Mapping of immune responses following wild-type and mutant ABeta42 plasmid or peptide vaccination in different mouse haplotypes and HLA Class II transgenic mice.

Although the recent clinical trial of the ABeta42 peptide vaccine against Alzheimer's Disease (AD) has been halted due to adverse events, the apparent clinical utility of this approach underscores the need to further improve the safety of the vaccine, as well as to understand the potential immunological basis for complications. In this study, we examine both humoral and cellular immune responses elicited by immunization with peptide or DNA encoding wild-type and the Flemish and Dutch mutations of ABeta42 (i.e. the beta amyloid peptide spanning amino acids 1-42) in mice of different immune haplotypes as well as HLA Class II transgenic mice. The Flemish and Dutch mutations have been associated with cerebrovascular hemorrhages in affected individuals. These data allow determination of potential immunological responses that could mediate pathology observed with mutant forms of amyloid beta, as well as lead to the generation of safer vaccine preparations. Following peptide or plasmid immunization, antibody responses were measured against the different ABeta42 peptides in an ELISA assay, while T cell epitopes were analyzed through interferon gamma ELISPOT and lymphocyte proliferation assays. B cell mapping studies indicated that sera from all of the haplotype mice vaccinated with any of the ABeta42 peptides reacted specifically to the first 10 amino acids of ABeta42 with the ABeta42 mutants eliciting higher immune responses. ELISPOT analysis, which accessed cellular immune responses indicated that mice expressed differences in Class I epitopes dependent on the different immune haplotypes. These results may have implications for the design of future ABeta42 based vaccines against Alzheimer's Disease.

Coimmunization with an optimized IL-15 plasmid results in enhanced function and longevity of CD8 T cells that are partially independent of CD4 T cell help.

DNA vaccines are a promising technology for the induction of Ag-specific immune responses, and much recent attention has gone into improving their immune potency. In this study we test the feasibility of delivering a plasmid encoding IL-15 as a DNA vaccine adjuvant for the induction of improved Ag-specific CD8(+) T cellular immune responses. Because native IL-15 is poorly expressed, we used PCR-based strategies to develop an optimized construct that expresses 80-fold higher than the native IL-15 construct. Using a DNA vaccination model, we determined that immunization with optimized IL-15 in combination with HIV-1gag DNA constructs resulted in a significant enhancement of Ag-specific CD8(+) T cell proliferation and IFN-gamma secretion, and strong induction of long-lived CD8(+) T cell responses. In an influenza DNA vaccine model, coimmunization with plasmid expressing influenza A PR8/34 hemagglutinin with the optimized IL-15 plasmid generated improved long term CD8(+) T cellular immunity and protected the mice against a lethal mucosal challenge with influenza virus. Because we observed that IL-15 appeared to mostly adjuvant CD8(+) T cell function, we show that in the partial, but not total, absence of CD4(+) T cell help, plasmid-delivered IL-15 could restore CD8 secondary immune responses to an antigenic DNA plasmid, supporting the idea that the effects of IL-15 on CD8(+) T cell expansion require the presence of low levels of CD4 T cells. These data suggest a role for enhanced plasmid IL-15 as a candidate adjuvant for vaccine or immunotherapeutic studies.