In vitro infection efficiency of nervous necrosis virus alters depending on amount of viral particles adsorbed onto cells.

Nervous necrosis virus (NNV) in the family Nodaviridae is one of the simplest spherical RNA viruses and is pathogenic to many fish species. We investigated the effect of purified NNV on striped snakehead cells (SSN-1) in terms of adsorption ratio and infection efficiency using the 96-well titration system. The proportion of cytopathic effect (CPE)-positive wells among total number of wells inoculated with the virus (CPE appearance ratio) reduced by 17% each time the NNV infectivity dose was halved (y = 55.7x + 50.6). Thus, subtle differences in NNV infectivity could be accurately detected using this system. Experiments performed to observe alteration of CPE appearance ratio with changing viral doses and adsorption times showed that NNV particles introduced into microplate wells as suspensions in ≤ 100 µl inoculum were adsorbed almost completely onto cells seeded on the wells within 4 days of incubation. Density profile analysis of NNV coat proteins revealed that the NNV suspension at 1 50% tissue culture infectious dose (TCID50) contained 60 particles. Infection efficiency/NNV peaked at 20 particles (1.20%/particle) and then declined gradually with increasing NNV doses. Therefore, in vitro infection efficiency of NNV may alter depending on the quantity of viral particles adsorbed onto cells.

Sites responsible for infectivity and antigenicity on nervous necrosis virus (NNV) appear to be distinct.

Nervous necrosis virus (NNV) is a pathogenic fish-virus belonging to the genus Betanodavirus (Nodaviridae). Surface protrusions on NNV particles play a crucial role in both antigenicity and infectivity. We exposed purified NNV particles to different physicochemical conditions to investigate the effects on antigenicity and infectivity, in order to reveal information regarding the conformational stability and spatial relationships of NNV neutralizing-antibody binding sites and cell receptor binding sites. Treatment with PBS at 37 °C, drastically reduced NNV antigenicity by 66-79% on day one, whereas its infectivity declined gradually from 107.6 to 105.8 TCID50/ml over 10 days. When NNV was treated with carbonate/bicarbonate buffers at different pHs, both antigenicity and infectivity of NNV declined due to higher pH. However, the rate of decline with respect to antigenicity was more moderate than for infectivity. NNV antigenicity declined 75-84% after treatment with 2.0 M urea, however, there was no reduction observed in infectivity. The antibodies used in antigenicity experiments have high NNV-neutralizing titers and recognize conformational epitopes on surface protrusions. The maintenance of NNV infectivity means that receptor binding sites are functionally preserved. Therefore, it seems highly likely that NNV neutralizing-antibody binding sites and receptor binding sites are independently located on surface protrusions.

Reproducibility of antigen-immobilized enzyme-linked immunosorbent assay (ELISA) and sandwich ELISA for quantitative detection of NNV particles.

Nervous necrosis virus (NNV) is a fish virus belonging to family Nodaviridae. In this study, we prepared partially aggregated and monometric NNV particles to determine reproducibility of two different enzyme-linked immunosorbent assays (ELISAs): antigen-immobilized ELISA and sandwich ELISA. Passing ratios of purified NNV particles through ultrafilters with molecular weight cut off (MWCO) of 105, 3 × 105 and 106 were 0%, 35.2% and 80.3%, respectively, suggesting that purified NNV particles were partially aggregated whereas those in filtrates with MWCO of 3 × 105 could be monometric. Both NNV particles were subjected to ELISAs. Reduction ratios of ELISA values by 2-fold dilution of antigens were 50% in sandwich ELISA regardless of aggregation state of NNV particles. In contrast, those in antigen-immobilized ELISA were 42% (partially aggregated NNV) to 43% (monometric NNV), which were lower than the theoretical value (50%). This could be due to changes in aggregation state of NNV particles during dry-immobilization. Sandwich ELISA has excellent reproducibility from five times of experiments, in comparison with antigen-immobilized ELISA. Furthermore, available range of regression lines (R2 > 0.99) in sandwich ELISA was wider than that in antigen-immobilized ELISA. These results revealed that sandwich ELISA had better quantitativeness, reproducibility and available range of ELISA values than antigen-immobilized ELISA.

