Peptide-mediated targeting of tumors has become an effective strategy for cancer therapy. Retro-inverso peptides resist protease degradation and maintain their bioactivity. We used the retro-inverso peptide D(PRPSPKMGVSVS) (D-SP5) as a targeting ligand to develop gene therapy for gastric adenocarcinoma. D-SP5 has a higher affinity for human gastric adenocarcinoma (SGC7901) cells compared with that of its parental peptide, L(SVSVGMKPSPRP) (L-SP5). Polyethylenimine (PEI)/pDNA, polyethylene glycol (mPEG)-PEI/pDNA and D-SP5-PEG-PEI/pDNA were prepared for further study. Quantitative luciferase assays showed the transfection efficiency of D-SP5-PEG-PEI/pGL4.2 was larger compared with that of mPEG-PEI/pGL4.2. Flow cytometry assays revealed that the apoptosis rates of SGC7901 cells treated with D-SP5-PEG-PEI/pTRAIL were larger than mPEG-PEI/pTRAIL. Western blot assays indicated that the expression of tumor necrosis factor-related apoptosis inducing ligand (TRAIL) protein in SGC7901 cells treated with D-SP5-PEG-PEI/pTRAIL was higher compared with that in cells treated with mPEG-PEI/pTRAIL. In vivo pharmacodynamics study revealed that D-SP5-PEG-PEI/pTRAIL could inhibit the growth of gastric adenocarcinoma SGC7901 xenografts in nude mice. Our results demonstrate that D-SP5-PEG-PEI is a safe and efficient gene delivery vector with potential applications in antitumor gene therapy.

The development of nonviral gene delivery vectors offers the potential to provide effective treatment for glioblastoma in the form of gene therapy. Here, we report the use of retro-inverso C-end rule (CendR) peptide D(RPPREGR) as a targeting ligand to prepare a D(RPPREGR)-PEG-PEI gene vector. D(RPPREGR) peptide specifically recognized the neuropilin-1 receptor that was overexpressed on U87 glioma cells, and showed enhanced tumor spheroid penetration ability. Compared with parental RGERPPR, D(RPPREGR) possessed improved biological stability and had a higher affinity for U87 glioma cells; it also showed enhanced penetration of the tumor spheroid. mPEG-PEI/pDNA and D(RPPREGR)-PEG-PEI/pDNA complexes were prepared and MTT assay results revealed that the cytotoxicity of D(RPPREGR)-PEG-PEI complexes was significantly lower than that of PEI complexes, with cell survival rates above 80%. Qualitative and quantitative in vitro transfection results revealed that D(RPPREGR)-PEG-PEI complex transfection efficiencies were 1.9 times higher than those of mPEG-PEI. Fluorescent imaging and frozen sections of brain tissue demonstrated that the D(RPPREGR) modification improved the in vivo transfection efficiency of mPEG-PEI in nude mice bearing U87 gliomas. An antiglioblastoma assay revealed that D(RPPREGR)-PEG-PEI carrying the therapeutic gene pORF-hTRAIL significantly prolonged the survival time of intracranial U87 glioma-bearing mice from 25 to 30 days. Therefore, D(RPPREGR)-PEG-PEI appears to be suitable for use as a safe and efficient gene delivery vehicle with potential applications in glioblastoma gene therapy.

The application of tumor targeting ligands for the treatment of cancer holds the promise of enhanced efficacy and reduced toxicity. L-SP5 (L(SVSVGMKPSPRP)) is a peptide that recognizes tumor neovasculature but not normal blood vessels (Lee et al., Cancer Res.2007, 67, 10958–65). The current report presents the design and application of D-SP5 (D(PRPSPKMGVSVS)), a novel retro-inverso analogue of L-SP5. Peptides D-SP5 and parental L-SP5 are shown to compete for the same target sites of a yet unknown cellular target and possess a dual-targeting bioactivity for both activated endothelial cells (HUVEC) and several tumor cell lines. Cellular uptake experiments showed superior in vitro targeting abilities of D-SP5 compared with L-SP5, such as enhanced internalization into stimulated HUVEC or KB, U87, and SGC tumor cells. A radioligand receptor binding assay revealed a higher cell affinity of D-SP5 in all tested cell lines, with Kd values for D-SP5 about 2-fold lower than for L-SP5. An up to 3-fold higher maximum binding capacity (Bmax) to cells of D-SP5 was noted. Fluorescein-labeled D-SP5 upon intravenous administration displayed strong association with tumor endothelium. D-SP5-conjugated PEG-DSPE micelles displayed enhanced tumor homing (evidenced by near-infrared in vivo imaging). When loaded with doxorubicin, D-SP5 micelles could markedly suppress tumor growth with higher efficacy than L-SP5 micelles both in vitro and in vivo in KB tumor xenografts. In summary, the data demonstrate that D-SP5 displays higher binding affinities toward tumor endothelium as well as tumor cells and enhanced tumor targeting capability in vitro and in vivo.