Targeting Highly Structured RNA by Cooperative Action of siRNAs and Helper Antisense Oligomers in Living Cells.

RNA target accessibility is one of the most important factors limiting the efficiency of RNA interference-mediated RNA degradation. However, targeting RNA viruses in their poorly accessible, highly structured regions can be advantageous because these regions are often conserved in sequence and thus less prone to viral escape. We developed an experimental strategy to attack highly structured RNA by means of pairs of specifically designed small interfering RNAs and helper antisense oligonucleotides using the 5' untranslated region (5'UTR) of coxsackievirus B3 as a model target. In the first step, sites accessible to hybridization of complementary oligonucleotides were identified using two mapping methods with random libraries of short DNA oligomers. Subsequently, the accessibility of the mapped regions for hybridization of longer DNA 16-mers was confirmed by an RNase H assay. Using criteria for the design of efficient small interfering RNAs (siRNA) and a secondary structure model of the viral 5'UTR, several DNA 19-mers were designed against partly double-stranded RNA regions. Target sites for DNA 19-mers were located opposite the sites which had been confirmed as accessible for hybridization. Three pairs of DNA 19-mers and the helper 2'-O-methyl-16-mers were able to effectively induce RNase H cleavage in vitro. For cellular assays, the DNA 19-mers were replaced by siRNAs, and the corresponding three pairs of siRNA-helper oligomer tools were found to target 5'UTR efficiently in a reporter construct in HeLa cells. Addition of the helper oligomer improved silencing capacity of the respective siRNA. We assume that the described procedure will generally be useful for designing of nucleic acid-based tools to silence highly structured RNA targets.

The structural and phylogenetic profile of the 3' terminus of coxsackievirus B3 negative strand.

In the replication process of RNA(+) viruses both the positive-strand template and the newly synthesized negative strand appear in a double-stranded form, RF. It has been shown for poliovirus that prior to the initiation of positive-strand synthesis, the 5'-terminus of the positive strand must adopt a cloverleaf structure. When that happens, the 3'-terminal region of the negative strand is released from the RF form and is able to form into its own defined structure. In order to determine the secondary structure of this region, a comprehensive approach consisting of experimental mapping methods, phylogenetic analysis and computer predictions was applied. Here we propose the first structural model of the 3'-terminal region of the coxsackievirus B3 (CV-B3) negative strand, approximately 450 nucleotides in length. The region folds into three highly defined structural domains, I'-III'. The most 3'-terminal part of this region is domain I', which folds into a cloverleaf structure similar to that found in the viral RNA strand of positive-polarity. Remarkably, this motif is conserved among all analyzed viral isolates of CV-B3 despite the observed sequence diversity. Several other conserved structural motifs within the 3'-terminal region of the viral negative strand were also identified. The structure of this region may be crucial for the replication complex assembly.