Stability and efficacy of the 3'-UTR A4G-G5A variant of viral hemorrhagic septicemia virus (VHSV) as a live attenuated immersion VHSV vaccine in olive flounder (Paralichthys olivaceus)

Protective efficacy and immune responses of largemouth bass (Micropterus salmoides) immunized with an inactivated vaccine against the viral hemorrhagic septicemia virus genotype IVa

Viral hemorrhagic septicemia virus (VHSV) poses a significant threat to the aquaculture industry, prompting the need for effective preventive measures. Here, we developed an inactivated VHSV and revealed the molecular mechanisms underlying the host's protective response against VHSV. The vaccine was created by treating VHSV with 0.05 % formalin at 16 °C for 48 h, which was determined to be the most effective inactivation method. Compared with nonvaccinated fish, vaccinated fish exhibited a remarkable increase in survival rate (99 %) and elevated levels of serum neutralizing antibodies, indicating strong immunization. To investigate the gene changes induced by vaccination, RNA sequencing was performed on spleen samples from control and vaccinated fish 14 days after vaccination. The analysis revealed 893 differentially expressed genes (DEGs), with notable up-regulation of immune-related genes such as annexin A1a, coxsackievirus and adenovirus receptor homolog, V-set domain-containing T-cell activation inhibitor 1-like, and heat shock protein 90 alpha class A member 1 tandem duplicate 2, indicating a vigorous innate immune response. Furthermore, KEGG enrichment analysis highlighted significant enrichment of DEGs in processes related to antigen processing and presentation, necroptosis, and viral carcinogenesis. GO enrichment analysis further revealed enrichment of DEGs related to the regulation of type I interferon (IFN) production, type I IFN production, and negative regulation of viral processes. Moreover, protein-protein interaction network analysis identified central hub genes, including IRF3 and HSP90AA1.2, suggesting their crucial roles in coordinating the immune response elicited by the vaccine. These findings not only confirm the effectiveness of our vaccine formulation but also offer valuable insights into the underlying immunological mechanisms, which can be valuable for future vaccine development and disease management in the aquaculture industry.

Protection of rainbow trout (Oncorhynchus mykiss) against VHSV genotype Ia and IHNV by immunization with VHSV genotype IVa backbone-based single-cycle viruses

To evaluate the protective effect of viral hemorrhagic septicemia virus genotype IVa (VHSV IVa) genome-based single-cycle viruses against VHSV genotype Ia (VHSV Ia) and infectious hematopoietic necrosis virus (IHNV) in rainbow trout, three kinds of single-cycle VHSVs were rescued using reverse genetic technology: i) rVHSV-IaGΔTM^-IVaG containing the transmembrane and cytoplasmic region-deleted G protein (GΔTM) of VHSV Ia instead of VHSV IVa full G gene ORF and having VHSV IVa G proteins on the envelope; ii) rVHSV-IaGΔTM^-IaG containing VHSV Ia GΔTM instead of VHSV IVa full G gene ORF and having VHSV Ia G proteins on the envelope; iii) rVHSV-IaGΔTM-ihnvGΔTM^-IVaG containing not only VHSV Ia GΔTM instead of full G gene but also IHNV GΔTM instead of NV gene and having VHSV IVa G proteins on the envelope. Rainbow trout immunized with rVHSV-IaGΔTM^-IaG and rVHSV-IaGΔTM^-IVaG showed significantly higher serum antibody titers against both VHSV Ia and VHSV IVa, and showed no mortality against VHSV Ia infection, while fish in the control groups showed 100% mortalities. Fish immunized with rVHSV-IaGΔTM-ihnvGΔTM^-IVaG showed significantly higher serum antibody titers against VHSV IVa, VHSV Ia, and IHNV compared to fish in the control group. Immunization with rVHSV-IaGΔTM-ihnvGΔTM^-IVaG induced significantly higher protection against not only VHSV Ia but also IHNV. These results suggest that the present single-cycle rVHSV-based system can be used as a platform to produce combined vaccines that can protect fish from multiple pathogenic species. However, the mechanism of the high protection against IHNV despite comparatively low antibody titer remains to be investigated.

Expression and purification of S5196-272 and S6200-317 proteins from Tilapia Lake Virus (TiLV) and their potential use as vaccines

Tilapia Lake Virus Disease (TiLVD) is caused by Tilapia Lake Virus (TiLV), and it has a cumulative mortality rate of up to 90% in Nile tilapia (Oreochromis niloticus). TiLV is a negative enveloped single-stranded RNA virus with 10 genomic segments. Segment 5 (S5) and segment 6 (S6) were predicted to include a signaling peptide, suggesting that the encoded proteins of these two segments may exist as part of the virus envelope. Based on bioinformatic predictions, the S5 and S6 proteins in this study were produced, including S5_27-343, S5_27-172, S5_196-272, S6_30-317, S6_30-190, and S6_200-317. All proteins were tested for their expression in Escherichia coli. Only S5_196-272 and S6_200-317 were expressed as soluble and insoluble proteins, respectively. The soluble protein was purified using affinity chromatography, whereas the insoluble protein was solubilized using 6 M urea lysis buffer before purification. Both proteins were further purified using gel filtration chromatography, and the results showed a symmetric peak of both proteins suggested a high degree of uniformity in the conformation of these proteins. Antigenicity results indicated that these proteins were recognized by serum from TiLV-infected fish. The immunization tests revealed that serum antibodies levels in Nile tilapia produced by S5_196-272 and S6_200-317 were significantly increased (p-value < 0.05) at 7 days post-immunization (dpi) compared to antibody levels on Day 0 (D0). All the results combined suggested a potential vaccine candidate of S5 and S6 for TiLV protection in Nile tilapia.

