Adenovirus-vectored Plasmodium vivax ookinete surface protein, Pvs25, as a potential transmission-blocking vaccine.

Adjuvants or delivery vehicles are essential components to expedite malaria vaccine development. In this study, replication-defective human adenovirus serotype 5 (rAd) was genetically engineered to express the Plasmodium vivax ookinete surface protein (OSP), Pvs25 (AdPvs25). BALB/c mice immunized with the AdPvs25 through various routes including intramuscular, subcutaneous and intranasal routes were analyzed for induction of antigen-specific transmission-blocking immunity. Parenteral but not mucosal immunization induced high serum immunoglobulin G (IgG) responses specific to P. vivax ookinetes isolated from P. vivax volunteer patients from Thailand. The membrane feeding assay revealed that antisera conferred a transmission blockade of up to 99% reduction in the average oocyst numbers per mosquito, while immunization with a rAd expressing Pfs25 from Plasmodium falciparum, a homolog of Pvs25, conferred only a background level of blockade, suggesting that a species-specific transmission-blocking immunity was induced. Vaccine efficacy of AdPvs25 was slightly higher than to a recombinant Pvs25 protein mixed with aluminum hydroxide, but less efficacious than the protein emulsified with incomplete Freund's adjuvant. This study, the first preclinical evaluation of adenovirus-vectored malaria OSPs, implicates a potential inclusion of malaria transmission-blocking vaccine antigens in viral vector systems.

Heteropentameric cholera toxin B subunit chimeric molecules genetically fused to a vaccine antigen induce systemic and mucosal immune responses: a potential new strategy to target recombinant vaccine antigens to mucosal immune systems.

Noninvasive mucosal vaccines are attractive alternatives to parenteral vaccines. Although the conjugation of vaccine antigens with the B subunit of cholera toxin (CTB) is one of the most promising strategies for vaccine delivery to mucosal immune systems, the molecule cannot tolerate large-protein fusion, as it severely impairs pentamerization and loses affinity for GM1-ganglioside. Here we report a new strategy, in which steric hindrance between CTB-antigen fusion subunits is significantly reduced through the integration of unfused CTB "molecular buffers" into the pentamer unit, making them more efficiently self-assemble into biologically active pentamers. In addition, the chimeric protein took a compact configuration, becoming small enough to be secreted, and one-step affinity-purified proteins, when administered through a mucosal route, induced specific immune responses in mice. Since our results are not dependent on the use of a particular expression system or vaccine antigen, this strategy could be broadly applicable to bacterial enterotoxin-based vaccine design.

Adenovirus-mediated gene transfer of triple human complement regulating proteins (DAF, MCP and CD59) in the xenogeneic porcine-to-human transplantation model. Part II: xenogeneic perfusion of the porcine liver in vivo.

In this study, the adenovirus-mediated gene transfer of triple human complement regulating proteins was investigated in xenogeneic pig liver perfusion. The porcine liver was perfused in situ at 4 degrees C under a pump-driven veno-venous shunt of the portal vein and inferior vena cava, with 5 to 15x10(11) plaque-forming units (pfu) of adenovirus vector (group 1: AxCALacZ; 2: AxCACD59; 3: AxCACD59 + AxCADAF; 4: AxCACD59 + AxCADAF + AxCAMCP) for 1 h (for each, n=3). The livers were harvested 24 h after gene transfer and then were reperfused ex-vivo with fresh human blood for 2 h. In immunohistochemical staining, each complement regulating protein (CRP) showed a distribution similar to that of the LacZ expression. The C3 levels in the perfusate were also maintained at higher levels in group 4 from 60 to 120 min after reperfusion (C3: 85% to 95% of the initial level) than in groups 1 to 3 (C3: 80% to 90% of the initial level) from 60 to 120 min after reperfusion. The complement deposition on the porcine liver [C3, membrane attack component (MAC)] decreased significantly more in group 4 than in groups 1 to 3. In conclusion, the adenovirus-mediated multiple gene transfer of human CRPs (hCRPs) was found to effectively suppress the complement activation in xenogeneic pig liver perfusion.

Adenovirus-mediated gene transfer of triple human complement regulating proteins (DAF, MCP and CD59) in the xenogeneic porcine-to-human transplantation model. Part I: in vitro assays using porcine aortic endothelial cells.

We assessed whether the adenovirus-mediated gene transfer of triple human complement regulating proteins (hCRPs) to the porcine aortic endothelium (PAE), could possibly exert a synergistic effect to inhibit human complement activation. Adenovirus vectors, encoding E.Coli beta-galactosidase (AxCALacZ), human membrane cofactor protein (MCP) (AxCAMCP), decay-accelerating factor (DAF) (AxCADAF), and CD59 (AxCACD59) were produced by the COS-TPC method. AxCALacZ was transfected to porcine aortic endothelium cells (PAECs) under various multiplicities of infection (MOI) to determine the efficiency of adenovirus-mediated gene transfer by 5-bromo-4-chloro-3-indolyl beta- D-galactopyranoside (X-gal) staining. The mRNA expressions of transfected CRPs were examined by reverse transcriptase-polymerase chain reaction (RT-PCR). Cellular damage to the PAEC was assessed by an MTT assay. PAEC was most efficiently transfected with the LacZ gene at 10(3) MOI/60-min incubation time (89.1%). In all samples transfected with the CRP gene, the corresponding mRNAs were detected in the RT-PCR. In the MTT assay, PAECs co-cultured with 20% human serum, showed the highest cellular viability after gene transfer of triple CRPs (117.7%), when compared with those of marker LacZ, single or double CRPs. The adenovirus-mediated multiple gene transfer of CRPs may thus be an efficient method for suppressing complement activation in the porcine-to-human model of hyperacute rejection.