The effects of thiophosphate substitutions on native siRNA gene silencing.

RNA mediated interference has emerged as a powerful tool in controlling gene expression in mammalian cells. We investigated the gene silencing properties of six thiophosphate substituted siRNAs (all based on a commercial luciferase medium silencer) compared to that of unmodified siRNA. We also examined the cytotoxicity and dose-response using several thiophosphate modified siRNAs with unmodified siRNA. Our results show that two thiophosphate siRNA sequences convert from medium to high silencers with the addition of four randomly placed thiophosphates. Both thiophosphate siRNAs have a statistically significant difference in luciferase gene silencing (5% and 6% activity) relative to the unmodified native medium silencer referred to as siRNA-2 (18% activity) and four other thiophosphate siRNAs that maintain their medium silencing capability. This indicates that specific thiophosphate substitutions may alter native siRNA function. Further, this shows that thiophosphate siRNAs with the same nucleotide sequence but with different sulfur modification positions have different silencing effects. Both the native siRNA and the thio siRNAs showed a concentration dependent relationship, i.e., with concentration increase, the luciferase gene silencing effect also increased. Confirming cytotoxicity experiments showed no significant changes when HeLa cells were treated with 10nM thiophosphate siRNAs over the course of several days. These results suggest that specific placement of thiophosphates could play an important role in the development of siRNAs as therapeutics by engineering in properties such as strength of binding, nuclease sensitivity, and ultimately efficacy.

Solution structure and antibody binding studies of the envelope protein domain III from the New York strain of West Nile virus.

The solution structure of domain III from the New York West Nile virus strain 385-99 (WN-rED3) has been determined by NMR methods. The West Nile domain III structure is a beta-barrel structure formed from seven anti-parallel beta-strands in two beta-sheets. One anti-parallel beta-sheet consists of beta-strands beta1 (Phe(299)-Asp(307)), beta2 (Val(313)-Tyr(319)), beta4 (Arg(354)-Leu(355)), and beta5 (Lys(370)-Glu(376)) arranged so that beta2 is flanked on either side by beta1 and beta5. The short beta4 flanks the end of the remaining side of beta5. The remaining anti-parallel beta-sheet is formed from strands beta3 (Ile(340)-Val(343)), beta6 (Gly(380)-Arg(388)), and beta7 (Gln(391)-Lys(399)) arranged with beta6 at the center. Residues implicated in antigenic differences between different West Nile virus strains (and other flaviviruses) and neutralization are located on the outer surface of the protein. Characterization of the binding of monoclonal antibodies to WN-rED3 mutants, which were identified through neutralization escape experiments, indicate that antibody neutralization directly correlates with binding affinities. These studies provide an insight into theoretical virus-receptor interaction points, structure of immunogenic determinants, and potential targets for antiviral agents against West Nile virus and highlight differences between West Nile virus and other flavivirus structures that may represent critical determinants of virulence.