Lower levels of gamma interferon expressed by a pseudotyped single-cycle simian immunodeficiency virus enhance immunogenicity in rats.

A vaccine for human immunodeficiency virus (HIV) infection is desperately needed to control the AIDS pandemic. To address this problem, we constructed single-cycle simian immunodeficiency viruses (SIVs) pseudotyped with the glycoprotein of vesicular stomatitis virus and expressing different levels of gamma interferon (IFN-gamma) as a potential vaccine strategy. We previously showed that IFN-gamma expression by pseudotyped SIVs does not alter viral single-cycle infectivity. T cells primed with dendritic cells transduced by pseudotyped SIVs expressing high levels of IFN-gamma had stronger T-cell responses than those primed with dendritic cells transduced by constructs lacking IFN-gamma. In the present study, we tested the immunogenicities of these pseudotyped SIVs in a rat model. The construct expressing low levels of rat IFN-gamma (dSIV(LRgamma)) induced higher levels of cell-mediated and humoral immune responses than the construct lacking IFN-gamma (dSIV(R)). Rats vaccinated with dSIV(LRgamma) also had lower viral loads than those vaccinated with dSIV(R) when inoculated with a recombinant vaccinia virus expressing SIV Gag-Pol as a surrogate challenge. The construct expressing high levels of IFN-gamma (dSIV(HRgamma)) did not further enhance immunity and was less protective than dSIV(LRgamma). In conclusion, the data indicated that IFN-gamma functioned as an adjuvant to augment antigen-specific immune responses in a dose- and cell type-related manner in vivo. Thus, fine-tuning of the cytokine expression appears to be essential in designing vaccine vectors expressing adjuvant genes such as the gene for IFN-gamma. Furthermore, we provide evidence of the utility of the rat model to evaluate the immunogenicities of single-cycle HIV/SIV recombinant vaccines before initiating studies with nonhuman primate models.