Evaluation of St. Louis encephalitis virus/dengue virus type 4 antigenic chimeric viruses in mice and rhesus monkeys.

To develop a live attenuated virus vaccine against St. Louis encephalitis (SLE) virus, two antigenic chimeric viruses were generated by replacing the membrane precursor and envelope protein genes of dengue virus type 4 (DEN4) with those from SLE with or without a 30 nucleotide deletion in the DEN4 3' untranslated region of the chimeric genome. Chimeric viruses were compared with parental wild-type SLE for level of neurovirulence and neuroinvasiveness in mice and for safety, immunogenicity, and protective efficacy in rhesus monkeys. The resulting viruses, SLE/DEN4 and SLE/DEN4Delta30, had greatly reduced neuroinvasiveness in immunodeficient mice but retained neurovirulence in suckling mice. Chimerization of SLE with DEN4 resulted in only moderate restriction in replication in rhesus monkeys, whereas the presence of the Delta30 mutation led to over-attenuation. Introduction of previously described attenuating paired charge-to-alanine mutations in the DEN4 NS5 protein of SLE/DEN4 reduced neurovirulence in mice and replication in rhesus monkeys. Two modified SLE/DEN4 viruses, SLE/DEN4-436,437 clone 41 and SLE/DEN4-654,655 clone 46, have significantly reduced neurovirulence in mice and conferred protective immunity in monkeys against SLE challenge. These viruses may be considered for use as SLE vaccine candidates and for use as diagnostic reagents with reduced virulence.

Dengue virus type 3 vaccine candidates generated by introduction of deletions in the 3' untranslated region (3'-UTR) or by exchange of the DENV-3 3'-UTR with that of DENV-4.

The dengue virus type 3 (DENV-3) vaccine candidate, rDEN3Delta30, was previously found to be under-attenuated in both SCID-HuH-7 mice and rhesus monkeys. Herein, two strategies have been employed to generate attenuated rDEN3 vaccine candidates which retain the full complement of structural and nonstructural proteins of DENV-3 and thus are able to induce humoral or cellular immunity to each of the DENV-3 proteins. First, using the predicted secondary structure of the 3' untranslated region (3'-UTR) of DENV-3 to design novel deletions, nine deletion mutant viruses were engineered and found to be viable. Four of nine deletion mutants replicated efficiently in Vero cells and were genetically stable. Second, chimeric rDENV-3 viruses were generated by replacement of the 3'-UTR of the rDENV-3 cDNA clone with that of rDENV-4 or rDEN4Delta30 yielding the rDEN3-3'D4 and rDEN3-3'D4Delta30 viruses, respectively. Immunization of rhesus monkeys with either of two deletion mutant viruses, rDEN3Delta30/31 and rDEN3Delta86, or with rDEN3-3'D4Delta30 resulted in infection without detectable viremia, with each virus inducing a strong neutralizing antibody response capable of conferring protection from DENV-3 challenge. The rDEN3Delta30/31 virus showed a strong host range restriction phenotype with complete loss of replication in C6/36 mosquito cells despite robust replication in Vero cells. In addition, rDEN3Delta30/31 had reduced replication in Toxorynchites mosquitoes following intrathoracic inoculation. The results are discussed in the context of vaccine development and the physical structure of the DENV 3'-UTR.

Vaccine candidates for dengue virus type 1 (DEN1) generated by replacement of the structural genes of rDEN4 and rDEN4Delta30 with those of DEN1.

BACKGROUND: Antigenic chimeric viruses have previously been generated in which the structural genes of recombinant dengue virus type 4 (rDEN4) have been replaced with those derived from DEN2 or DEN3. Two vaccine candidates were identified, rDEN2/4Delta30(ME) and rDEN3/4Delta30(ME), which contain the membrane (M) precursor and envelope (E) genes of DEN2 and DEN3, respectively, and a 30 nucleotide deletion (Delta30) in the 3' untranslated region of the DEN4 backbone. Based on the promising preclinical phenotypes of these viruses and the safety and immunogenicity of rDEN2/4Delta30(ME) in humans, we now describe the generation of a panel of four antigenic chimeric DEN4 viruses using either the capsid (C), M, and E (CME) or ME structural genes of DEN1 Puerto Rico/94 strain. RESULTS: Four antigenic chimeric viruses were generated and found to replicate efficiently in Vero cells: rDEN1/4(CME), rDEN1/4Delta30(CME), rDEN1/4(ME), and rDEN1/4Delta30(ME). With the exception of rDEN1/4(ME), each chimeric virus was significantly attenuated in a SCID-HuH-7 mouse xenograft model with a 25-fold or greater reduction in replication compared to wild type DEN1. In rhesus monkeys, only chimeric viruses with the Delta30 mutation appeared to be attenuated as measured by duration and magnitude of viremia. rDEN1/4Delta30(CME) appeared over-attenuated since it failed to induce detectable neutralizing antibody and did not confer protection from wild type DEN1 challenge. In contrast, rDEN1/4Delta30(ME) induced 66% seroconversion and protection from DEN1 challenge. Presence of the Delta30 mutation conferred a significant restriction in mosquito infectivity upon rDEN1/4Delta30(ME) which was shown to be non-infectious for Aedes aegypti fed an infectious bloodmeal. CONCLUSION: The attenuation phenotype in SCID-HuH-7 mice, rhesus monkeys, and mosquitoes and the protective immunity observed in rhesus monkeys suggest that rDEN1/4Delta30(ME) should be considered for evaluation in a clinical trial.