Development of a safe and efficient gene delivery system based on a biodegradable tannic acid backbone.

Finding a safe and efficient gene delivery vector is a major international challenge facing the development of gene therapy. Tannic acid (TA) is a natural cross-linker owing to its hydroxyl and carboxyl groups that can interact with biopolymers for different biomaterial design. In this work, three polyethyleneimine-modified TA polymers were prepared, and the polymers were characterized by FTIR, UV-vis, elemental analysis and 1H NMR. The potential of PTAs as gene vector was studied in vitro, including DNA loading capacity, DNA protection ability and biocompatibility. In addition, the particle size, zeta potential, DNA encapsulation efficiency, cell uptake and transfection efficiency of the PTA-pDNA polyplexes were also studied. The results showed that PTA2k and PTA30k could completely condense DNA at N/P of 2, and PTA600 could only completely condense DNA at N/P of 50. The PTA/pDNA polyplexes could protect DNA from degrading by DNA enzymes and could be efficiently uptaked by cells. Biocompatibility assay showed that PTA had no significant cytotoxicity and effect on cell proliferation compared to PEI. At low N/P ratios of 1-4, PTA showed higher transfection efficiency than PEI, and the transfection efficiency increased with the increase of PEI molecular weight in PTA. At N/P of 3, PTA30k showed the highest transfection efficiency of 23.8%, while PEI30k showed only 6.7%. These results indicate that PTA is a promising candidate vector for safe and efficient gene delivery.

Safe and efficient gene delivery based on rice bran polysaccharide.

Polysaccharides are capable of being modified by polycations to adjust their physical and chemical properties, which accordingly are considered as potential candidate materials for safe and efficient gene delivery. Here, we extracted and purified polysaccharides from rice bran, and their physicochemical properties were determined by various methods. Polyethyleneimine (PEI) modified rice bran polysaccharide (PRBP) was prepared by grafting RBP with low molecular weight PEI and the preparation was determined by FTIR. The potential of PRBP as a gene vector was systematically evaluated in vitro. The results show that PRBP can compact DNA and form PRBP/DNA polylexes with a particle size of 50-100 nm. The PRBP/DNA polylexes can protect DNA degradation from DNase I efficiently. Compared with PEI, higher transfection efficiency was achieved by the PRBP. At weight ratio of 3, the highest efficiency of gene transfection mediated by PRBP-2000 was obtained, which was 37.5% and significantly higher than PEI and commercial reagents (calcium phosphate cell transfection kit) and was closed to lipo6000. Furthermore, according to MTT results, the cytotoxicity of PRBP is much lower than that of PEI, especially for PEI2000. We hope these results will provide new strategy for rice bran polysaccharides development and application as biomaterials.

Rice bran polysaccharide-metal complexes showed safe antioxidant activity in vitro.

The effect on the intracellular reactive oxygen species (ROS) generation, and the antioxidant and cytotoxicity properties of rice bran polysaccharides (RBP) and RBP-metal complexes RBP-Fe(III), RBP-Cu, RBP-Zn and RBP-Ca, were evaluated using atomic absorption spectroscopy (AAS), scavenging activity assays, cell viability assay and fluorescence microscopy. The RBP-metal complexes were prepared using the hydrothermal method. The RBP-Fe(III) complexes were found to be potent scavengers for superoxide (O2-) free radicals. The RBP alone and RBP-Ca complex showed high scavenging activity for 2,2-diphenyl-1-picrylhydrazyl (DPPH) free radicals. In addition, the RBP-Fe(III) complex also showed good biocompatibility and lowered the intracellular ROS levels, while RBP alone, RBP-Zn and RBP-Ca complexes were observed to increase the intracellular ROS level. Our findings suggest that among the tested RBP-metal complexes, RBP-Fe(III) complex is a strong candidate as an antioxidant therapeutic.