Altered conformational structures of nervous necrosis virus surface protrusions and free coat proteins after incubation at moderate-low temperatures.

Nervous necrosis virus (NNV) is a pathogenic fish virus belonging to family Nodaviridae. The objective of this study was to analyze stabilities of NNV surface protrusion and free coat protein (CP) conformational structures by analyzing changes of NNV infectivity and antigenicity after incubation at moderate-low temperatures. When cultured NNV suspension was incubated at 45 °C, its infectivity declined gradually but its antigenicity maintained. In contrast, both infectivity and antigenicity of purified NNV declined after incubation at 45 °C. After heat-treatment, surface protrusions of NNV particles disappeared completely, although viral particle structures maintained. Therefore, the reduction in NNV infectivity appeared to specifically occur as a result of heat-denaturation of virus surface protrusions. The loss of NNV infectivity in the presence of fetal bovine serum (FBS) was delayed compared to virus heated in the absence of FBS, demonstrating that FBS could function as a stabilizer for conformational structures of NNV surface protrusions. Moreover, the stabilizing function of FBS changed depending on salt concentration. Continued maintenance of antigenicity for heated cultured NNV suspension containing free-CPs may suggest that conformational structures corresponding to protrusion-domain of free-CP are more heat-stable than those of surface protrusions on NNV particles.

Lack of nervous necrosis virus (NNV) neutralizing antibodies in convalescent sevenband grouper Hyporthodus septemfasciatus after NNV infection.

Viral nervous necrosis (VNN) is caused by nervous necrosis viruses (NNVs) belonging to genus Betanodavirus (Nodaviridae). It is one of the most serious diseases in aquaculture industry worldwide. In the present study, the kinetics of NNV-infectivity and NNV-specific antibodies in convalescent sevenband grouper Hyporthodus septemfasciatus after NNV infection was determined. When fish were infected with NNV at 17.5 °C, and reared for 84 days at natural seawater temperature (increasing rate: approximately 0.1 °C/day), NNV infectivity peaked on day 14 with 107.80 TCID50/g at the highest, and declined to below the detection limit. When convalescent fish were reared at 27 °C, and re-infected with NNV at 104.3 or 106.3 TCID50/fish, no mortality was observed although NNV multiplied up to 108.80 and 107.80 TCID50/g at the highest, respectively, suggesting NNV-specific immune response. It also revealed that convalescent fish were re-infected by NNV although NNV multiplication was strongly regulated. Interestingly, NNV-specific antibodies were detectable in 20% and ≥80% of convalescent fish before and after re-infection with NNV, respectively. However, no NNV-neutralizing activity was detected before and after re-infection in almost all of the convalescent fish. Therefore, NNV-neutralizing antibodies might not be necessary for the protection of convalescent fish against NNV re-infection after previous NNV infection.

Multiple Passages of Grunt Fin Cells Persistently Infected with Red Seabream Iridovirus (RSIV) at 15ºC or 30ºC to Yield Uninfected Cells.

Red seabream iridovirus (RSIV), a member within genus Megalocytivirus (Iridoviridae), causes serious economic losses to marine fish aquaculture industry in East Asia. In this study, we established a Blue Striped Grunt Haemulon sciurus fin (grunt fin; GF) cell line persistently infected with RSIV (PI-GFRSIV) by subculturing GF cells that survived RSIV inoculation. PI-GFRSIV cells were morphologically indistinguishable from naive GF cells. They could stably produce RSIV at approximately 104.9 ± 0.5 genomes per microliter after 24 passages over 18 months. The optimum temperature to produce RSIV in PI-GFRSIV cells was 25°C. These cells also produced RSIV at 15, 20, and 30°C with multiple subcultures. The amount of RSIV yielded from PI-GFRSIV cells decreased gradually by multiple subculturing at 15°C or 30°C. Red seabream iridovirus was no longer detected from PI-GFRSIV cells after subcultures at these temperatures. These PI-GFRSIV cells freed from RSIV infection exhibited a level of RSIV productivity similar to those of naive GF cells after inoculation with RSIV. Therefore, we consider that these PI-GFRSIV cells were no longer infected with RSIV after multiple subculturing at 15°C or 30°C. Received October 15, 2015; accepted June 27, 2016.

