The efficacy of inactivated West Nile vaccine (WN-VAX) in mice and monkeys.

BACKGROUND: West Nile virus (WNV) belonging to the genus Flavivirus of the family Flaviviridae causes nervous system disorder in humans, horses and birds. Licensed WNV vaccines are available for use in horses but not for humans. We previously developed an inactivated West Nile virus vaccine (WN-VAX) using a seed virus from West Nile virus (WNV NY99) that was originally isolated in New York City in 1999. In this study, we report the immunogenicity of WN-VAX in both mice and non-human primates. FINDINGS: The WN-VAX immunized mice showed protection against lethal infection with WNV NY99. The challenge test performed on mice passively immunized with serum from other mice that were previously immunized with WN-VAX confirmed that the neutralizing antibody titers of more than 1log10 protected the passively immunized mice from WNV lethal infection. Furthermore, monkeys (Macaca fascicularis) immunized three times with 2.5 µg, 5 µg or 10 µg/dose of WN-VAX exhibited neutralizing antibodies in their sera with titers of more than 2log10 after the second immunization. CONCLUSIONS: The WN-VAX was protective in mice both by active and passive immunizations and was immunogenic in monkeys. These results suggest that the vaccine developed in this study may be a potential WNV vaccine candidate for human use.

Superior immunogenicity of a freeze-dried, cell culture-derived Japanese encephalitis vaccine (inactivated).

Japanese encephalitis is an infectious disease caused by the Japanese encephalitis virus, which is widespread throughout Asia. The worldwide incidence is 50,000 cases per year. There is no specific treatment available, but inactivated mouse brain-derived vaccine was used from the 1950s to prevent infection. However, quality control of mouse brain-derived vaccines is difficult, and therefore a new freeze-dried, cell culture-derived Japanese encephalitis vaccine (inactivated) (JEBIK V; development code: BK-VJE) was developed. In this paper, we report an analysis of neutralizing antibody titers in vaccinated subjects enrolled in clinical study of BK-VJE at various doses, and study of BK-VJE with the mouse brain-derived vaccine as a control. The results show that BK-VJE has superior immunogenicity compared to mouse brain-derived vaccine.

Development and evaluation of a formalin-inactivated West Nile Virus vaccine (WN-VAX) for a human vaccine candidate.

A formalin-inactivated West Nile Virus (WNV) vaccine (WN-VAX) derived from the WNV-NY99 strain was tested for its safety, efficacy, dilution limit for complete protection, and cross-neutralization. Safety tests performed with experimental animals, bacteria, or cultured cell lines showed no evidence of short- or long-term adverse effects. WN-VAX also protected 100% of 4-week-old mice against a lethal challenge from the WNV-NY99 strain after two doses of intraperitoneal inoculation-even when the vaccine was diluted to 3.2ng/dose. Moreover, very limited cross-neutralization activity against Japanese encephalitis virus, Dengue virus, Murray Valley encephalitis virus, Yellow fever virus or St. Louis encephalitis virus was observed. Therefore, the WN-VAX satisfies the requirements for human trials planned to be done in Japan.

DNA sequence analysis of varicella-zoster virus gene 62 from subclinical infections in healthy children immunized with the Oka varicella vaccine.

A live attenuated varicella vaccine, the Oka vaccine strain (vOka), is routinely administered to children in Japan and other countries, including the United States. vOka consists of a mixture of genotypically distinct variants, but little is known about the growth potential of each variants in vivo. We isolated varicella-zoster virus (VZV) DNA sequences from the peripheral blood mononuclear cells (PBMCs) of asymptomatic healthy children immunized with the Oka varicella vaccine. VZV gene 62 DNA fragments were detected in 5 of 166 (3.0%) PBMC samples by nested PCR within 5 weeks of the vaccination. Sequence analysis of VZV DNA from these five PBMC samples indicated that multiple viral clones in the vaccine could infect vaccinees and replicate in vivo. We also provide evidence that a nonsynonymous substitution at position 105356 may affect viral replication in vivo.

Molecular characterization of attenuated Japanese encephalitis live vaccine strain ML-17.

The Japanese encephalitis (JE) zoonotic vaccine strain ML-17 was sequenced and compared to related JE virus strains to identify genomic attenuation markers. Relative to its parental strain, JaOH0566, 25 nucleotide alterations and 10 amino acid changes to, prM/M(2), NS2A(1), NS4B(3) and NS5(4) proteins were recorded. Both structural-gene changes were in the prM/M region (127Met-->Ile and 274Asn-->Thr). To study the effects of these prM/M changes, mutants bearing the changes were prepared using an infectious clone of JaOArS982 previously established at this lab. Compared with JaOArS982, mutant 127(Met-->Ile) showed marked reduction in murine neuroinvasiveness. Mutant 274(Asn-->Thr), showed slight reduction. Neither mutant recorded ML-17-equivalent attenuation, implying that prM/M changes need to combine with other recorded genomic differences to cause attenuation. Importantly, ML-17 with its unchanged E region, presents a possible backbone candidate for preparation of "E-replacement" type live attenuated flavivirus chimeric vaccines.

Estimation of the neuraminidase content of influenza viruses and split-product vaccines by immunochromatography.

The neuraminidase (NA) of the influenza virus, as well as the hemagglutinin, is the most important protective components in the vaccine. However, the NA content of the vaccine remains to be standardized because of the labile nature of this glycoprotein during various chemical treatments and storage. In the present study, the NA content of the split-product (SP) vaccine (virus treated with ether then formalin) was estimated together with that of the virus by an immunochoromatography technique using monoclonal antibodies (mAbs) to viral NA for A/Panama/2007/99 (A/Pa) (H3N2), B/Shangdong/7/97 (B/S) or A/New Caledonia/20/99 (A/NC) (H1N1) viral strains. In the new method, the NA catalytic activity of each fraction from steps of NA purification was measured as an index of NA content. The NA level of A/Pa, B/S or A/NC viral particles was estimated at 6.9+/-0.9, 7.6+/-0.8 or 8.5+/-1.7% of total viral protein (not significant difference between viral strains). The NA level of the corresponding A/Pa, B/S or A/NC vaccines was estimated at 9.6+/-1.5, 12.7+/-0.4 or 12.2+/-1.2% of the total vaccine protein (a significant difference between each strain of virus and its vaccine). These results suggest that the NA content in the N1, N2 or B type NA virus ranges from 5 to 11% of the total viral protein, and that the NA level in each split-product vaccine is 1.4- to 1.6-fold higher than that in the corresponding viral particles. They also suggest that the NA content can be estimated by the immunochoromatography technique using anti-viral NA mAbs.