Single-dose vaccine against tick-borne encephalitis.

Tick-borne encephalitis (TBE) virus is the most important human pathogen transmitted by ticks in Eurasia. Inactivated vaccines are available but require multiple doses and frequent boosters to induce and maintain immunity. Thus far, the goal of developing a safe, live attenuated vaccine effective after a single dose has remained elusive. Here we used a replication-defective (single-cycle) flavivirus platform, RepliVax, to generate a safe, single-dose TBE vaccine. Several RepliVax-TBE candidates attenuated by a deletion in the capsid gene were constructed using different flavivirus backbones containing the envelope genes of TBE virus. RepliVax-TBE based on a West Nile virus backbone (RV-WN/TBE) grew more efficiently in helper cells than candidates based on Langat E5, TBE, and yellow fever 17D backbones, and was found to be highly immunogenic and efficacious in mice. Live chimeric yellow fever 17D/TBE, Dengue 2/TBE, and Langat E5/TBE candidates were also constructed but were found to be underattenuated. RV-WN/TBE was demonstrated to be highly immunogenic in Rhesus macaques after a single dose, inducing a significantly more durable humoral immune response compared with three doses of a licensed, adjuvanted human inactivated vaccine. Its immunogenicity was not significantly affected by preexisting immunity against WN. Immunized monkeys were protected from a stringent surrogate challenge. These results support the identification of a single-cycle TBE vaccine with a superior product profile to existing inactivated vaccines, which could lead to improved vaccine coverage and control of the disease.

Characterization of the RepliVax platform for replication-defective flavivirus vaccines.

RepliVax, a novel replication-defective vaccine platform has recently been described as a suitable means of generating potent vaccines targeting flaviviruses. In this study, we directly compared attenuation, immunogenicity and efficacy of several prototype RepliVax constructs to available, well characterized live attenuated (LAV) and inactivated (INV) flavivirus vaccine controls in mice and hamsters. Other important aspects of general mechanisms and properties of RepliVax vaccines were also studied. The prototypes were found to be nonpathogenic in sensitive suckling mouse neurovirulence tests, and highly immunogenic and efficacious in mice and hamsters, with evidence that immunogenicity can be comparable to LAV controls in terms of both magnitude and durability of response. Our data also suggest that choice of inoculation route can be beneficial for maximizing RepliVax immunogenicity. Additionally, different vaccine constructs can be administered as cocktail formulations without compromising immunogenicity of individual components. RepliVax constructs were determined to induce a Th1 biased immune response, similar to LAVs, and different from INV inducing a Th2 type response. The results presented validate the utility of the RepliVax platform for development of novel flavivirus vaccines.