Development of a gene-deleted live attenuated candidate vaccine against fish virus (ISKNV) with low pathogenicity and high protection

Aquaculture provides important food, nutrition, and income sources for humans. However, aquaculture industry is seriously threatened by viral diseases. Infectious spleen and kidney necrosis virus (ISKNV) disease causes high mortality and economic losses to the fish culture industry in Asia and has been listed as a certifiable disease by the International Epizootic Office. Vaccine development is urgent to control this disease. Here, a gene-deleted live attenuated candidate vaccine (ΔORF022L) against ISKNV with low pathogenicity and high protection was developed. ΔORF022L replicated well in mandarin fish fry-1 cells and showed similar structure with wild-type ISKNV. However, the pathogenicity was significantly lower as 98% of the mandarin fish infected with ΔORF022L survived, whereas all those infected with wild-type ISKNV died. Of importance, 100% of the ΔORF022L-infected fish survived the ISKNV challenge. ΔORF022L induced anti-ISKNV specific antibody response and upregulation of immune-related genes. This work could be beneficial to the control of fish diseases.

Assessment of a natural grass carp reovirus genotype II avirulent strain GD1108 shows great potential as an avirulent live vaccine

Vaccine immunization is currently the only effective way to prevent and control the grass carp haemorrhagic disease, and the primary pathogen in these infections is grass carp reovirus genotype II (GCRV-II) for which there is no commercial vaccine. In this study, we evaluated the safety of the GCRV-II avirulent strain GD1108 which isolated in the early stage of the laboratory through continuously passed in grass carp. The immunogenicity and protective effects were evaluated after immunization by injection and immersion. The avirulent strain GD1108 could infect and replicate in the fish which did not revert to virulence after continuous passage. No adverse side effects were observed and the vaccine strain did not spread horizontally among fish. Two routes of immunization induced high serum antibody titers of OD_450nm value were 0.79 and 0.76 and neutralization titers of 320 and 320 for the injection and immersion routes of inoculation, respectively. The expression of immune-related genes increased after immunization and the levels were statistically significant. Challenge of immunized fish with a virulent GCRV-II strain resulted in protection rates of 93.88% and 76.00% for the injection and immersion routes, respectively. The avirulent strain GD1108 revealed good safety and immunogenicity via two different inoculation routes. Although the injection route provided the best immune effect, two pathways provided protection against infection with virulent GCRV-II strains in various degrees. These results indicated that the avirulent strain GD1108 can be used for the development and application as live vaccine.

Genetically engineered viral hemorrhagic septicemia virus (VHSV) vaccines

Viral hemorrhagic septicemia virus (VHSV) has been one of the major causes of mortality in a wide range of freshwater and marine fishes worldwide. Although various types of vaccines have been tried to prevent VHSV disease in cultured fishes, there are still no commercial vaccines. Reverse genetics have made it possible to change a certain regions on viral genome in accordance with the requirements of a research. Various types of VHSV mutants have been generated through the reverse genetic method, and most of them were recovered to investigate the virulence mechanisms of VHSV. In the reverse genetically generated VHSV mutants-based vaccines, high protective efficacies of attenuated VHSVs and single-cycle VHSV particles have been reported. Furthermore, the application of VHSV for the delivery tools of heterologous antigens including not only fish pathogens but also mammalian pathogens has been studied. As not much research has been conducted on VHSV mutants-based vaccines, more studies on the enhancement of immunogenicity, vaccine administration routes, safety to environments are needed for the practical use in aquaculture farms.

Review on Immersion Vaccines for Fish: An Update 2019

Immersion vaccines are used for a variety of aquacultured fish to protect against infectious diseases caused by bacteria and viruses. During immersion vaccination the antigens are taken up by the skin, gills or gut and processed by the immune system, where the resulting response may lead to protection. The lack of classical secondary responses following repeated immersion vaccination may partly be explained by the limited uptake of antigens by immersion compared to injection. Administration of vaccines depends on the size of the fish. In most cases, immersion vaccination is inferior to injection vaccination with regard to achieved protection. However, injection is problematic in small fish, and fry as small as 0.5 gram may be immersion vaccinated when they are considered adaptively immunocompetent. Inactivated vaccines are, in many cases, weakly immunogenic, resulting in low protection after immersion vaccination. Therefore, during recent years, several studies have focused on different ways to augment the efficacy of these vaccines. Examples are booster vaccination, administration of immunostimulants/adjuvants, pretreatment with low frequency ultrasound, use of live attenuated and DNA vaccines, preincubation in hyperosmotic solutions, percutaneous application of a multiple puncture instrument and application of more suitable inactivation chemicals. Electrostatic coating with positively charged chitosan to obtain mucoadhesive vaccines and a more efficient delivery of inactivated vaccines has also been successful.