Canarypox and fowlpox viruses as recombinant vaccine vectors: a biological and immunological comparison.

Canarypox and fowlpox viruses represent alternative vaccine vectors due to their natural host-range restriction to avian species. Although they cannot replicate in mammals, they correctly express transgenes in human cells and elicit a complete immune response in vaccinated subjects. Several studies have evaluated their genomic differences and protective efficacy in preclinical trials, but detailed information is not available for their transgene expression, cytokine modulation and abortive replication in mammals. This study demonstrates that the heterologous HIV gag/pol and env genes are more efficiently expressed by fowlpox in non-immune and immune cells. The production of retrovirus-like particles, the longer transgene expression, and a balanced cytokine induction may confer to fowlpox-based recombinants the ability to elicit a better immune response.

Canarypox and fowlpox viruses as recombinant vaccine vectors: an ultrastructural comparative analysis.

Due to their natural host-range restriction to avian species, canarypox virus (CP) and fowlpox virus (FP) represent efficient and safe vaccine vectors, as they correctly express transgenes in human cells, elicit complete immune responses, and show protective efficacy in preclinical animal models. At present, no information is available on the differences in the abortive replication of these two avipox viruses in mammalian cells. In the present study, the replicative cycles of CP and FP, wild-type and recombinants, are compared in permissive and non-permissive cells, using transmission electron microscopy. We demonstrate that in non-permissive cells, the replicative cycle is more advanced in FP than in CP, that human cells, whether immune or not, are less permissive to avipox replication than monkey cells, and that the presence of virus-like particles only occurs after FP infection. Overall, these data suggest that the use of FP recombinants is more appropriate than the use of CP for eliciting an immune response.

Pseudovirion particle production by live poxvirus human immunodeficiency virus vaccine vector enhances humoral and cellular immune responses.

Live-vector-based human immunodeficiency virus (HIV) vaccines are an integral part of a number of HIV vaccine regimens currently under evaluation. Live vectors that carry an intact gag gene are capable of eliciting HIV pseudovirion particle formation from infected host cells. The impact of pseudovirion particle formation on the immune response generated by live HIV vaccine vectors has not been established. In this study, a canarypox HIV vaccine candidate vector expressing HIV gag and env genes, vCP205, was modified by the introduction of a glycine-to-alanine coding change in the N-terminal myristylation site of gag to create Myr- vCP205. This substitution effectively eliminated particle formation without altering the level of protein production. vCP205 and Myr- vCP205 were then directly compared for the ability to induce HIV-specific immune responses in mice. The particle-competent vector vCP205 elicited higher levels of CD8+ T-cell responses, as indicated by gamma interferon enzyme-linked immunospot (ELISPOT) assay and intracellular cytokine staining. Humoral responses to Gag and Env were also markedly higher from animals immunized with the particle-competent vector. Furthermore, HIV-specific CD4+ T-cell responses were greater among animals immunized with the particle-competent vector. Using a human dendritic cell model of antigen presentation in vitro, vCP205 generated greater ELISPOT responses than Myr- vCP205. These results demonstrate that pseudovirion particle production by live-vector HIV vaccines enhances HIV-specific cellular and humoral immune responses.