Establishment of rock bream Oplegnathus fasciatus embryo (RoBE-4) cells with cytolytic infection of red seabream iridovirus (RSIV).

Red seabream iridovirus (RSIV) is a member of genus Megalocytivirus in the family Iridoviridae. RSIV infection causes significant economic losses of marine-fishes in East Asian countries. Grunt fin (GF) cell line has been commonly used for culturing RSIV. However, it is not suitable for definite evaluation of infectivity titer of RSIV because cells infected with RSIV are not completely cytolysed. Thus, we established a new cell line, RoBE-4, from rock bream (Oplegnathus fasciatus) eyed-egg embryos in this study. Morphologically, RoBE-4 cells were fibroblastic-like. They have been stably grown over two-years with 60 passages using Leibovitz's L-15 medium containing 10% (v/v) fetal bovine serum. RoBE-4 cells infected with RSIV exhibited cytopathic effects (CPE) with cell rounding. They were cytolysed completely after ≥2 weeks of culture. Numerous RSIV particles with icosahedral morphology of approximately 122nm in diameter were observed in cytoplasmic area of infected RoBE-4 cells. The RSIV-suceptibility and amount of extracellular RSIV released by RoBE-4 cells were 100-fold higher than those by GF cells. RSIV cultured with RoBE-4 cells was highly virulent to rock bream in infection experiments. Therefore, using RoBE-4 cells instead of GF cells will enable accurate and sensitive measurement of RSIV infectivity. In addition, RoBE-4 cells might be used to produce RSIV vaccine in the future with significant reduction in cost.

Purification of nervous necrosis virus (NNV) particles by anion-exchange chromatography.

Nervous necrosis virus (NNV) belongs to genus Betanodavirus (family Nodaviridae). It is highly pathogenic to various marine fishes. In the present study, cultured NNV suspension was placed in dialysis tube at molecular weight cut off (MWCO) of 106 and dialyzed against Dulbecco's phosphate buffered saline (D-PBS), 15mM Tris-HCl (pH 8.0), or deionized water (DIW) for 14days followed by anion-exchange chromatography. Infectivity titers of NNV suspensions were stable during dialyses. However, the antigenicity of NNV suspension was decreased to 2.5% by D-PBS dialysis, 11.8% by Tris-HCl dialysis, and 56.2% by DIW dialysis. Anion-exchange chromatograms revealed a total of four peaks (P300, P400, P600 and P700) for NNV suspension after D-PBS dialysis. Additional two peaks (P800 and P-OH) were detected in the NNV suspension after Tris-HCl or DIW dialysis. The substance from the P700 peak had the highest NNV-infectivity. Peak P700 commonly shared by the NNV suspensions after dialysis against the three different buffers. After Tris-HCl dialysis, no other protein except NNV coat protein (CP) at Mr 41,000 was detected from P700. However, after D-PBS dialysis, the P700 peak also contained P600 antigens. Therefore, the P700 peak after Tris-HCl dialysis represented the peak of highly purified NNV particles.

Dialysis buffer with different ionic strength affects the antigenicity of cultured nervous necrosis virus (NNV) suspensions.

Nervous necrosis virus (NNV) belongs to the genus Betanodavirus (Nodaviridae). It is highly pathogenic to various marine fishes. Here, we investigated the antigenicity changes of cultured NNV suspensions during 14days of dialyses using a dialysis tube at 1.4×10(4) molecular weight cut off (MWCO) in three different buffers (Dulbecco's phosphate buffered saline (D-PBS), 15mM Tris-HCl (pH 8.0), and deionized water (DIW)). Total NNV antigen titers of cultured NNV suspension varied depending on different dialysis buffers. For example, total NNV antigen titer during D-PBS dialysis was increased once but then decreased. During Tris-HCl dialysis, it was relatively stable. During dialysis in DIW, total NNV antigen titer was increased gradually. These antigenicity changes in NNV suspension might be due to changes in the aggregation state of NNV particles and/or coat proteins (CPs). ELISA values of NNV suspension changed due to changing aggregates state of NNV antigens. NNV particles in suspension were aggregated at a certain level. These aggregates were progressive after D-PBS dialysis, but regressive after Tris-HCl dialysis. The purified NNV particles self-aggregated after dialysis in D-PBS or in Tris-HCl containing 600mM NaCl, but not after dialysis in Tris-HCl or DIW. Quantitative analysis is merited to determine NNV antigens in the highly purified NNV particles suspended in buffer at low salt condition.

