Sequence-Specific Suppression of mdr1a/1b Expression in Mice via RNA Interference

Abstract

RNA interference (RNAi) is a powerful tool for silencing gene expression posttranscriptionally. The purpose of this study was to examine whether in vivo RNAi can be induced against endogenous mdr1a/1b in adult mice and to assess the feasibility of generating P-glycoprotein (P-gp) knockdown mice based on RNAi by a very simple intravenous injection of synthetic small interfering RNA (siRNAs) or siRNA-expressing plasmid DNAs. The targeted sequences for silencing mdr1a specifically or mdr1a/1b simultaneously were examined in an in vitro study using a mouse colon carcinoma cell line, colon26 cells, in culture. Mice were repeatedly treated with intravenous synthetic siRNAs or siRNA-expressing plasmid DNAs in naked form administered via a large-volume and high-speed injection, i.e., the hydrodynamics-based procedure. The amount of targeted mRNA and P-gp in the liver were determined by real-time polymerase chain reaction and Western blot analysis, respectively. Among several targeted sequences, two and one optimized sequences were selected for mdr1a and mdr1a/1b, respectively, in the in vitro study. Following administration of synthetic siRNAs or siRNA-expressing plasmid DNAs directed against mdr1a, the mRNA level in the liver was significantly reduced to approximately 50-60% of that in control mice. Furthermore, a slight reduction was observed at the protein level. Similar results were obtained in the experiments using siRNA-expressing pDNA directed against mdr1a/1b. Our results demonstrate that sequence-specific suppression of mdr1 gene expression is possible at the mRNA level as well as the protein level in mice following intravenous delivery of siRNA effectors.