Self-Amplifying RNA Vaccines for Venezuelan Equine Encephalitis Virus Induce Robust Protective Immunogenicity in Mice.

Venezuelan equine encephalitis virus (VEEV) is a known biological defense threat. A live-attenuated investigational vaccine, TC-83, is available, but it has a high non-response rate and can also cause severe reactogenicity. We generated two novel VEE vaccine candidates using self-amplifying mRNA (SAM). LAV-CNE is a live-attenuated VEE SAM vaccine formulated with synthetic cationic nanoemulsion (CNE) and carrying the RNA genome of TC-83. IAV-CNE is an irreversibly-attenuated VEE SAM vaccine formulated with CNE, delivering a TC-83 genome lacking the capsid gene. LAV-CNE launches a TC-83 infection cycle in vaccinated subjects but eliminates the need for live-attenuated vaccine production and potentially reduces manufacturing time and complexity. IAV-CNE produces a single cycle of RNA amplification and antigen expression without generating infectious viruses in subjects, thereby creating a potentially safer alternative to live-attenuated vaccine. Here, we demonstrated that mice vaccinated with LAV-CNE elicited immune responses similar to those of TC-83, providing 100% protection against aerosol VEEV challenge. IAV-CNE was also immunogenic, resulting in significant protection against VEEV challenge. These studies demonstrate the proof of concept for using the SAM platform to streamline the development of effective attenuated vaccines against VEEV and closely related alphavirus pathogens such as western and eastern equine encephalitis and Chikungunya viruses.

A DNA vaccine for Crimean-Congo hemorrhagic fever protects against disease and death in two lethal mouse models.

Crimean-Congo hemorrhagic fever virus (CCHFV) is a tick-borne virus capable of causing a severe hemorrhagic fever disease in humans. There are currently no licensed vaccines to prevent CCHFV-associated disease. We developed a DNA vaccine expressing the M-segment glycoprotein precursor gene of CCHFV and assessed its immunogenicity and protective efficacy in two lethal mouse models of disease: type I interferon receptor knockout (IFNAR-/-) mice; and a novel transiently immune suppressed (IS) mouse model. Vaccination of mice by muscle electroporation of the M-segment DNA vaccine elicited strong antigen-specific humoral immune responses with neutralizing titers after three vaccinations in both IFNAR-/- and IS mouse models. To compare the protective efficacy of the vaccine in the two models, groups of vaccinated mice (7-10 per group) were intraperitoneally (IP) challenged with a lethal dose of CCHFV strain IbAr 10200. Weight loss was markedly reduced in CCHFV DNA-vaccinated mice as compared to controls. Furthermore, whereas all vector-control vaccinated mice succumbed to disease by day 5, the DNA vaccine protected >60% of the animals from lethal disease. Mice from both models developed comparable levels of antibodies, but the IS mice had a more balanced Th1/Th2 response to vaccination. There were no statistical differences in the protective efficacies of the vaccine in the two models. Our results provide the first comparison of these two mouse models for assessing a vaccine against CCHFV and offer supportive data indicating that a DNA vaccine expressing the glycoprotein genes of CCHFV elicits protective immunity against CCHFV.