Shau- Chi

Efficacies of inactivated vaccines against betanodavirus in grouper larvae (Epinephelus coioides) by bath immunization

Betanodavirus is the pathogen of viral nervous necrosis (VNN) disease that has caused mass mortality among many species of marine fish at larval stage. In this study, the efficacy of inactivated betanodavirus was evaluated by bath-immunization and bath-challenge of orange-spotted grouper (Epinephelus coioides) at early larval stage. Two kinds of chemicals were used for inactivation of the virus, and the relative percent survival (RPS) values of 0.4mM binary ethylenimine (BEI)-inactivated vaccine was revealed to be 79-95, higher than that of 0.1-0.2% formalin-inactivated vaccines (39-43). Three lengths of bath immunization time were tested, and 20 min immersion of BEI-inactivated betanodavirus at a concentration of 10(6)TICD(50)/ml was sufficient to induce high protection (RPS > 75). Protection of the BEI-inactivated vaccine was evaluated at different time post immunization, and the peak of protection was observed 30 days post vaccination, and retained for at least 3 months. The efficacies of formalin-inactivated vaccines with or without encapsulation were compared, and the result revealed that the efficacy of formalin-inactivated vaccine could be significantly improved by nano-encapsulation (RPS = 85). All these data strongly suggested that bath immunization with nano-encapsulated formalin-inactivated or BEI-inactivated betanodavirus vaccines is an effective strategy to protect grouper larvae against VNN.

Antimicrobial peptides (AMP) with antiviral activity against fish nodavirus

Nervous necrosis virus (NNV) is classified as betanodavirus of Nodaviridae, and has caused mass mortality of numerous marine fish species at larval stage. Antimicrobial peptides (AMPs) play an important role of innate immunity either against bacterial pathogens or viruses. Up to date, little is known if any AMP could effectively inhibit fish nodaviruses and its mechanism. In this study, the antiviral activities of three antimicrobial peptides (AMPs) against grouper NNV (GNNV) were screened in the fish cell line. Two of the three AMPs, tilapia hepcidin 1-5 (TH 1-5) and cyclic shrimp anti-lipopolysaccharide factor (cSALF), were able to agglutinate purified NNV particles into clump, and the clumps were further confirmed to be viral proteins by TEM and Western blot. The NNV solution, separately pre-mixed with AMP (TH 1-5 or cSALF) or deionized-distilled water for 1 h, was used to infect GF-1 cells, and the levels of capsid protein in the GNNV-AMP-infected cells at 1 h post infection were much lower than that in the GNNV-H(2)O-infected cells, indicating that only a small portion of viral particles in the GNNV-AMP mixture could successfully infected the cells. Treatment of cBB cells with TH 1-5 and cSALF did not induce Mx gene expression; however, grouper epinecidin-1 (CP643-1) could induce the expression of Mx in the pre-treated cBB cells. This study revealed three AMPs with anti-NNV activity through two different mechanisms, and shed light on the future application in aquaculture.

Temperature effect on nervous necrosis virus infection in grouper cell line and in grouper larvae.

This preliminary study elucidates the in vitro and in vivo effects of temperature on grouper nervous necrosis virus (GNNV) infection. A novel continuous cell line derived from the fin tissue of a grouper (Epinephelus coioides, Hamilton), named as GF-1 cell line, was used. Cytopathic effect was observed in GNNV-infected GF-1 cells incubated at 24-32 degrees C after viral adsorption, but not at 20 degrees C or 37 degrees C even though the viral adsorption temperature was 28 degrees C. Viral protein could be detected in the pellets of GNNV-infected GF-1 cells cultured at 20-32 degrees C, but not at 37 degrees C. In a challenge test, GNNV-challenged larvae which were maintained at a constant 28 degrees C began to die 1 day post challenge (p.c.) with a death rate of 80%. Mortality reached 100% by 50 h p.c., while the mortality of negative control fish was only 5%. The cumulative mortality of GNNV-challenged larvae at ambient temperature, i.e. 28 degrees C at noon and 24 degrees C at midnight, was 10% 1 day p.c., and increased to 100% by 80 h p.c. Based on the results, we concluded that temperature plays an important role in GNNV infection and pathogenicity.

