Pre-clinical safety and efficacy of TA-CIN, a recombinant HPV16 L2E6E7 fusion protein vaccine, in homologous and heterologous prime-boost regimens.

Human papillomavirus (HPV) E6 and E7 oncoproteins are attractive targets for T-cell-based immunotherapy of cervical intraepithelial neoplasia (CIN) and cancer. A newly designed vaccine, comprising the HPV16 L2, E6 and E7 as a single fusion protein (TA-CIN), was shown to elicit HPV16-specific CTL, T-helper cells and antibodies in a pre-clinical mouse model. These immune responses effectively prevented outgrowth of HPV16-positive tumour cells in a prophylactic setting as well as in a minimal residual disease setting. CTL immunity was optimally induced when TA-CIN was employed in heterologous prime-boost regimens in combination with TA-HPV, a clinical grade vaccinia-based vaccine. These data provide a scientific basis for the use of TA-CIN, alone or in combination with TA-HPV in future human trials.

Inactivated recombinant plant virus protects dogs from a lethal challenge with canine parvovirus.

A vaccine based upon a recombinant plant virus (CPMV-PARVO1), displaying a peptide derived from the VP2 capsid protein of canine parvovirus (CPV), has previously been described. To date, studies with the vaccine have utilized viable plant chimaeric particles (CVPs). In this study, CPMV-PARVO1 was inactivated by UV treatment to remove the possibility of replication of the recombinant plant virus in a plant host after manufacture of the vaccine. We show that the inactivated CVP is able to protect dogs from a lethal challenge with CPV following parenteral immunization with the vaccine. Dogs immunized with the inactivated CPMV-PARVO1 in adjuvant displayed no clinical signs of disease and shedding of CPV in faeces was limited following CPV challenge. All immunized dogs elicited high titres of peptide-specific antibody, which neutralized CPV in vitro. Levels of protection, virus shedding and VP2-specific antibody were comparable to those seen in dogs immunized with the same VP2- peptide coupled to keyhole limpet hemocyanin (KLH). Since plant virus-derived vaccines have the potential for cost-effective manufacture and are not known to replicate in mammalian cells, they represent a viable alternative to current replicating vaccine vectors for development of both human and veterinary vaccines.

Highly efficient transduction of human monocyte-derived dendritic cells with subgroup B fiber-modified adenovirus vectors enhances transgene-encoded antigen presentation to cytotoxic T cells.

The efficiency of dendritic cells (DC) as immunotherapeutic vaccines critically depends on optimal delivery of target Ags. Although DC modified by subgroup C type 5 recombinant adenoviruses (rAd5) provide encouraging results, their clinical application is hampered by the need for high viral titers to achieve sufficient gene transfer, due to the lack of the Ad5 fiber receptor. We now demonstrate that rAd5 carrying subgroup B Ad fibers are up to 100-fold more potent than classical rAd5 for gene transfer and expression in human DC, rAd5 with a type 35 fiber (rAd5F35) being the most efficient vector. This improvement relates to a greater and faster virus entry and to an increased transgene expression especially following DC maturation. Furthermore, these new vectors possess enhanced synergistic effects with other activation signals to trigger DC maturation. Consequently, rAd5F35-infected DC engineered to express the gp100 melanoma-associated Ag largely exceed rAd5-infected DC in activating gp100-specific CTL. Finally, the DC infection pattern of rAd5F35 is fully conserved when DC are in the vicinity of primary skin-derived fibroblasts, suggesting this vector as a candidate for in vivo targeting of DC. Thus, subgroup B fiber-modified rAd5 constitute a major breakthrough in the exploitation of ex vivo rAd-targeted DC as clinically relevant vaccines and may also be suitable for in vivo genetic modification of DC.

Systemic immunization with papillomavirus L1 protein completely prevents the development of viral mucosal papillomas.

Infection of mucosal epithelium by papillomaviruses is responsible for the induction of genital and oral warts and plays a critical role in the development of human cervical and oropharyngeal cancer. We have employed a canine model to develop a systemic vaccine that completely protects against experimentally induced oral mucosal papillomas. The major capsid protein, L1, of canine oral papillomavirus (COPV) was expressed in Sf9 insect cells in native conformation. L1 protein, which self-assembled into virus-like particles, was purified on CsCl gradients and injected intradermally into the foot pad of beagles. Vaccinated animals developed circulating antibodies against COPV and became completely resistant to experimental challenge with COPV. Successful immunization was strictly dependent upon native L1 protein conformation and L1 type. Partial protection was achieved with as little as 0.125 ng of L1 protein, and adjuvants appeared useful for prolonging the host immune response. Serum immunoglobulins passively transferred from COPV L1-immunized beagles to naive beagles conferred protection from experimental infection with COPV. Our results indicate the feasibility of developing a human vaccine to prevent mucosal papillomas, which can progress to malignancy.

Protection of swine against foot-and-mouth disease with viral capsid proteins expressed in heterologous systems.

Three groups of swine were each inoculated with a different antigen preparation of foot-and-mouth disease virus (FMDV) capsid proteins and challenged by contact exposure to animals infected with FMDV. One group of four animals was inoculated with an extract from cells infected with a recombinant baculovirus containing the FMDV P1-2A structural protein precursor gene and a portion of the P2 gene. Two out of four animals were protected from clinical disease, but not from virus replication. A second group of animals was inoculated with an extract from Escherichia coli that expressed FMDV proteins from a construct containing the P1-2A gene, a portion of the P2 gene and the 3C protease gene. Three out of four animals in this group did not develop clinical signs of FMD upon challenge and two of four were protected against virus replication. In contrast, inoculation of a third group of swine with an extract from E. coli expressing the same FMDV construct as present in the recombinant baculovirus failed to protect any of the four animals from generalized FMD.