Enhanced endosomal escape of siRNA-incorporating hybrid nanoparticles from calcium phosphate and PEG-block charge-conversional polymer for efficient gene knockdown with negligible cytotoxicity.

Development of safe and efficient short interfering RNA (siRNA) delivery system for RNA interference (RNAi)-based therapeutics is a current critical challenge in drug delivery field. The major barriers in siRNA delivery into the target cytoplasm are the fragility of siRNA in the body, the inefficient cellular uptake, and the acidic endosomal entrapment. To overcome these barriers, this study is presenting a hybrid nanocarrier system composed of calcium phosphate comprising the block copolymer of poly(ethylene glycol) (PEG) and charge-conversional polymer (CCP) as a siRNA vehicle. In these nanoparticles, the calcium phosphate forms a stable core to incorporate polyanions, siRNA and PEG-CCP. The synthesized PEG-CCP is a non-toxic endosomal escaping unit, which induces endosomal membrane destabilization by the produced polycation through degradation of the flanking cis-aconitylamide of CCP in acidic endosomes. The nanoparticles prepared by mixing of each component was confirmed to possess excellent siRNA-loading efficiency (∼80% of dose), and to present relatively homogenous spherical shape with small size. With negligible cytotoxicity, the nanoparticles efficiently induced vascular endothelial growth factor (VEGF) mRNA knockdown (∼80%) in pancreatic cancer cells (PanC-1). Confocal laser scanning microscopic observation revealed rapid endosomal escape of siRNA with the nanoparticles for the excellent mRNA knockdown. The results obtained demonstrate our hybrid nanoparticle as a promising candidate to develop siRNA therapy.

Pittella F ，Zhang M ，Lee Y ，Kim HJ ，Tockary T ，Osada K ，Ishii T ，Miyata K ，Nishiyama N ，Kataoka K ... -  《-》

Pancreatic cancer therapy by systemic administration of VEGF siRNA contained in calcium phosphate/charge-conversional polymer hybrid nanoparticles.

Development of an efficient in vivo delivery vehicle of small interfering RNA (siRNA) is the key challenge for successful siRNA-based therapies. In this study, toward systemic delivery of siRNA to solid tumors, a smart polymer/calcium phosphate (CaP)/siRNA hybrid nanoparticle was prepared to feature biocompatibility, reversible stability and endosomal escape functionality using a pH sensitive block copolymer of poly(ethylene glycol) and charge-conversional polymer (PEG-CCP), of which anionic functional groups could be converted to cationic groups in an endosomal acidic condition for facilitated endosomal escape. Nanoparticles were confirmed to be approximately 100nm in size, narrowly dispersed and spherical. Also, the nanoparticle was highly tolerable in medium containing serum, while releasing the entrapped siRNA in a cytoplasm-mimicking ionic condition, presumably based on the equilibrium between CaP complexes and calcium ions. Further, the nanoparticle showed high gene silencing efficiency in cultured pancreatic cancer cells (BxPC3) without associated cytotoxicity. Ultimately, systemic administration of the nanoparticles carrying vascular endothelium growth factor (VEGF) siRNA led to the significant reduction in the subcutaneous BxPC3 tumor growth, well consistent with the enhanced accumulation of siRNA and the significant VEGF gene silencing (~68%) in the tumor. Thus, the hybrid nanoparticle was demonstrated to be a promising formulation toward siRNA-based cancer therapies.

Pittella F ，Miyata K ，Maeda Y ，Suma T ，Watanabe S ，Chen Q ，Christie RJ ，Osada K ，Nishiyama N ，Kataoka K ... -  《-》

Systemic siRNA delivery to a spontaneous pancreatic tumor model in transgenic mice by PEGylated calcium phosphate hybrid micelles.

Efficient systems for delivery of small interfering RNA (siRNA) are required for clinical application of RNA interference (RNAi) in cancer therapy. Herein, we developed a safe and efficient nanocarrier comprising poly(ethylene glycol)-block-charge-conversional polymer (PEG-CCP)/calcium phosphate (CaP) hybrid micelles for systemic delivery of siRNA and studied their efficacy in spontaneous bioluminescent pancreatic tumors from transgenic mice. PEG-CCP was engineered to provide the siRNA-loaded hybrid micelles with enhanced colloidal stability and biocompatibility due to the PEG capsule and with endosome-disrupting functionality due to the acidic pH-responsive CCP segment where the polyanionic structure could be converted to polycationic structure at acidic pH through cis-aconitic amide cleavage. The resulting hybrid micelles were confirmed to have a diameter of <50nm, with a narrow size distribution. Intravenously injected hybrid micelles significantly reduced the luciferase-based luminescent signal from the spontaneous pancreatic tumors in an siRNA sequence-specific manner. The gene silencing activity of the hybrid micelles correlated with their preferential tumor accumulation, as indicated by fluorescence imaging and histological analysis. Moreover, there were no significant changes in hematological parameters in mice treated with the hybrid micelles. These results demonstrate the great potential of the hybrid micelles as siRNA carriers for RNAi-based cancer therapy.

