Enhanced Systemic Anti-Angiogenic siVEGF Delivery Using PEGylated Oligo-d-arginine.

Angiogenesis mainly mediated by upregulation of vascular endothelial growth factor (VEGF) provides a hallmark of rapidly proliferating tumor cells and an essential component of the tumor growth and microenvironment, making it a targetable process for antitumor therapy. RNA interference (RNAi) provides a very effective tool for developing antitumor therapies; however, its application to date has been hampered due to the lack of efficient small interfering RNA (siRNA) delivery systems in vivo. Here, we report a polymeric gene carrier system based on PEGylation of a cationic cysteine-ended 9-mer arginine oligopeptide (CR9C), which provides effective siRNA systemic delivery and specifically suppresses VEGF (siVEGF). The PEG500-CR9C/siVEGF oligopeptoplex provided improved blood circulation, enhanced protection from serum proteases, reduced uptake in the liver and kidneys, enhanced tumor targeting, and down-regulated intratumoral VEGF level, which comprehensively resulted in improved antitumor efficacy without significant toxicity in vivo. PEG500-CR9C has a great potential for safe and efficient siRNA delivery with diverse applications.

Reducible Poly(Oligo-D-Arginine) as an Efficient Carrier of the Thymidine Kinase Gene in the Intracranial Glioblastoma Animal Model.

Gene therapy has been considered as an alternative treatment for glioblastoma therapy. In this study, a glioblastoma-specific suicide gene, pEpo-NI2-SV-TK, was delivered into the intracranial glioblastoma model using reducible poly(oligo-d-arginines) (rPOA). pEpo-NI2-SV-TK has the erythropoietin (Epo) enhancer and the nestin intron 2 (NI2) for glioblastoma specific gene expression. The in vitro studies showed that the rPOA formed stable complexes with pEpo-NI2-SV-TK. In the MTT and TUNEL assays, rPOA showed lower cytotoxicity than polyethylenimine (25 kDa, PEI25k). In addition, the rPOA/pEpo-NI2-SV-TK complex induced higher glioblastoma cell death under hypoxic condition than normoxic condition, suggesting that pEpo-NI2-SV-TK induced gene expression in the hypoxic tumor tissue. For in vivo therapeutic efficacy evaluation, the rPOA/pEpo-NI2-SV-TK complex was injected into the brains of an intracranial glioblastoma rat model. The rPOA/pEpo-NI2-SV-TK injected group had a significantly reduced tumor size, compared with the control and the PEI25k/pEpo-NI2-SV-TK injected group. The TUNEL assay showed that the rPOA-pEpo-NI2-SV-TK complex had more apoptotic cells than the control and PEI25k/pEpo-NI2-SV-TK injected groups. These results suggest that the rPOA is an efficient carrier for pEpo-NI2-SV-TK and increased the therapeutic efficacy in the intracranial glioblastoma models. Therefore, the rPOA/pEpo-NI2-SV-TK complex may be useful for glioblastoma specific gene therapy.