Rapid and sustained CD4(+) T-cell-independent immunity from adenovirus-encoded vaccine antigens.

Many novel vaccine strategies rely on recombinant viral vectors for antigen delivery, and adenovirus vectors have emerged among the most potent of these. In this report, we have compared the immune response induced through priming with adenovirus vector-encoded full-length viral protein to that elicited with an adenovirus-encoded minimal epitope covalently linked to beta(2)-microglobulin. We demonstrate that the beta(2)-microglobulin-linked epitope induced an accelerated and augmented CD8(+) T-cell response. Furthermore, the immunity conferred by vaccination with beta(2)-microglobulin-linked lymphocytic choriomeningitis virus (LCMV)-derived epitopes was long-lived and protective. Notably, in contrast to full-length protein, the response elicited with the beta(2)-microglobulin-linked LCMV-derived epitope was CD4(+) T-cell independent. Furthermore, virus-specific CD8(+) T cells primed in the absence of CD4(+) T-cell help were sustained in the long term and able to expand and control a secondary challenge with LCMV. Our results demonstrate that modifications to the antigen used in adenovirus vaccines may be used to improve the induced T-cell response. Such a strategy for CD4(+) T-cell-independent immunity from adenovirus vectors offers prospects for vaccination against opportunistic pathogens in AIDS patients and possibly immunotherapy in chronic virus infections.

The virus-encoded chemokine vMIP-II inhibits virus-induced Tc1-driven inflammation.

The human herpesvirus 8-encoded protein vMIP-II is a potent in vitro antagonist of many chemokine receptors believed to be associated with attraction of T cells with a type 1 cytokine profile. For the present report we have studied the in vivo potential of this viral chemokine antagonist to inhibit virus-induced T-cell-mediated inflammation. This was done by use of the well-established model system murine lymphocytic choriomeningitis virus infection. Mice were infected in the footpad, and the induced CD8(+) T-cell-dependent inflammation was evaluated in mice subjected to treatment with vMIP-II. We found that inflammation was markedly inhibited in mice treated during the efferent phase of the antiviral immune response. In vitro studies revealed that vMIP-II inhibited chemokine-induced migration of activated CD8(+) T cells, but not T-cell-target cell contact, granule exocytosis, or cytokine release. Consistent with these in vitro findings treatment with vMIP-II inhibited the adoptive transfer of a virus-specific delayed-type hypersensitivity response in vivo, but only when antigen-primed donor cells were transferred via the intravenous route and required to migrate actively, not when the cells were injected directly into the test site. In contrast to the marked inhibition of the effector phase, the presence of vMIP-II during the afferent phase of the immune response did not result in significant suppression of virus-induced inflammation. Taken together, these results indicate that chemokine-induced signals are pivotal in directing antiviral effector cells toward virus-infected organ sites and that vMIP-II is a potent inhibitor of type 1 T-cell-mediated inflammation.