E3L and F1L Gene Functions Modulate the Protective Capacity of Modified Vaccinia Virus Ankara Immunization in Murine Model of Human Smallpox.

The highly attenuated Modified Vaccinia virus Ankara (MVA) lacks most of the known vaccinia virus (VACV) virulence and immune evasion genes. Today MVA can serve as a safety-tested next-generation smallpox vaccine. Yet, we still need to learn about regulatory gene functions preserved in the MVA genome, such as the apoptosis inhibitor genes F1L and E3L. Here, we tested MVA vaccine preparations on the basis of the deletion mutant viruses MVA-ΔF1L and MVA-ΔE3L for efficacy against ectromelia virus (ECTV) challenge infections in mice. In non-permissive human tissue culture the MVA deletion mutant viruses produced reduced levels of the VACV envelope antigen B5. Upon mousepox challenge at three weeks after vaccination, MVA-ΔF1L and MVA-ΔE3L exhibited reduced protective capacity in comparison to wildtype MVA. Surprisingly, however, all vaccines proved equally protective against a lethal ECTV infection at two days after vaccination. Accordingly, the deletion mutant MVA vaccines induced high levels of virus-specific CD8+ T cells previously shown to be essential for rapidly protective MVA vaccination. These results suggest that inactivation of the anti-apoptotic genes F1L or E3L modulates the protective capacity of MVA vaccination most likely through the induction of distinct orthopoxvirus specific immunity in the absence of these viral regulatory proteins.

Concomitant type I IFN receptor-triggering of T cells and of DC is required to promote maximal modified vaccinia virus Ankara-induced T-cell expansion.

Virus-induced expansion of CD8(+) T cells may be promoted by type I IFN receptor (IFNAR)-triggering of T cells, depending on the pathogen tested. We studied modified vaccinia virus Ankara (MVA), a promising vaccine vector candidate, which was derived from conventional vaccinia virus (VACV) by more than 570 consecutive in vitro passages. In adoptive transfer experiments, we verified that VACV expressing the gp33 epitope of lymphocytic choriomeningitis virus (VACV(gp33)) induced largely IFNAR-independent expansion of gp33-specific T cells. On the contrary, MVA(gp33)-induced T-cell expansion was IFNAR dependent. Interestingly, under the latter conditions, T-cell activation was IFNAR independent, whereas T-cell apoptosis was enhanced in the absence of IFNAR. To address whether MVA-induced T-cell expansion was solely affected by IFNAR-triggering of T cells, expansion of endogenous T cells was studied in conditional mice with a T-cell- or DC-specific IFNAR deletion. Interestingly, both mouse strains showed moderately reduced T-cell expansion, whereas mice with a combined T-cell- and DC-specific IFNAR ablation showed massively reduced T-cell expansion similar to that of IFNAR(-/-) mice. These results are compatible with the model that IFN-inducing viruses such as MVA confer virus-specific CD8(+) T-cell expansion by concomitant IFNAR-triggering of DC and of T cells.

Vaccinia virus double-stranded RNA-binding protein E3 does not interfere with siRNA-mediated gene silencing in mammalian cells.

Vaccinia virus (VACV) evolved several strategies to evade antiviral cellular defence. The vaccinia virus E3 protein for example binds and sequesters double stranded RNA (dsRNA) and counteracts interferon action. We were interested to find out whether and to what extend E3 interferes with RNA silencing mediated by short interfering RNA (siRNA) in mammalian cells. We could show that the expression of a VACV-encoded marker gene can be efficiently inhibited by siRNA independently of the presence of the E3 protein. In addition, expression of E3 had no impact on RNA polymerase III promoter-derived shRNA-induced silencing of a cellular gene in human cells. Both VACV early and late gene expression could be inhibited by siRNA. Furthermore, downregulation of the expression of the E3L gene itself by siRNA in VACV infected cells produced the previously described phenotype of a knock-out virus, which illustrates the power of siRNA for vaccinia virus gene function analysis.