Pittella F ，Cabral H ，Maeda Y ，Mi P ，Watanabe S ，Takemoto H ，Kim HJ ，Nishiyama N ，Miyata K ，Kataoka K ... -  《-》

Fine-tuning of charge-conversion polymer structure for efficient endosomal escape of siRNA-loaded calcium phosphate hybrid micelles.

For efficient delivery of siRNA into the cytoplasm, a smart block copolymer of poly(ethylene glycol) and charge-conversion polymer (PEG-CCP) is developed by introducing 2-propionic-3-methylmaleic (PMM) amide as an anionic protective group into side chains of an endosome-disrupting cationic polyaspartamide derivative. The PMM amide moiety is highly susceptible to acid hydrolysis, generating the parent cationic polyaspartamide derivative at endosomal acidic pH 5.5 more rapidly than a previously synthesized cis-aconitic (ACO) amide control. The PMM-based polymer is successfully integrated into a calcium phosphate (CaP) nanoparticle with siRNA, constructing PEGylated hybrid micelles (PMM micelles) having a sub-100 nm size at extracellular neutral pH 7.4. Ultimately, PMM micelles achieve the significantly higher gene silencing efficiency in cultured cancer cells, compared to ACO control micelles, probably due to the efficient endosomal escape of the PMM micelles. Thus, it is demonstrated that fine-tuning of acid-labile structures in CCP improves the delivery performance of siRNA-loaded nanocarriers.

Maeda Y ，Pittella F ，Nomoto T ，Takemoto H ，Nishiyama N ，Miyata K ，Kataoka K ... -  《-》

Systemic delivery of therapeutic small interfering RNA using a pH-triggered amphiphilic poly-L-lysine nanocarrier to suppress prostate cancer growth in mice.

Prostate cancer is associated with high mortality and new therapeutic strategies are necessary for improved patient outcome. The utilisation of potent, sequence-specific small interfering RNA (siRNA) to facilitate down-regulation of complementary mRNA sequences in vitro and in vivo has stimulated the development of siRNA-based cancer therapies. However, the lack of an effective siRNA delivery system significantly retards clinical application. Amphiphilic polycations with 'stealth' capacity have previously been synthesised by PEGylation of poly-l-lysine-cholic acid (PLL-CA). The benzoic imine linker between PEG and PLL-CA was designed to be stable at physiological pH but cleavable at lower pHs, consistent with the extracellular environment of tumours and the interior of endosomes/lysosomes. The selective hydrolysis of the PEG linker at these targeted sites should provide enhanced cellular uptake and endosomal escape while simultaneously ensuring prolonged blood circulation times. In this study, physicochemical profiling demonstrated nano-complex formation between the PLL derivatives and siRNA (200-280 nm in diameter). At physiological pH only a slight cationic surface charge (<20 mV) was detected, due to the masking effect of the PEG. In contrast, significantly higher positive charges (∼20 to 30 mV and >40 mV) were detected upon hydrolysis of the PEG linker at acidic pHs (pH=6.8 and 5.5, respectively). The PEGylated complexes were stable in serum without significant aggregation or decomplexation of siRNA for up to 48 h. At the cellular level, PEG-PLLs were comparable with the commercial carrier INTERFRin, in terms of cellular uptake, endosomal escape and in vitro reporter gene knockdown. In vivo, utilising a mouse model grafted with prostate carcinoma, significant tumour suppression was achieved using PEGylated complexes without marked toxicity or undesirable immunological response, this was accompanied by a simultaneous reduction in target mRNA levels. In summary, the advantages of these vectors include: the in vitro and in vivo silencing efficiency, and the low toxicity and immunogenicity.

Guo J ，Cheng WP ，Gu J ，Ding C ，Qu X ，Yang Z ，O'Driscoll C ... -  《-》