Cytoplasm-responsive nanocarriers conjugated with a functional cell-penetrating peptide for systemic siRNA delivery.

To develop a gene carrier for cancer therapy by systemic injection, we synthesized methoxypolyethylene glycol-polycaprolactone (MPEG-PCL) diblock copolymers conjugated with a cytoplasm-responsive cell-penetrating peptide (CPP), CH2R4H2C (C, Cys; H, His; R, Arg). The carrier/small interfering RNA (siRNA) complexes (N/P ratio of 20) had a particle size of approximately 50 nm and stabilized the siRNA against RNase. The cellular uptake ability of the carrier/FAM-siRNA complexes with fetal bovine serum was significantly higher than that of naked FAM-siRNA. In addition, the carrier/anti-vascular endothelial growth factor siRNA (siVEGF) complexes attained a significantly greater silencing effect than naked siVEGF with low cytotoxicity, resulting from higher uptake, early endosomal escape, and efficient release from the complexes in the cytoplasm. Furthermore, intravenous injection of MPEG-PCL-CH2R4H2C/siVEGF complexes had a significantly higher anti-tumor effect in S-180 tumor-bearing mice, which could be attributed to the rigid compaction of siRNA by ionic interactions and disulfide linkages in the CPP polymer micelles in the blood, as well as higher release following cleavage of the disulfide bonds in the reductive cytosol. Taken together, our data demonstrated that these cytoplasm-responsive polymer micelles conjugated with multi-functional CPP, could facilitate siVEGF delivery to tumor tissues after systemic injection and could exert an extremely strong anti-tumor effect.

Suppression of tumor growth by systemic delivery of anti-VEGF siRNA with cell-penetrating peptide-modified MPEG-PCL nanomicelles.

Small interfering RNAs (siRNAs) have potential applications for many diseases, such as cancer, since siRNAs can specifically silence disease-associated genes. However, effective siRNA carriers need to be developed to overcome the low siRNA stability in vivo, to form stable complexes and to facilitate intracellular uptake. In this study, to develop a carrier for systemic siRNA delivery, we prepared methoxy poly(ethylene glycol) (MPEG)/polycaprolactone (PCL) diblock copolymers conjugated with a cell-penetrating peptide, Tat, via a disulfide linkage, and evaluated their ability as an siRNA carrier. The particle size of MPEG-PCL-SS-Tat/siRNA complexes was approximately 100-200 nm. The cellular uptake ability after transfection with FAM-siRNA with MPEG-PCL-SS-Tat was significantly higher than that with FAM-siRNA only. MPEG-PCL-SS-Tat did not induce substantial cytotoxicity. Intravenous injection of MPEG-PCL-SS-Tat/anti-vascular endothelial growth factor (VEGF) siRNA (siVEGF) complexes achieved a high anti-tumor effect in tumor-bearing mice. These results suggest that MPEG-PCL-SS-Tat is a potentially effective siRNA carrier for silencing genes in vitro and in vivo.

A cytoplasm-sensitive peptide vector cross-linked with dynein light chain association sequence (DLCAS) enhances gene expression.

We previously engineered a novel, non-viral, multifunctional gene vector (STR-CH(2)R(4)H(2)C) containing stearoyl (STR) and a block peptide consisting of Cys (C), His (H), and Arg (R). STR-CH(2)R(4)H(2)C forms a nano-complex with pDNA and is stabilized by electronic interactions and disulfide cross linkages. In blood, pDNA, a cytosol-sensitive gene vector, is released from the complex into the cytosol. The current study aimed to make STR-CH(2)R(4)H(2)C capable of active nuclear localization. The dynein light chain association sequence (DLCAS) was disulfide cross-linked to STR-CH(2)R(4)H(2)C/pDNA through disulfide linkages, and the gene expression ability of this DLCAS cross-linked gene vector was evaluated. We examined the gene transfection efficiency of S-180 cells transfected with the STR-CH(2)R(4)H(2)C/DLCAS/pDNA complex. STR-CH(2)R(4)H(2)C/DLCAS/pDNA showed significantly higher and faster gene expression compared with STR-CH(2)R(4)H(2)C/pDNA. We also evaluated the cellular uptake ability of STR-CH(2)R(4)H(2)C/DLCAS/Cy5-labeled pDNA complex. STR-CH(2)R(4)H(2)C/DLCAS/pDNA showed significantly lower cellular uptake compared with STR-CH(2)R(4)H(2)C/pDNA. This result indicates that high gene expression of STR-CH(2)R(4)H(2)C/DLCAS/pDNA does not facilitate its cellular uptake. In addition, the gene expression of DLCAS/STR-CH(2)R(4)H(2)C/pDNA in S-180 cells pretreated with the tubulin polymerization inhibitor, nocodazole (NCZ), was significantly lower than that in the absence of NCZ. These results indicate that the high transfection efficiency of DLCAS/STR-CH(2)R(4)H(2)C/pDNA is dependent on intra-cellular transport utilizing the microtubule motor protein, dynein. Taken together, our results suggest that DLCAS-modified STR-CH(2)R(4)H(2)C may be a promising gene delivery system.