Anti-viral mechanism of barramundi Mx against betanodavirus involves the inhibition of viral RNA synthesis through the interference of RdRp

Nervous necrosis virus (NNV) belongs to the betanodavirus of the Nodaviridae family. It is the causative agent of viral nervous necrosis (VNN) disease, and has inflicted devastating damage on the world-wide aquaculture industry. The fish that survived after the outbreak of VNN become persistently NNV-infected carriers. NNV-persistent infection has been demonstrated in a barramundi brain (BB) cell line, and it involves the type I interferon (IFN) response with the expression of Mx gene. However, little of the defense mechanism in fish cells against NNV infection is understood. In this study, the anti-NNV mechanism of barramundi Mx protein (BMx) was elucidated in cBB cells which were derived from BB cell line after serial treatments by NNV-specific antiserum and then became an NNV-free cell line. After NNV infection of cBB cells, the level of viral RNA-dependent RNA polymerase (RdRp) increased with time over a period of 24 h post-infection (hpi), but decreased when the BMx expression increased 48 and 72 hpi. When the expression of BMx was down-regulated by BMx-specific siRNA, the expression levels of viral RNA, proteins and progeny viral titers were restored. The BMx was found to colocalize with viral RdRp at the perinuclear area 24 hpi and coprecipitate with viral RdRp, indicating that they could bind with each other. Viral RdRp was also revealed to colocalize with lysosomes 48 hpi as the NNV RdRp level started to decline. Therefore, it is suggested that BMx inhibited the viral RNA synthesis by interaction with viral RdRp, and redistributed RdRp to perinuclear area for degradation.

Inactivation of nervous necrosis virus infecting grouper (Epinephelus coioides) by epinecidin-1 and hepcidin 1–5 antimicrobial peptides, and downregulation of Mx2 and Mx3 gene expressions

Betanodaviruses are one of the serious pathogens in nervous necrosis viral (NNV) disease that brings about mortality in the larval stage of grouper (Epinephelus coioides). In this study, the efficacy of pretreatment, co-treatment, and posttreatment with the antimicrobial epinecidin-1 and hepcidin 1-5 peptides against a betanodavirus was evaluated by intraperitoneal inoculation in grouper. The results showed that co-treatment of epinecidin-1 or hepcidin 1-5 with the virus was effective in promoting a significant decrease in grouper mortality. Re-challenge with virus again after 30 day in co-treated grouper groups showed high survival suggesting that epinecidin-1 and hepcidin 1-5 enhanced fish survival. However, grouper inoculated with NNV and then inoculated with epinecidin-1 8 h later showed significantly different survival from the group inoculated with virus alone, suggesting that epinecidin-1 can be used as a drug to rescue infected grouper. Infection after pretreatment, co-treatment, and posttreatment with epinecidin-1 or hepcidin 1-5 was verified by RT-PCR which showed downregulation of Mx2 and Mx3 gene expressions. All these data strongly suggest that epinecidin-1 and hepcidin 1-5 are effective peptides for protecting grouper larvae by reducing NNV infection.

Vaccination of grouper broodfish (Epinephelus tukula) reduces the risk of vertical transmission by nervous necrosis virus.

