Selecting effective siRNAs based on guide RNA structure.

In RNA interference, guide RNAs direct RNA-induced silencing complexes to mRNA targets, mediating cleavage and ultimately leading to gene silencing. We have observed that unstructured guide strands, which either completely lack complementary bases or in which internal base pairing is thermodynamically unlikely, confer strongest silencing, whereas structures with base-paired ends are inactive. Thus, the structure of the guide strand represents a major determinant of small interfering RNA activity. Here we describe a detailed computational protocol for identification of unstructured guide strands for a given mRNA target sequence. Sequentially, all guide sequences with target complementarity are simulated, their corresponding structures are folded and unstructured guide strands are selected and rated according to thermodynamic parameters. Although this procedure is new and remains to be validated by the community, it allows reliable identification of highly active siRNAs that can be used for functional target validation or drug development.

Design of siRNAs producing unstructured guide-RNAs results in improved RNA interference efficiency.

In RNA interference (RNAi), guide RNAs direct RNA-induced silencing complexes (RISC) to their mRNA targets, thus enabling the cleavage that leads to gene silencing. We describe a strong inverse correlation between the degree of guide-RNA secondary structure formation and gene silencing by small interfering (si)RNA. Unstructured guide strands mediate the strongest silencing whereas structures with base-paired ends are inactive. Thus, the availability of terminal nucleotides within guide structures determines the strength of silencing. A to G and C to U base exchanges, which involve wobble base-pairing with the target but preserve complementarity, turned inactive into active guide structures, thereby expanding the space of functional siRNAs. Previously observed base degenerations among mature micro (mi)RNAs together with the data presented here suggest a crucial role of the guide-RNA structures in miRNA action. The analysis of the effect of the secondary structures of guide-RNA sequences on RNAi efficiency provides a basis for better understanding RNA silencing pathways and improving the design of siRNAs.