Nucleic acid amplification assays for detection of La Crosse virus RNA.

We report the development of nucleic acid sequence-based amplification (NASBA) and quantitative real-time reverse transcription (RT)-PCR assays for the detection of La Crosse (LAC) virus in field-collected vector mosquito samples and human clinical samples. The sensitivities of these assays were compared to that of a standard plaque assay in Vero cells. The NASBA and quantitative real-time RT-PCR assays demonstrated sensitivities greater than that of the standard plaque assay. The specificities of these assays were determined by testing a battery of reference strain viruses, including representative strains of LAC virus and other arthropod-borne viruses. Additionally, these assays were used to detect LAC viral RNA in mosquito pool samples and human brain tissue samples and yielded results within less than 4 h. The NASBA and quantitative real-time RT-PCR assays detect LAC viral RNA in a sensitive, specific, and rapid manner; these findings support the use of these assays in surveillance and diagnostic laboratory systems.

Inhibition of dengue virus serotypes 1 to 4 in vero cell cultures with morpholino oligomers.

Five dengue (DEN) virus-specific R5F2R4 peptide-conjugated phosphorodiamidate morpholino oligomers (P4-PMOs) were evaluated for their ability to inhibit replication of DEN virus serotype 2 (DEN-2 virus) in mammalian cell culture. Initial growth curves of DEN-2 virus 16681 were obtained in Vero cells incubated with 20 microM P4-PMO compounds. At 6 days after infection, a P4-PMO targeting the 3'-terminal nucleotides of the DEN-2 virus genome and a random-sequence P4-PMO showed relatively little suppression of DEN-2 virus titer (0.1 and 0.9 log10, respectively). P4-PMOs targeting the AUG translation start site region of the single open reading frame and the 5' cyclization sequence region had moderate activity, generating 1.6- and 1.8-log10 reductions. Two P4-PMO compounds, 5'SL and 3'CS (targeting the 5'-terminal nucleotides and the 3' cyclization sequence region, respectively), were highly efficacious, each reducing the viral titer by greater than 5.7 log10 compared to controls at 6 days after infection with DEN-2 virus. Further experiments showed that 5'SL and 3'CS inhibited DEN-2 virus replication in a dose-dependent and sequence-specific manner. Treatment with 10 microM 3'CS reduced the titers of all four DEN virus serotypes, i.e., DEN-1 (strain 16007), DEN-2 (16681), DEN-3 (16562), and DEN-4 (1036) viruses by over 4 log10, in most cases to below detectable limits. The extent of 3'CS efficacy was affected by the timing of compound application in relation to viral infection of the cells. The 5'SL and 3'CS P4-PMOs did not suppress the replication of West Nile virus NY99 in Vero cells. These data indicate that further evaluation of the 5'SL and 3'CS compounds as potential DEN virus therapeutics is warranted.