Nervous necrosis virus (NNV) has caused mass mortality in many species of cultured fish at larval stage. Strong evidence of vertical transmission of NNV has been reported in the carrier broodstock of striped jack and sea bass. An effective immunization program was developed and monitored in adult groupers (Epinephelus coioides) with average body weight of 1.35kg. The highest neutralizing antibody titers were found in the fish intramuscularly injected with adjuvanted NNV vaccine at 10(9)TCID(50)kg(-1), and the enhanced 2-fold neutralization activity could sustain up to 17 months post-vaccination (mpv). An immunization program was applied in the broodstocks of grouper (Epinephelus tukula) with body weight of 35-60kg. The levels of NNV-specific antibodies detected, from 1 to 5 mpi, in the homogenates of the eggs from the vaccinated broodfish were elevated than that from non-vaccinated fish. By nested RT-PCR, NNV was detectable in the eggs from the non-vaccinated fish at Month 5, but not in the eggs from vaccinated fish. It is therefore suggested that vaccination will be a potentially practical measure to reduce the risk of vertical transmission of NNV of grouper broodfish under stress of repeated spawning.

Dietary supplementation of Pediococcus pentosaceus enhances innate immunity, physiological health and resistance to Vibrio anguillarum in orange-spotted grouper (Epinephelus coioides) ☆

Groupers (Epinephelus spp.) are economically important fish species in Southeast Asian aquaculture. Vibriosis caused by Vibro spp. is one of the severe bacterial diseases that devastate the grouper aquaculture industry. Probiotics have been reported to show the potential to enhance fish immunity and to antagonize pathogens. In our previous study, a lactic acid bacterium Pediococcus pentosaceus strain 4012 (LAB4012), isolated from cobia intestine, protects cobia from photobacteriosis after a 2-week feeding. In this study, we examined the potential of LAB4012 to be a probiotic for the orange-spotted grouper through feeding, thus to guard against vibriosis. In vitro, LAB4012 culture supernatant with low pH suppressed the growth of Vibrio anguillarum, and lactic acid in the metabolite of LAB4012 appeared to be the major factor to the growth inhibition of V. anguillarum. In vivo, the challenge test showed that the cumulative mortality of the LAB4012-fed groupers was significantly lower than that of the control fish after V. anguillarum infection. Supplementation of LAB4012 in commercial diet not only enhanced the growth rate and erythrocyte numbers of the groupers, but also regulated the gene expression of the pro-/anti-inflammatory cytokines. One day post-infection of V. anguillarum, the leukocyte numbers in the peripheral blood and the phagocytic activity of the head-kidney phagocytes in the LAB4012-fed groupers were found significantly increased, when compared with those without LAB4012-feeding. These results suggested that LAB4012 can be a dietary probiotic for groupers in modulating the immunity and protecting the groupers from V. anguillarum infection.

Interference of the life cycle of fish nodavirus with fish retrovirus.

Interference of the life cycle of grouper nervous necrosis virus (GNNV), a member of the Nodaviridae, genus Betanodavirus, by snakehead retrovirus (SnRV) has been studied in vitro. SGF-1, a new fish cell line that is persistently infected with SnRV, was induced by inoculating SnRV into the grouper fin cell line GF-1. Culture supernatants and cell pellets from both GNNV-infected SGF-1 and GF-1 cells were collected and employed for virus productivity analysis. The yields of GNNV RNA and capsid protein in GNNV-infected SGF-1 cells were similar to those in GNNV-infected GF-1 cells. However, when GF-1 cells were used for titration, the titre of the culture supernatant from GNNV-infected SGF-1 cells was much higher than that from GNNV-infected GF-1 cells. The titration result suggested that SnRV enhanced the infection or cytopathic effect (CPE) of GNNV during GNNV and SnRV coinfection of the GF-1 cell titration system, although SnRV cannot induce any CPE in GF-1 cells alone, nor can it increase the yield of GNNV after GNNV superinfection of SGF-1 cells. Moreover, GNNV cDNA was detected in both the pellet and the supernatant from GNNV-infected SGF-1 cells. This result indicated that SnRV reverse-transcribed the GNNV single-stranded genomic RNA into cDNA during GNNV superinfection of SGF-1 cells and created a new cDNA stage in the life cycle of the fish nodavirus.

