Modifying the HIV-1 env gp160 gene to improve pDNA vaccine-elicited cell-mediated immune responses.

Plasmid DNA (pDNA) vaccines are effective at eliciting immune responses in a wide variety of animal model systems, however, pDNA vaccines have generally been incapable of inducing robust immune responses in clinical trials. Therefore, to identify means to improve pDNA vaccine performance, we compared various post-transcriptional and post-translational genetic modifications for their ability to improve antigen-specific CMI responses. Mice vaccinated using a sub-optimal 100 mcg dose of a pDNA encoding an unmodified primary isolate HIV-1(6101) env gp160 failed to demonstrate measurable env-specific CMI responses. In contrast, significant env-specific CMI responses were seen in mice immunized with pDNA expression vectors encoding env genes modified by RNA optimization or codon optimization. Further modification of the RNA optimized env gp160 gene by the addition of (i) a simian retrovirus type 1 constitutive RNA transport element; (ii) a murine intracisternal A-particle derived RNA transport element; (iii) a tissue plasminogen activator protein signal leader sequences; (iv) a beta-catenin derived ubiquitination target sequence; or (v) a monocyte chemotactic protein-3 derived signal sequence failed to further improve the induction of env-specific CMI responses. Therefore, modification of the env gp160 gene by RNA or codon optimization alone is necessary for high-level rev-independent expression and results in robust env-specific CMI responses in immunized mice. Importantly, further modification(s) of the env gene to alter cellular localization or increase proteolytic processing failed to result in increased env-specific immune responses. These results have important implications for the design and development of an efficacious vaccine for the prevention of HIV-1 infection.

A dose sparing effect by plasmid encoded IL-12 adjuvant on a SIVgag-plasmid DNA vaccine in rhesus macaques.

An experimental pDNA vaccine adjuvant expressing IL-12 was evaluated for its ability to augment the humoral and cellular immune responses elicited by a SIVmac239 gag p39 expressing pDNA vaccine. To determine the effect of vaccine dose on the immune response, rhesus macaques were immunized with 1.5 mg or 5.0 mg of SIVmac239 gag pDNA, with or without co-immunization of IL-12 pDNA at 1.5 mg and 5.0 mg, respectively. Serum antibody responses to simian immunodeficiency virus (SIV) gag were increased 10-fold (p=0.044, 0.002) in macaques receiving IL-12 pDNA. Cellular immune responses, monitored by SIV gag-specific IFN-gamma ELISpot assay, were also significantly higher (p=0.007, 0.019) when the pDNA vaccine was co-immunized with IL-12 pDNA at high and low doses. There was no statistical difference between the immune responses elicited by the high and low dose of IL-12 pDNA (p=0.221, 0.917), a finding which could allow a dose reduction of vaccine without the concomitant loss of imunogenicity. Furthermore, analysis of the breadth of the T-cell response during the vaccination schedule, using overlapping peptides to SIV gag, demonstrated a significant correlation (p=0.0002) between the magnitude and breadth of the immune responses in the vaccines. These results have important implications for the continuing development of an effective, safe low dose pDNA vaccine adjuvant suitable for human use.

Comparison of antibody titers after immunization with monovalent or tetravalent KLH conjugate vaccines.

Antigens such as ganglioside GD3, neutral glycolipid Lewis(y) (Le(y)) and mucins MUC1 and MUC2 are over-expressed on the cell surface of many tumors. We have shown previously that conjugation of antigens such as these to keyhole limpet hemocyanin (KLH) and the use of immunological adjuvant QS-21 is the optimal approach for inducing high titer IgM and IgG antibodies. These antibodies are able to bind with natural antigens on the tumor cell surface and mediate complement dependent cytotoxicity and/or antibody dependent cell mediated cytotoxicity. Immunization of patients with monovalent vaccines containing these and a variety of other antigens have demonstrated both the consistent immunogenicity and the safety of these vaccines. Now, in preparation for the use of polyvalent conjugate vaccines in the clinic, we have addressed for the first time with conjugate vaccines against cancer antigens several questions in the pre-clinical setting, including whether immunogenicity of the individual components is decreased in the polyvalent vaccine and issues relating to vaccine formulation and administration. We have immunized groups of mice with GD3-KLH, Le(y)-KLH, MUC1-KLH and MUC2-KLH conjugates and QS-21 separately or mixed and administered at one or four sites. High titer IgM and IgG antibodies were induced against each of the four antigens whether administered singly in separate mice, at separate sites in the same mice, or mixed and administered at a single site or at four sites, or administered subcutaneously (s.c.) or intraperitoneally (i.p.). These antibodies reacted specifically with the respective antigens and tumor cells expressing these antigens. There was no evidence of suppression of the antibody response against any one of the antigens by the presence of the other conjugates in the vaccine. Immunogenicity of the four individual antigens conjugated to KLH and QS-21 is not affected by mixing the four together and administering them at a single subcutaneous site.