Serum stability of non-viral vectors is a crucial factor for successful in vivo gene delivery. Pluronic-block copolymers consisting of hydrophilic ethylene oxide and hydrophobic propylene oxide blocks were tested to prevent the reduction of serum-mediated inhibition of gene transfer of polyethyleneimine (PEI)-DNA complexes in NIH/3T3 cells. The order of hydrophilic-lipophilic balance (HLB) of six different types of Pluronics used in this study was F68>F127>P105>P94>L122>L61. Transfection activities of NIH/3T3 cells with PEI-DNA complexes containing Pluronics with higher HLB showed marked improvement of gene-expression levels in serum media from 10 to 50% fetal bovine serum compared with PEI-DNA complexes alone. Also, higher concentrations (1 and 3%) of Pluronics with higher HLB in the PEI/DNA dispersion provided a stronger steric hindrance in resisting serum components than those obtained in a lower concentration (0.1%). These results suggested that non-viral vectors incorporated with higher HLB of Pluronics may be used as potential vehicles for in vivo delivery of DNA.
Cationic dendrimers possess attractive nano-sized architectures that make them suitable as targeted drug/gene delivery systems. However, very little is known about their mechanisms of cell death in cellular systems. In the current study, the apoptotic and necrotic effects of starburst polyamidoamine(PAMAM) and polypropylenimine (DAB) dendrimers in cultured RAW 264.7 murine macrophage-like cells were investigated. Cationic dendrimer treatment produced a typically dose-dependent cytotoxic effect on macrophage cells. RAW 264.7 cells exposed to cationic dendrimers exhibited morphological features of apoptosis. Apoptotic ladders were observed in DNA extracted from RAW 264.7 cells treated with cationic dendrimers. Analysis from flow cytometry demonstrated an increase in hypodiploid DNA population (sub-G1) and a simultaneous decrease in diploid DNA content, indicating that DNA cleavage occurred after exposure of the cells to cationic dendrimers. Also, cells treated with DAB dendrimer induced a higher percentage of sub-G1 population than those treated with PAMAM dendrimer at the same dose. In addition, it was shown that pre-treatment of RAW 264.7 cells with the general caspase inhibitor zVAD-fmk prevented some degree of apoptosis induced by cationic dendrimers, suggesting that apoptosis in macrophage cells involves a caspase dependent pathway. Macrophage cells were also found to be sensitive to induction of apoptosis by dendrimers, whereas NIH/3T3 cells (mouse fibroblast) and BNL CL.2 (mouse liver) cells did not undergo apoptosis. These results could be helpful for optimizing the biocompatibility of dendrimers used for targeted drug/gene delivery.
This study investigates the feasibility of using the process of spray-freeze drying (SFD) to produce DNA dry powders for non-viral gene delivery. The effect of protective agents was assessed on the stability of DNA dry powders after SFD. The process of SFD had adverse effects on the tertiary structure of DNA with the protective agents of sucrose, trehalose and mannitol. With the protection of these sugars, a band corresponding to the linear form of DNA was observed during gel electrophoresis between the supercoiled form (SC) and the open circular (OC) form. On the contrary, excess cationic condensing polyethyleneimine (PEI), in conjunction with the above sugars, had the ability to provide protection for DNA from degradation after SFD. This is indicated by the reservation in SC and OC forms of DNA during agarose gel electrophoresis. The electrostatic forces between PEI polymer and DNA are critical for providing protection against various stresses generated by the process of SFD. Furthermore, on rehydration, the particle size and zeta potential of PEI/DNA complexes at weight ratios 3:1 of SFD dry powders were well maintained. Also, no transfection activity loss of PEI/DNA complexes at weight ratios 3:1 on NIH/3T3 cells was observed for reconstituted powders as compared with untreated control solutions. These results give a better understanding of preparing stable DNA dry powders by the process of SFD.
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