Molecular mechanisms of formalin-fixed cellular vaccine reactogenicity.

Local and systemic reactogenic responses to Q-VAX have prevented licensing of this vaccine outside of Australia. These reactogenic responses occur in previously sensitized individuals and have not been well defined at the cellular level, in part because many studies have been done in guinea pigs that have limited molecular tools. We previously characterized a mouse model of reactogenicity where local reaction sites showed an influx of CD8+ and IFNγ-expressing IL17a+ CD4+ T cells consistent with a Th1 delayed-type hypersensitivity. In this study, we determined, using depletion and adoptive transfer experiments, that both anti- antibodies and CD4+ T cells were essential for localized reactions at the site of vaccination. Furthermore, IFNγ depletion showed significant histological changes at the local reaction sites demonstrating the essential nature of this cytokine to reactogenicity. In addition to the cells and cytokines required for this response, we determined that whole cell vaccine (WCV) material remained at the site of vaccination for at least 26 weeks post-injection. Transmission electron microscopy (TEM) of these sites demonstrated intact rod-shaped bacteria at 2 weeks post-injection and partially degraded bacteria within macrophages at 26 weeks post-injection. Finally, because small cell variants (SCVs) are an environmentally stable form, we determined that local reactions were more severe when the WCV material was prepared with higher levels of SCVs compared to typical WCV or with higher levels of large cell variant (LCV). These studies support the hypothesis that antigen persistence at the site of injection contributes to this reactogenicity and that anti- antibodies, CD4+ T cells, and IFNγ each contribute to this process.