Immune gene expressions in grouper larvae (Epinephelus coioides) induced by bath and oral vaccinations with inactivated betanodavirus.

Nervous necrosis virus (NNV) has caused mass mortality in many mariculture fish species. Bath vaccination of inactivated NNV and oral immunization of recombinant NNV coat protein are reported to protect grouper larvae against NNV infection. However, the information of immune gene expression in grouper larvae (Epinephelus coioides) after bath and oral immunizations is still limited. In this study, grouper larvae were respectively bath- and orally immunized with binary ethylenimine (BEI)-inactivated NNV, and the expression levels of immune genes were analyzed. Significant gene expressions of IL-1β, Mx, MHC-I, MHC-II, CD8α, IgM and IgT were observed in bath- and orally immunized fish 1-4 weeks post immunization (wpi). Particularly, the up-regulation of IL-1β and Mx gene expression lasted for 4 weeks. The IgT gene expression in gill was only induced by bath immunization, while that in gut was only stimulated by oral immunization. Both immunizations elicited MHC-I and CD8α gene expression relative to cellular immunity. Furthermore, NNV RNA genome, which was detected in inactivated NNV, could induce Mx gene expression in grouper brain (GB) cells, indicating that NNV RNA genome could be recognized by pathogen-recognition receptors (PRRs). In summary, bath and oral vaccinations with BEI-inactivated NNV triggered the gene expression of not only humoral immunity but also cellular immunity.

GHSC70 is involved in the cellular entry of nervous necrosis virus.

ABSTRACT Nervous necrosis virus (NNV) is a devastating pathogen of cultured marine fish and has affected more than 40 fish species. NNV belongs to the betanodaviruses of Nodaviridae and is a nonenveloped icosahedral particle with 2 single-stranded positive-sense RNAs. To date, knowledge regarding NNV entry into the host cell remains limited, and no NNV-specific receptor protein has been published. Using grouper fin cell line GF-1 and purified NNV capsid protein in a virus overlay protein binding assay (VOPBA), grouper heat shock cognate protein 70 (GHSC70) and grouper voltage-dependent anion selective channel protein 2 (GVDAC2) were investigated as NNV receptor protein candidates. We cloned and sequenced the genes for GHSC70 and GVDAC2 and expressed them in Escherichia coli for antiserum preparation. Knockdown of the expression of GHSC70 and GVDAC2 genes with specific short interfering RNAs (siRNAs) significantly downregulated viral RNA expression in NNV-infected GF-1 cells. By performing an immunoprecipitation assay, we confirmed that GHSC70 interacted with NNV capsid protein, while VDAC2 did not. Immunofluorescence staining and flow cytometry analysis revealed the presence of the GHSC70 protein on the cell surface. After a blocking assay, we detected the NNV RNA2 levels after 1 h of adsorption to GF-1 cells; the level was significantly lower in the cells pretreated with the GHSC70 antiserum than in nontreated cells. Therefore, we suggest that GHSC70 participates in the NNV entry of GF-1 cells, likely functioning as an NNV receptor or coreceptor protein. IMPORTANCE Fish nodavirus has caused mass mortality of more than 40 fish species worldwide and resulted in huge economic losses in the past 20 years. Among the four genotypes of fish nodaviruses, the red-spotted grouper nervous necrosis virus (RGNNV) genotype exhibits the widest host range. In our previous study, we developed monoclonal antibodies with high neutralizing efficiency against grouper NNV in GF-1 cells, indicating that NNV-specific receptor(s) may exist on the GF-1 cell membrane. However, no NNV receptor protein has been published. In this study, we found GHSC70 to be an NNV receptor (or coreceptor) candidate through VOBPA and provided several lines of evidence demonstrating that GHSC70 protein has a role in the NNV entry step of GF-1 cells. To the best of our knowledge, this is the first report identifying grouper HSC70 and its role in NNV entry into GF-1 cells.