Virulence, immunogenicity and live vaccine potential of aroA and phoP mutants of Edwardsiella piscicida in zebrafish.

Vaccination remains the most effective approach for prevention and control of infectious diseases in aquaculture. Edwardsiella piscicida is a causative agent of edwardsiellosis leading to mass mortality in a variety of fish species, leading to huge economic losses in the aquaculture industry. In this study, we have deleted the aroA and phoP genes in E. piscicida and investigated the phenotype, degrees of attenuation, immunogenicity, and ability to confer immune protection in zebrafish host. Our vaccine strain χ16028 with genotype ΔaroA11 ΔphoP12, showed significantly reduced growth, motility, biofilm formation and intracellular replication compared to the wild-type strain J118. In this regard, χ16028 exhibited retarded colonization and attenuation phenotype in zebrafish. Studies showed that χ16028 induced TLR4 and TLR5 mediated NF-kB pathway and upregulated cytokine gene expression i.e., TNF-α, IL-1ß, IL-6, IL-8 and type-I IFN in zebrafish. Zebrafish immunized by intracoelomic injection (i.c.) with χ16028 showed systemic and mucosal IgM responses and protection against the wild-type E. piscicida i.c. injection challenge. However, the protection was only 25% in zebrafish following i.c. challenge. We speculate that our vaccine strain might be very attenuated; a booster dose may trigger better immune response and increase the percentage of survival to a more significant level.

Construction and Evaluation of Recombinant Attenuated Edwardsiella piscicida Vaccine (RAEV) Vector System Encoding Ichthyophthirius multifiliis (Ich) Antigen IAG52B.

We have successfully designed and constructed a RAEV vector system with regulated-delayed attenuation in vivo attributes that synthesizes Ichthyophthirius multifiliis (Ich) protective antigen IAG52B to enable vaccination of fish susceptible to edwardsiellosis and white spot disease. The first feature of this vaccine delivery system is an Edwardsiella piscicida strain carrying genomic deletions of asdA. AsdA is an enzyme necessary for the synthesis of diaminopimelic acid (DAP), which is an essential component of the peptidoglycan layer of the cell wall of Gram-negative bacteria. asdA mutant strains have obligate growth requirements for DAP in the medium or a plasmid vector with the wild-type asdA gene enabling synthesis of DAP. This balanced-lethal plasmid vector-host system in E. piscicida enables as a second feature the synthesis of recombinant antigens to induce protective immunity against fish pathogens. Recombinant protective antigen IAG52B from the fish pathogen I. multifiliis was synthesized by RAEV strains harboring the AsdA+ plasmid pG8R8029. The third feature of this vaccine strain is a regulated-delayed attenuation in vivo phenotype that is based on the replacement of an arabinose-regulated araC ParaBAD cassette for the promoters of the fur and crp genes of E. piscicida such that the expression of these genes is dependent on arabinose provided during growth. Thus, following colonization, the Fur and Crp proteins stop being synthesized due to the lack of arabinose and attenuation is progressively achieved in vivo to prevent generation of diseases symptoms. Our vaccine strain χ16022 with the genotype ΔasdA10 ΔPfur170::TT araC ParaBADfur ΔPcrp68::TT araC ParaBADcrp contains the AsdA+ plasmid, pG8R8029, which encodes the IAG52B antigen. Vaccine strain χ16022(pG8R8029) is attenuated and induces systemic and mucosal IgM titer against E. piscicida and Ich in zebrafish. In addition, transcript levels of tnf-α, il-1ß, il-6 and il-8 were significantly increased in different tissues of vaccinated zebrafish compared to unimmunized fish. Zebrafish vaccinated with χ16022(pG8R8029) showed 60% survival upon intracoelomic (i.c.) challenge with a lethal dose of virulent E. piscicida strain J118. Our RAEV system could be used as a generalized vaccine-vector system to protect teleost fish against multiple bacterial, viral and parasitic infectious diseases.

Pathogenicity and immunogenicity of Edwardsiella piscicida ferric uptake regulator (fur) mutations in zebrafish.

Edwardsiella piscicida is the etiological agent of edwardsiellosis in fish and causes severe economic losses in global aquaculture. Vaccination would be the most effective method to prevent infectious diseases and their associated economic losses. The ferric uptake regulator (Fur) is an important transcriptional global regulator of Gram-negative bacteria. In this study, we examined the regulatory function of Fur in E. piscicida. We designed a strain that displays features of the wild-type virulent strain of E. piscicida at the time of immunization to enable strains first to effectively colonize lymphoid tissues and then to exhibit a regulated delayed attenuation in vivo to preclude inducing disease symptoms. Regulated delayed attenuation in vivo is based on the substitution of a tightly regulated araC ParaBAD cassette for the promoter of the fur gene such that expression of this gene is dependent on arabinose provided during growth. Thus, following E. piscicida mutant colonization of lymphoid tissues, the Fur protein ceases to be synthesized due to the absence of arabinose such that attenuation is gradually manifest in vivo to preclude induction of diseases symptoms. We deleted the promoter, including all sequences that interact with activator or repressor proteins, for the fur gene, and substituted the improved araC ParaBAD cassette to yield an E. piscicida strain with the ΔPfur170:TT araC ParaBADfur deletion-insertion mutation (χ16012). Compared to the wild-type strain J118, χ16012 exhibited retarded growth and enhanced siderophore production in the absence of arabinose. mRNA levels of Fur-regulated genes were analyzed in iron deplete or replete condition in wild-type and fur mutant strains. We observed zebrafish immunized with χ16012 showed better colonization and protection compared to the Δfur (χ16001). Studies showed that E. piscicida strain χ16012 is attenuated and induces systemic and mucosal IgM titer in zebrafish. In addition, we found an increase in transcript levels of tnf-α, il-1ß, il-8 and ifn-γ in different tissues of zebrafish immunized with χ16012 compared to the unimmunized group. We conclude that, E. piscicida with regulated delayed attenuation could be an effective immersion vaccine for the aquaculture industry.