HIV-1 T cell epitopes targeted to Rhesus macaque CD40 and DCIR: A comparative study of prototype dendritic cell targeting therapeutic vaccine candidates.

HIV-1 infection can be controlled by anti-retroviral drug therapy, but this is a lifetime treatment and the virus remains latent and rapidly rebounds if therapy is stopped. HIV-1-infected individuals under this drug regimen have increased rates of cancers, cardiovascular diseases, and autoimmunity due to compromised immunity. A therapeutic vaccine boosting cellular immunity against HIV-1 is therefore desirable and, possibly combined with other immune modulating agents, could obviate the need for long-term drug therapies. An approach to elicit strong T cell-based immunity is to direct virus protein antigens specifically to dendritic cells (DCs), which are the key cell type for controlling immune responses. For eliciting therapeutic cellular immunity in HIV-1-infected individuals, we developed vaccines comprised of five T cell epitope-rich regions of HIV-1 Gag, Nef, and Pol (HIV5pep) fused to monoclonal antibodies that bind either, the antigen presenting cell activating receptor CD40, or the endocytic dendritic cell immunoreceptor DCIR. The study aimed to demonstrate vaccine safety, establish efficacy for broad T cell responses in both primed and naïve settings, and identify one candidate vaccine for human therapeutic development. The vaccines were administered to Rhesus macaques by intradermal injection with poly-ICLC adjuvant. The animals were either i) naïve or, ii) previously primed with modified vaccinia Ankara vector (MVA) encoding HIV-1 Gag, Pol, and Nef (MVA GagPolNef). In the MVA-primed groups, both DC-targeting vaccinations boosted HIV5pep-specific blood CD4+ T cells producing multiple cytokines, but did not affect the MVA-elicited CD8+ T cell responses. In the naive groups, both DC-targeting vaccines elicited antigen-specific polyfunctional CD4+ and CD8+ T cell responses to multiple epitopes and these responses were unchanged by a subsequent MVA GagPolNef boost. In both settings, the T cell responses elicited via the CD40-targeting vaccine were more robust and were detectable in all the animals, favoring further development of the CD40-targeting vaccine for therapeutic vaccination of HIV-1-infected individuals.

Human MxA protein participates to the interferon-related inhibition of hepatitis B virus replication in female transgenic mice.

BACKGROUND/AIMS: The interferon (IFN) inducible MxA protein is endowed with antiviral activity against a broad range of RNA viruses. In a previous in vitro study, we demonstrated that MxA inhibits hepatitis B virus (HBV) replication, arguing that the antiviral activity of MxA is not restricted to RNA viruses but also includes a DNA virus. The aim of the present study was to further demonstrate in vivo the antiviral action of MxA against HBV. METHODS: We generated HBV and HBV/MxA transgenic mice lacking a functional IFN-alpha/beta receptor and thus constituting a good model to evaluate MxA-induced virus resistance. HBV proteins expression, viral load and HBV replication were compared in HBV and HBV/MxA mice. RESULTS: An MxA-dependent moderate inhibitory effect on HBV expression was only observed in female HBV/MxA mice, in which MxA downregulates (i) viral HBeAg and capsid protein expression, (ii) viremia and (iii) HBV replication by decreasing the synthesis of HBV DNA replicative intermediates. Furthermore, these effects were not associated with changes to steady-state levels of HBV RNAs. CONCLUSIONS: Our results show that in vivo, MxA is able per se to reduce HBV expression by a post-transcriptional mechanism, and thus participates in the antiviral activity of IFN-alpha against HBV.