Delivery of small interfering ribonucleic acid using lipid nanoparticles prepared with pH-responsive dipeptide-conjugated lipids.

The development of lipid nanoparticles (LNPs) has enabled the clinical application of small interfering ribonucleic acid (siRNA)-based therapies. Accordingly, various unique ionizable lipids have been explored for efficient siRNA delivery. However, safety concerns related to the structure of ionizable lipids have been raised. Here, we developed a pH-responsive dipeptide-conjugated lipid (DPL) for efficient, high safety siRNA delivery. We synthesized a DPL library by varying the dipeptide sequence and established a strong correlation between the knockdown efficiency of the DPL-based LNPs and the dipeptide sequence. The LNPs prepared with a DPL containing arginine (R) and glutamic acid (E) (DPL-ER) exhibited the highest knockdown efficiency. In addition, the DPL-ER-based LNPs with relatively long lipid tails (DPL-ER-C22:C22) exhibited a higher knockdown efficiency than those with short ones (DPL-ER-18:C18). The zeta potential of the DPL-ER-C22:C22-based LNPs increased as the pH decreased from 7.4 (physiological condition) to 5.5 (endosomal condition). Importantly, the DPL-ER-C22:C22-based LNPs exhibited a higher knockdown efficiency than the LNPs prepared using commercially available ionizable lipids. These results suggest that the DPL-based LNPs are safe and efficient siRNA delivery carriers.

Design of a Novel PEGylated Liposomal Vector for Systemic Delivery of siRNA to Solid Tumors.

A small interfering RNA (siRNA) delivery system using dioleylphosphate-diethylenetriamine conjugate (DOP-DETA)-based liposomes (DL) was assessed for systemic delivery of siRNA to tumors. DL carrying siRNA capable of inducing efficient gene silencing with low doses of siRNA were modified with polyethylene glycol (PEG-DL/siRNA) for systemic injection of siRNA. The biodistribution of DL and siRNA in the PEG-DL/siRNA was studied by using radiolabeled DL and fluorescence-labeled siRNA, respectively. DL in the PEG-DL/siRNA showed a high retention in the plasma, accumulation in the tumor, and low accumulation in the liver and spleen after intravenous injection. The in vivo effects of PEGylation were observed only when distearoylphosphatidylethanolamine (DSPE)-PEG but not distearoylglycerol (DSG)-PEG were used. This result suggests that the electrostatic interaction between lipid molecules on the surface of PEG-DL/siRNA was a critical determinant for the in vivo effect of PEGylation. When PEG-DL/siRNA (0.1 mg/kg siRNA) was intravenously injected into tumor-bearing mice, in vivo gene silencing was observed in subcutaneous tumors. These results indicate that PEG-DL/siRNA designed in this study is a promising formulation for systemic use of siRNA.

Charge-reversible lipid derivative: A novel type of pH-responsive lipid for nanoparticle-mediated siRNA delivery.

RNA interference induced by small interfering RNA (siRNA) is a promising strategy for the treatment of various intractable diseases including cancer. Lipid nanoparticles (LNP) composed of ionizable lipids and siRNA are known as a leading siRNA delivery system. However, LNPs composed of conventional ionizable lipids will be aggregated in the physiological environment because of loss of ionization. Therefore, the inclusion of hydrophilic polymer-conjugated lipids such as polyethylene glycol (PEG)-conjugated lipid is required to improve the LNP stability. Herein, we synthesized a novel charge-reversible lipid derivative, dioleoylglycerophosphate-diethylenediamine conjugate (DOP-DEDA). The surface of LNP composed of DOP-DEDA (DOP-DEDA LNP) was constantly ionized and positively charged at pH 6.0, almost neutral at pH 7.4, and negatively charged at pH 8.0. Importantly, DOP-DEDA LNP were stable in the physiological milieu without PEG-conjugated lipid. DOP-DEDA LNP disrupted the red blood cells only under the low-pH condition in a hemolysis assay, suggesting that the interaction between DOP-DEDA LNP and biological membranes is pH-dependent. DOP-DEDA LNP encapsulating siRNA against polo-like kinase 1 (siPLK1) highly suppressed the expression of PLK1 mRNA and its protein. The cellular uptake of DOP-DEDA LNP was increased in an apolipoprotein E3 (apoE3) dose-dependent manner. In addition, DOP-DEDA LNP was taken up into cancer cells via both clathrin- and caveola-mediated endocytosis pathways. These findings indicate that LNP composed of this charge-reversible lipid should be a highly stable and potent siRNA delivery vector.

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.