Cell Culture Medium Inhibits Antigen Binding Used in an ELISA for Detection of Antibodies against Nervous Necrosis Virus.

Abstract We investigated the optimum dilution of nervous necrosis virus (NNV) for use as antigens to detect antibodies by an enzyme-linked immunosorbent assay (ELISA) in the Sevenband Grouper Epinephelus septemfasciatus. The ELISA values for a standardized suspension of antigens diluted with L-15 medium containing 1% fetal bovine serum decreased gradually with the dilution of the antigens, whereas those for the antigens diluted with distilled water (DW) initially increased with the dilution of the antigens, peaked at a 320-fold dilution, and then decreased thereafter. Additional studies revealed that binding of NNV antigens to ELISA wells was inhibited by fetal bovine serum and other substances in the L-15 medium. Sera obtained from Sevenband Grouper vaccinated with live NNV vaccine and survivors from natural NNV-infection were subjected to antibody detection by ELISA. All of the sera were positive by ELISA when the standardized suspension was diluted 320-fold, whereas sera from five out of the six survivors and two out of the six vaccinated fish were negative or weakly positive by ELISA using NNV antigens diluted 10-fold. We therefore concluded that cultured NNV solutions prepared in cell culture media may need to be diluted with distilled water for use in ELISA. Received January 28, 2014; accepted April 16, 2014.

Potential for a live red seabream iridovirus (RSIV) vaccine in rock bream Oplegnathus fasciatus at a low rearing temperature.

Serious economic losses have occurred in fingerlings and market-sized rock bream Oplegnathus fasciatus in Korea due to red seabream iridovirus (RSIV) infection. We demonstrated previously that viral multiplication in fish is downregulated by maintaining fish at far from optimum temperatures at the onset of disease. We applied this concept to develop a live RSIV vaccine in rock bream. Mortalities in rock bream that were inoculated with RSIV and reared at 21-30°C were ≥90%, whereas no mortality was observed in fish that received an RSIV inoculation and were reared at ≤18°C. RSIV kinetics revealed that RSIV multiplied rapidly in fish reared at 24.3±1.3°C, and achieved the critical level for rock bream (approximately 10(9.0) genomes/mg) within 28 days. In contrast, the RSIV genome was detected on day 10 in fish that received an RSIV inoculation at 15.5°C, and peaked on day 28 at 10(5.91±0.54) genomes/mg, then decreasing gradually, and were then maintained under the detection level beginning on day 84 after RSIV inoculation. Furthermore, the fish surviving the RSIV infection at low rearing temperature were strongly protected from re-challenge with homologous RSIV; the threshold level of RSIV for rock bream to mount a protective immune response was ≤10(5.4) genomes/mg. Cohabitation experiments revealed that the spread of RSIV from rock bream vaccinated with a live RSIV could be low if it is limited to fish in the late stage (≥84 days of elapse) after vaccination. Thus, it was concluded that when rock bream are reared at ≤18°C and inoculated with RSIV, the survivors can mount a protective immune response against RSIV, suggesting a positive effect of a live RSIV vaccine for rock bream.

Complete genome sequence of viral hemorrhagic septicemia virus isolated from an olive flounder in South Korea.

Viral hemorrhagic septicemia virus (VHSV) is a seriously problematic pathogen in olive flounder (Paralichthys olivaceus) aquaculture farms in South Korea. Here, we report the complete genome sequence of VHSV which was isolated from spleen and kidney tissues of dead fish at an aquaculture farm in 2005. This genome sequence will be useful for virus diagnostics and in comparative analyses with other virus genotypes.

Assessment of the sevenband grouper Epinephelus septemfasciatus with a live nervous necrosis virus (NNV) vaccine at natural seawater temperature.

