicited the production of NNV-specific antibodies, indicating that the vaccine was capable of triggering adaptive humoral response. Furthermore, significant induction of TLR9, Mx and IL-1ß was observed in the spleen on day 7 post-vaccination, supporting that the vaccine could trigger TLR9 signaling. The incorporation of CpG ODN at high dose did not significantly affect the level of NNV-specific antibodies, but was able to moderately enhance the expression of Mx and IL-1ß on day 7, indicating its ability in modulating innate response. After challenge with NNV, the vaccine alone enhanced the survival rate in infected larvae at both 1 and 2 weeks post-vaccination. The combination of CpG ODN further increased the survival rate at week 1 but not week 2. Interestingly, at week 2 the ODN appeared to induce a Th1-like response, as indicated by upregulation of T-bet (a Th1 marker) and downregulation of GATA-3 (a Th2 marker). Thus, the results suggest that the boosted Th1 response by CpG ODN does not augment the protection efficacy of pcMGNNV2 vaccine. To our best knowledge, this is the first report of a successful DNA vaccine against NNV in grouper.

Transcriptome characterization and gene expression of Epinephelus spp in endoplasmic reticulum stress-related pathway during betanodavirus infection in vitro.

BACKGROUND: Grouper (Epinephelus spp) is an economically important fish species worldwide. However, viral pathogens such as nervous necrosis virus (NNV) have been causing severe infections in the fish, resulting in great loss in the grouper aquaculture industry. Yet, the understanding of the molecular mechanisms underlying the pathogenicity of NNV is still inadequate, mainly due to insufficient genomic information of the host. RESULTS: De novo assembly of grouper transcriptome in the grouper kidney (GK) cells was conducted by using short read sequencing technology of Solexa/Illumina. A sum of 66,582 unigenes with mean length of 603 bp were obtained, and were annotated according to Gene Ontology (GO) and Clusters of Orthologous Groups (COG). In addition, the tag-based digital gene expression (DGE) system was used to investigate the gene expression and pathways associated with NNV infection in GK cells. The analysis revealed endoplasmic reticulum (ER) stress response was prominently affected in NNV-infected GK cells. A further analysis revealed an interaction between the NNV capsid protein and the ER chaperone immunoglobulin heavy-chain binding protein (BiP). Furthermore, exogenous expression of NNV capsid protein was able to induce XBP-1 mRNA splicing in vivo, suggesting a role of the capsid protein in the NNV-induced ER stress. CONCLUSIONS: Our data presents valuable genetic information for Epinephelus spp., which will benefit future study in this non-model but economically important species. The DGE profile of ER stress response in NNV-infected cells provides information of many important components associated with the protein processing in ER. Specifically, we showed that the viral capsid protein might play an important role in the ER stress response.

Differential viral propagation and induction of apoptosis by grouper iridovirus (GIV) in cell lines from three non-host species.

Grouper iridovirus (GIV), belonging to the Ranavirus genus of the Iridoviridae family, was demonstrated to differentially express viral genes and induce apoptosis in three non-host fish cell lines rainbow trout monocyte/macrophage (RTS11), chinook salmon embryonic (CHSE-214) and fathead minnow Epithelioma papulosum cyprinid (EPC). These cells were challenged with GIV and virus entry into all three cell lines was confirmed by the expression of viral immediate early genes. The expression of the late major capsid protein gene was detected in CHSE-214 and EPC, but not in RTS11, suggesting an earlier termination in the viral replication cycle in RTS11. Approximately 12h after infection with GIV, cell death was prominent in all three non-host cell lines. Death was later confirmed to be apoptosis by the presence of chromosomal DNA fragmentation and phosphatidylserine externalization. To determine whether apoptosis was protein related or gene expression related, the three cell lines were challenged with heat-inactivated GIV and UV-treated GIV (GIV(UV)). The heat inactivation abolished apoptosis in all three cell lines, but each cell line responded differently to GIV(UV). Relative to GIV, GIV(UV) caused no apoptosis in CHSE-214, decreased apoptosis in RTS11, and increased apoptosis in EPC. These results suggest that early GIV gene expression was needed for apoptosis in CHSE-214 but impeded apoptosis in EPC. At the cellular level, only EPC is a permissive host as EPC was the only cell line of the three capable of producing a moderate increase in virus titer. The three non-host cell lines present a good system for potentially identifying different components of GIV-induced apoptotic pathways in future studies.