Key determinants of siRNA delivery mediated by unique pH-responsive lipid-based liposomes

Lipid-based nanoparticles, a potential nonviral vector due to their good biocompatibility and biodegradability, have been extensively developed for the delivery of small interfering RNA (siRNA). We designed a unique pH-responsive lipid derivative, a dioleylphosphate-diethylenetriamine conjugate (DOP-DETA). DOP-DETA consists of a pH-responsive triamine and unsaturated fatty acids that accelerate membrane fusion. Our results showed that DOP-DETA-based liposomes (DL) efficiently delivered siRNA into the cytoplasm and induced RNA interference even at a low siRNA concentration. The knockdown efficiency of DL depended on the molar ratio of total DL lipids to siRNA. When siRNA was formulated with a sufficient amount of DL, it was efficiently taken up by cells and induced effective gene silencing. Time-lapse imaging showed that siRNA transfected with DL was rapidly internalized into the cells and uniformly dispersed in the cytoplasm within a few minites. The results also showed that DL induced sufficient change in surface charge to allow it to interact with the cell membrane and to allow for rapid endosomal escape. Uptake pathway and time-lapse imaging studies revealed that siRNA was delivered by DL into the cytoplasm, possibly through both macropinocytosis and membrane fusion. The present results emphasize that the modulation of surface charge on nanoparticles is crucial for each siRNA delivery process. Our results also suggest that DL is a potentially useful vector for inducing gene silencing with low-doses of siRNA.