Optimization of linear double-stranded RNA for the production of multiple siRNAs targeting hepatitis C virus

RNA interference (RNAi)-based gene silencing possesses great therapeutic potential for inhibiting replication of human viruses such as hepatitis C virus (HCV). However, one of the putative limitations for its use as a therapy is the rapid emergence of escape variants. These contain deletions or mutations within the viral genome sequences complementary to the small interfering RNAs (siRNAs) or short hairpin RNAs (shRNAs) being used for treatment. As a potential solution to this problem, we constructed an expression system for duplex RNAs harboring two siRNA units using convergent H1 and U6 Pol III promoters. Here, the length and orientation of the transcript, tandem siRNA (tsiRNA), were optimized to be processed by the intracellular ribonuclease Dicer into functional siRNAs targeting different sequences. Assessment in transfected cells indicates that the length of the tsiRNA duplex (40–42 base pairs) is more critical for both siRNA-producing capacity and gene silencing activity than the orientation of each siRNA unit. In Huh7 cells replicating full-length HCV RNA, expression of length-optimized tsiRNA inhibited viral protein levels as efficiently as a single 21-nucleotide siRNA-expression construct, without affecting miRNA maturation or induction of an interferon response. We verified that the anti-viral activity of tsiRNA was achieved by precise cleavage of two target sites. A distinct advantage of this strategy is that each side of the optimized linear duplex RNA could enter into the Dicer-mediated processing machinery, thus likely providing more equal and efficient production of multiple siRNAs required for reducing the chance of viral escape