Murine responses to recombinant MVA versus ALVAC vaccines against tumor-associated antigens, gp100 and 5T4.

Virally vectored cancer vaccines comprise a new form of immunotherapy that aim to generate anti-tumor immune responses with potential for tumor clearance and enhanced patient survival. Here, we compared 2 replication-deficient poxviruses modified vaccinia Ankara (MVA) and ALVAC(2) in their ability to induce antigen expression and immunogenicity of the tumor-associated antigens (TAAs) 5T4 and gp100. To facilitate the comparison, recombinant MVA-gp100M and ALVAC(2)-5T4 were constructed to complement existing ALVAC(2)-gp100M and MVA-5T4 vectors. Recombinant TAA expression in chicken embryo fibroblast cells was confirmed by Western blot analysis. 5T4 expression was approximately equal for both viruses, whereas ALVAC-derived gp100 was quickly degraded, at a time point when MVA-derived gp100 was still stable and expressed at high levels. Human leukocyte antigen-A2 transgenic mice were vaccinated with recombinant viruses and the CD8 T-cell responses elicited against each TAA were monitored by interferon-γ enzyme-linked immunospot. No 5T4 peptide responses were detected using splenocytes from mice vaccinated with either vector, whereas vaccination with MVA elicited a significantly higher gp100-specific response than ALVAC(2) at 10 PFU (P<0.001). In CD-1 mice, each vector elicited similar 5T4 antibody responses, whereas MVA was more potent and induced gp100 antibody responses at a lower immunization dose than ALVAC (P<0.001). In this study, immunogenicity varied depending on the viral vector used and reflected vector-associated differences in in vitro TAA expression and stability. These findings suggest that novel vector-transgene combinations must be assessed individually when designing vaccines, and that stability of vector-encoded proteins produced in vitro may be useful as a predictor for in vitro immunogenicity.

Production of HIV-1 p24 protein in transgenic tobacco plants.

The production of antigens for vaccines in plants has the potential as a safe and cost-effective alternative to traditional production systems. Toward the development of a plant-based expression system for the production of human immunodeficiency virus type I (HIV-1) p24 capsid protein, the p24 gene was introduced into the genome of tobacco plants using Agrobacterium tumefaciens-mediated gene transfer. Southern blot analyses confirmed the presence of the p24 coding sequence within the genome of transgenic lines. Western blot analysis of protein extracts from transgenic plants identified plant-expressed p24 protein that cross-reacted with a p24-specific monoclonal antibody, thus confirming the maintenance of antigenicity. Quantification of the p24 protein using enzyme-linked immunosorbent assay (ELISA) estimated yields of approx 3.5 mg per g of soluble leaf protein. Similar accumulation levels of p24 were also detected in T1 plants, confirming that the p24 gene is transmitted stably. Our results indicate that plant-based transgenic expression represents a viable means of producing p24 for the development of HIV vaccine and for use in HIV diagnostic procedures.