We investigated the long-term kinetics of nervous necrosis virus (NNV) infectivity in sevenband grouper, Epinephelus septemfasciatus, injected with a live NNV vaccine at 17.3°C and reared at natural seawater temperature. We also evaluated horizontal infection of NNV from fish vaccinated with live NNV to naïve fish in a cohabitation experiment. Although 10.5% mortality was observed in the vaccinated fish, they were strongly protected from the challenge with homologous NNV. The NNV infectivity titer was detected from day 5 after vaccination, peaked on day 10 at 10(7.43±0.35) TCID50/g, but NNV was under the detection limit (≤10(2.8) TCID50/g) between days 42 and 128. No mortalities or NNV were detected in any of the vaccinated and cohabitated naïve fish, suggesting that NNV spread from fish vaccinated with live NNV should be low if it is limited to fish in the late stage of vaccination (≥42 days from NNV inoculation). The present results demonstrate that a protective immune response to NNV was mounted in sevenband grouper by the live NNV vaccine without controlling fish rearing temperature.

Establishment and characterization of the epithelioma papulosum cyprini (EPC) cell line persistently infected with infectious pancreatic necrosis virus (IPNV), an aquabirnavirus.

Infectious pancreatic necrosis virus (IPNV), a type species of aquabirnaviruses in the family Birnaviridae, is an etiological agent of infectious pancreatic necrosis and has been isolated from epizootics of cultured salmonids. In the present study, an epithelioma papulosum cyprini (EPC) cell line persistently infected with IPNV (PI-EPC) was experimentally established by subculturing EPC cells surviving IPNV infection, and was characterized. PI-EPC cells were morphologically indistinguishable from EPC, but continued to grow and yield IPNV. PI-EPC cells showed no cytopathic effect due to IPNV inoculation, and susceptibility of PI-EPC cells against heterologous viruses was not different from that of EPC cells. Only one cell of 10(3.5) PI-EPC cells produced IPNV at approximately 10(0.5) 50% tissue culture infectious dose (TCID50)/cell/day, which was approximately 1,000 times lower than that of normal EPC cells. PI-EPC cells that did not yield IPNV (N-PI-EPC) were screened. The IPNV genome was detected from both PI-EPC and N-PI-EPC cells, and the IPNV VP2 structural protein was detected from both cell lines, but no other IPNV proteins were observed by Western blot analysis with anti-IPNV serum. Thus, multiplication of IPNV in PI-EPC cells was regulated by some host cell factors, except interferon.

Potentiality of a live vaccine with nervous necrosis virus (NNV) for sevenband grouper Epinephelus septemfasciatus at a low rearing temperature.

Nervous necrosis virus (NNV) is the causative agent of viral nervous necrosis (VNN), one of the most serious diseases in over 30 species of cultured marine fishes worldwide. Although several kinds of NNV vaccines have been developed, none of these vaccines have been yet marketed. Here, we demonstrate the potentiality of a live NNV vaccine for sevenband grouper Epinephelus septemfasciatus at a low rearing temperature (17°C). Moreover, we investigated the kinetics of NNV infectivity titer in fish reared at low and optimum temperatures (17°C and 26°C) for VNN onset to determine why sevenband grouper reared at 17°C survive NNV infection. In pathogenicity tests of NNV, fish mortality was reduced by decreasing the fish rearing temperature, and no mortality was observed in fish reared at 17°C regardless of the infection method. During fish acclimation to the optimum temperature of VNN onset (26°C), increased mortalities were observed in the survivors from the 1st NNV-infection. Little or no mortality was observed in the 2nd NNV-infection. Thus, it was demonstrated that the survivors from the 1st NNV-infection mounted a specific protective immune response against NNV. Especially, in the fish infected with NNV by immersion at 17°C, only two out of 30 fish died until the end of the 2nd infection (total survival rate: 93.3%), suggesting a positive potentiality for a live NNV vaccine. In the analysis of NNV kinetics in the fish reared at 26°C, NNV rapidly multiplied up to ≥ 10(9)TCID(50)g(-1) before fish began to die, and the critical level of NNV was around 10(10)TCID(50)g(-1). Probability of NNV multiplication reduced by decreasing the inoculated NNV dose, but NNV multiplication rate was independent of the NNV dose. The threshold of NNV for fish mounting a protective immune response was around >10(4)TCID(50)g(-1). Against this, in the fish reared at 17°C, NNV slowly multiplied in comparison with that in fish at 26°C. NNV titer in the peak was at 10(7.1 ± 1.4)TCID(50)g(-1), which was far behind the critical level of NNV but still greatly above the threshold level (10(4)TCID(50)g(-1)). Thus, it was demonstrated that the multiplication rate of NNV in vivo was strongly correlated to NNV virulence and fish mortality, and down-regulation of NNV multiplication in fish reared at 17°C enabled control of VNN onset for development of a live NNV vaccine.

