V. Juillard

A West Nile virus (WNV) recombinant canarypox virus vaccine elicits WNV-specific neutralizing antibodies and cell-mediated immune responses in the horse

Successful vaccination against West Nile virus (WNV) requires induction of both neutralizing antibodies and cell-mediated immune responses. In this study, we have assessed the ability of a recombinant ALVAC-WNV vaccine (RECOMBITEK WNV) to elicit neutralizing antibodies and virus-specific cell-mediated immune responses in horses. In addition, we examined whether prior exposure to ALVAC-WNV vaccine would inhibit B and cell-mediated immune responses against the transgene product upon subsequent booster immunizations with the same vaccine. The results demonstrated that the recombinant ALVAC-WNV vaccine induced neutralizing antibodies and prM/E insert-specific IFN-gamma(+) producing cells against WNV in vaccinated horses. Prior exposure to ALVAC-WNV vaccine did not impair the ability of horses to respond to two subsequent booster injections with the same vaccine, although anti-vector-specific antibody and cell-mediated immune responses were induced in vaccinated horses. This report describes, for the first time, the induction of antigen-specific cell-mediated responses following vaccination with an ALVAC virus recombinant vaccine encoding WNV antigens. Moreover, we showed that both WNV-specific IFN-gamma producing cells and anti-WNV neutralizing antibody responses, are not inhibited by subsequent vaccinations with the same vector vaccine.

Superiority of needle-free transdermal plasmid delivery for the induction of antigen-specific IFNγ T cell responses in the dog

Although successful needle-free DNA vaccination has been described on several occasions, the true benefit of this delivery technology over needle-based injections for DNA vaccination of dogs has not yet been documented. We conducted a side-by-side comparison of needle-free transdermal plasmid delivery vs. intramuscular vs. intradermal needle-based delivery of the same plasmid in dogs. Our data confirmed the importance of the route of plasmid delivery and further established the unique potential of needle-free transdermal plasmid delivery to elicit strong antigen-specific, hTyr-specific IFNgamma T in the dog. Further, this study demonstrated that properly enabled DNA vaccination has the potential to trigger very significant cell-based immune responses in dogs, establishing needle-free transdermal plasmid delivery as a critical technology for successful immunotherapy of cancer and/or chronic infectious diseases in companion animal medicine.

Quantitative analysis of the antigen-specific IFNγ+ T cell-mediated immune response in conventional outbred pigs: kinetics and duration of the DNA-induced IFNγ+ CD8+ T cell response

It is now well established that antigen-specific CD8(+) T cells play a major role in vaccine-induced immunity against intracellular pathogens and tumor cells. The detection of these immune cells in outbred animals has been hampered mainly by the need to generate individual autologous antigen-presenting cells (APCs) due to the high degree of polymorphism of the major histocompatibility complex (MHC) Class I loci. We used individually derived immature porcine dendritic cells infected with a pox-based recombinant viral vector to ex vivo stimulate PBMCs from vaccinated conventional pigs. The frequencies of antigen-specific T cells was determined by the number of IFNgamma-secreting cells in a quantitative enzyme-linked immune spot (ELISPOT) assay. Using this approach we were able to rank different pseudorabies virus (PRV) vaccines strategies for their ability to prime viral-specific IFNgamma(+) T cells. Plasmid DNA has recently emerged as a promising tool with multiple applications in the field of infectious diseases, allergy and cancer. We showed for the first time in this study that DNA immunization induced a long-lived antigen-specific IFNgamma(+) T cells response in conventional pigs. Additional studies allowed us to show that these virus-specific IFNgamma(+) responding cells detected in this ELISPOT assay were MHC-restricted and comprised in the CD8alpha(bright) pig T cell subset. These new data confirm the usefulness of DNA vaccines to control diseases requiring cellular immunity in pigs.

The synthetic peptides bovine enteric β-defensin (EBD), bovine neutrophil β-defensin (BNBD) 9 and BNBD 3 are chemotactic for immature bovine dendritic cells

Human and murine immature DCs (iDCs) are highly efficient in antigen capture and processing, while as mature cells they present antigen and are potent initiators of cell-mediated immune responses. Consequently, iDCs are logical targets for vaccine antigens. Originally discovered for their antimicrobial activity, and thought of as strictly part of the innate immune system, studies with defensins such as human β (beta)-defensin 2 (hBD2) and murine β-defensin 2 (mBD2) have shown that they can function as chemo-attractant for iDCs and, in vaccination strategies, can enhance antigen-specific adaptive immune responses. Most studies to date have been conducted in mice. In contrast, little is known about defensins in cattle. To expand our understanding of the role of defensins in modulating immune responses in cattle, DCs were generated from bovine monocytes and the immature state of these bovine DCs was characterized phenotypically and through functional assays. By day 3 (DC3), bovine monocyte-derived DCs stained positively for DC-specific receptors CD1, CD80/86, CD205, DC-Lamp and MMR. When compared to conventional 6-day DC cultures or DCs cultured for 10 days with and without maturation factors, these DC3 were functionally at their most immature stage. Fourteen of the 16 known bovine β-defensins were synthesized and the synthetic peptides were screened for their ability to attract bovine iDCs. Bovine DC3 were consistently attracted to BNBD3, an analog of BNBD3 (aBNBD3), BNBD9 and bovine EBD in vitro and to aBNBD3 in vivo. These results are the first to describe chemotactic ability of synthetic bovine β-defensins for immature bovine monocyte-derived DCs.