Attenuation of a vaccine strain of vaccinia virus via inactivation of interferon viroceptor.

BACKGROUND: Interferons (IFNs) play an important role in host antiviral responses, but viruses, including vaccinia viruses (VV), employ mechanisms to disrupt IFN activities, and these viral mechanisms are often associated with their virulence. Here, we explore an attenuation strategy with a vaccine strain of VV lacking a virus-encoded IFN-gamma receptor homolog (viroceptor). METHODS: To facilitate the monitoring of virus properties, first we constructed a Lister vaccine strain derivative VV-RG expressing optical reporters. Further, we constructed a VV-RG derivative, VV-RG8, which lacks the IFN-gammaR viroceptor (B8R gene product). Replication, immunological and pathogenic properties of the constructed strains were compared. RESULTS: Viruses did not show significant differences in humoral and cellular immune responses of immune-competent mice. Replication of constructed viruses was efficient both in vitro and in vivo, but showed marked difference in kinetics of propagation. In cultured CV-1 epithelial cells, the VV-RG8 strain retained the propagation potential of the parental virus, while, in the C6 glial cells, significant delay was observed in the kinetics of the VV-RG8 replication cycle compared to VV-RG. The pathogenesis of the viruses was tested by survival assay and biodistribution in nude mice. High dose inoculation of nude mice with VV-RG8 caused less pronounced virus dissemination, improved weight gain, and increased survival rate, as compared with the VV-RG strain. CONCLUSIONS: The replication-competent virus VV-RG8 carrying a mutation at the B8R gene is less pathogenic for mice than the parental vaccine virus. We anticipate that step-wise inactivation of VV vaccine genes involved in evasion of host immune response may provide an alternative approach for generation of hyper-attenuated replication-competent vaccines.

Suppression of hyperglycemia in NOD mice after inoculation with recombinant vaccinia viruses.

In autoimmune (type 1) diabetes, autoreactive lymphocytes destroy pancreatic beta-cells responsible for insulin synthesis. To assess the feasibility of gene therapy for type 1 diabetes, recombinant vaccinia virus (rVV) vectors were constructed expressing pancreatic islet autoantigens proinsulin (INS) and a 55-kDa immunogenic peptide from glutamic acid decarboxylase (GAD), and the immunomodulatory cytokine interleukin (IL)-10. To augment the beneficial effects of recombinant virus therapy, the INS and GAD genes were fused to the C terminus of the cholera toxin B subunit (CTB). Five-week-old non-obese diabetic (NOD) mice were injected once with rVV. Humoral antibody immune responses and hyperglycemia in the infected mice were analyzed. Only 20% of the mice inoculated with rVV expressing the CTB::INS fusion protein developed hyperglycemia, in comparison to 70% of the mice in the uninoculated animal group. Islets from pancreatic tissues isolated from euglycemic mice from this animal group showed no sign of inflammatory lymphocyte invasion. Inoculation with rVV producing CTB::GAD or IL-10 was somewhat less effective in reducing diabetes. Humoral antibody isotypes of hyperglycemic and euglycemic mice from all treated groups possessed similar IgG1/IgG2c antibody titer ratios from 19 to 32 wk after virus inoculation. In comparison with uninoculated mice, 11-wk-old NOD mice injected with virus expressing CTB::INS were delayed in diabetes onset by more than 4 wk. The experimental results demonstrate the feasibility of using rVV expressing CTB::INS fusion protein to generate significant protection and therapy against type 1 diabetes onset and progression.