Shift of phylogenic position in megalocytiviruses based on three different genes.

Major capsid protein (MCP), the adenosine triphosphatase (ATPase), and the PstI fragment genes from five Japanese and three Korean megalocytivirus isolates were sequenced and phylogenetically analyzed with known megalocytiviruses. Phylogenetic trees formed three major clusters (M1, M2, and M3 or P1, P2, and P3), and genogroup I was divided into two minor clusters (M1a/M1b and P1a/P1b) using three target genes. Sequence identity was >97% within each cluster, except cluster II of the PstI fragment (>94% of sequence identity). Interestingly, different genotyping patterns were observed for the same isolates depending on the gene analyzed. The JPN-YelTail and JPN-BfTuna isolates located in the minor M1a cluster, based on MCP and ATPase nucleotide sequences, appeared in the minor P1b cluster based on the PstI fragment, suggesting a shift of phylogenic position in megalocytiviruses. Further study will be conducted to compare the viral antigenicity and pathogenicity between the two isolates showing the shift of phylogenic position and the other isolates clustered within genogroup I.

Live vaccine of viral hemorrhagic septicemia virus (VHSV) for Japanese flounder at fish rearing temperature of 21°C instead of Poly(I:C) administration.

The process of "Poly(I:C) immunization" involves immunization of fish with a pathogenic live virus, followed by administration of Poly(I:C), which induces a transient, non-specific antiviral state. As a result, fish in an antiviral state survive the initial immunization with live virus. Moreover, these fish are able to mount a specific protective immune response against the injected pathogenic virus. In the present study, we investigated the optimum temperature for Poly(I:C) immunization of Japanese flounder Paralichthys olivaceus with live viral hemorrhagic septicemia virus (VHSV). It was revealed that the optimum temperature was around at 17°C for Poly(I:C) immunization in Japanese flounder. Furthermore, the protection efficacy of Poly(I:C) immunization was significantly decreased by elevation of fish rearing temperature, and no efficacy was observed at a fish rearing temperature of 25°C. Interestingly, no mortality by VHSV infection was observed in fish reared at 21°C and 25°C even when those fish were not administered Poly(I:C). All of the survivors from the first VHSV-challenge at 21°C were strongly protected from re-challenge with VHSV. However, almost all of the survivors (≥82.6%) from the first challenge at 25°C were lost by the second challenge with VHSV. It was thus concluded that by rearing fish at 21°C and challenging with live VHSV, it is possible to induce strong specific immunity in Japanese flounder without Poly(I:C) administration.

Protection of Japanese flounder Paralichthys olivaceus from viral hemorrhagic septicemia (VHS) by Poly(I:C) immunization.

In immunization of fish with polyinosinic-polycytidylic acid (poly[I:C], a synthetic double-stranded RNA, injection of Poly(I:C) followed by challenge with a live virus induces a transient, non-specific antiviral state by interferon activity. When exposed to a virus while in this antiviral state, the fish acquire a specific and protective immunity against the corresponding viral disease and survive. In the present study, the effiacy of Poly(I:C) immunization was investigated in japanese flounder Paralichthys olivaceus using viral hemorrhagic septicemia virus (VHSV) as a model; the minimum dose of Poly(I:C) required for inducing protection and the duration of the antiviral state were determined, and a potentially curative effect of Poly(I:C) administration was assessed. The antiviral state was induced by administration of Poly(I:C) doses ranging from 12.5 to 200 microg fish(-1). Minimum dose to induce the antiviral state (relative percentage survival, RPS: 90%) was 12.5 microg fish(-1). No curative effect of Poly(I:C) was observed in fish pre-infected with VHSV. Fish injected with 200 microg Poly(I:C) fish(-1) were highly protected (RPS: 100%) from an artificial challenge with VHSV, and specific antibodies against VHSV were detected. The corresponding high level of antiviral state against VHSV was attained 1 d post Poly(I:C) injection, lasted for 6 d and susequently decreased. Moreover, the surviving fish were highly protected from re-challenge with VHSV (RPS: 100%). Thus, it was considered that an immunity against viral hemorrhagic septicemia was induced in the Japanese flounder by injecting live VHSV following Poly(I:C) administration.

Protection of rainbow trout from infectious hematopoietic necrosis (IHN) by injection of infectious pancreatic necrosis virus (IPNV) or poly(I:C).

It was recently reported that prophylaxis against infectious hematopoietic necrosis virus (IHNV) in fish was induced by pre-exposure to the infectious pancreatic necrosis virus (IPNV). Here the establishment of IHNV immunity in rainbow trout Oncorhynchus mykiss was investigated by IHNV challenge following non-lethal pre-infection with IPNV. Also, synthetic double-stranded RNA polyinosinic polycytidylic acid, Poly(I:C), an inducer for interferon (IFN), was evaluated as a substitute for IPNV induction of the non-specific antiviral state and subsequent IHNV-specific immunity in fish. Rainbow trout pre-infected with IPNV were protected from IHNV challenge 7 d later (relative percentage survival, RPS: 68.8%), and IHNV-specific antibodies were detected in sera from the survivors. Moreover, these surviving fish showed 91.6% RPS when re-challenged with IHNV 28 d after the primary IHNV challenge. Thus, fish appear to acquire IHNV-specific immunity through the IHNV challenge following pre-injection with IPNV. Fish pre-injected with Poly(I:C) were also highly protected from IHNV challenge 2 d later (RPS: 95.2%), and IHNV-specific antibodies were also detected amongst survivors. The survivors showed a 100% survival rate following re-challenge with IHNV both 21 and 49 d after the primary IHNV challenge. Thus, IHNV immunity in rainbow trout is induced by challenge with live IHNV following pre-injection with either IPNV or Poly(I:C). The use of Poly(I:C) to induce an anti-viral state protecting rainbow trout from an otherwise lethal vaccination dose of IHNV may have application to a wider range of fish species and fish pathogenic viruses.

Fish immunization using a synthetic double-stranded RNA Poly(I:C), an interferon inducer, offers protection against RGNNV, a fish nodavirus.

Viral nervous necrosis (VNN), caused by a fish nodavirus, is one of the most serious fish diseases worldwide. Here we report a unique vaccination method in sevenband grouper Epinephelus septemfasciatus using a synthetic double-stranded RNA polyinosinic polycytidylic acid (Poly(I:C)), an interferon inducer, followed by challenge with a live fish nodavirus. Fish injected with Poly(I:C) at 200 microg fish(-1) were highly protected from artificial challenge with red-spotted grouper nervous necrosis virus (RGNNV) (relative percentage survival, RPS: 100%), and specific antibodies against RGNNV were detected in sera from survivors. Moreover, the surviving fish were protected from rechallenge with RGNNV (relative percent survival RPS: 100%). Thus, it was confirmed that specific immunity against RGNNV was established in sevenband grouper by injection with live RGNNV following Poly(I:C) administration. Antiviral state was induced in fish by injection with Poly(I:C) at > or = 50 microg fish(-1), but no toxic response was observed in the fish even if Poly(I:C) was injected at a dose of 200 microg fish . In fish injected with Poly(I:C) at 200 pg fish(-1), a high level of antiviral state of > 90% RPS against RGNNV challenge lasted for at least 4 d after Poly(I:C) injection. However, no curative effect by Poly(I:C) injection was observed in fish already infected with RGNNV. It is considered that the present immunization method using Poly(I:C) followed by a live virus injection could offer protection against various viral infections in a broader range of fish species.