Dual Environment-Responsive Polyplex Carriers for Enhanced Intracellular Delivery of Plasmid DNA

Abstract

In this study, we describe a multifunctional, nontoxic delivery vehicle with dual-environment sensitivity to deliver plasmid DNA (pDNA) into the cytoplasm of cells. This delivery vehicle was designed to be destabilized by reduction of disulfide cross-links in the intracellular environment and also to contain pH-sensitive membrane-destabilizing activity in acidic late endosomal/lysosomal compartments to allow escape of pDNA into the cell cytoplasm. Polyion complex formation was used to form ternary polyplexes using ionic polymers containing specific chemistries to achieve functional demands. First, template binary polyplexes were formed by association of cationic poly(l-lysine) containing thiol groups (PLys(PDP)) with pDNA and were subsequently cross-linked by disulfide formation for increased stability. Then, binary cross-linked polyplexes were coated with a pH-sensitive membrane-active polyanion, poly(ethylene glycol)-b-poly(aspartamide(DET-Aco)) (PEG-PAsp(DET-Aco)), to produce ternary cross-linked polyplexes. PEG-PAsp(DET-Aco) comprises two repeating units of aminoethylene in PAsp side chains and primary amines modified with anionic cis-aconitic groups. PEG-PAsp(DET-Aco) degrades at acidic pH to generate the parent PEG-PAsp(DET) polymer, which is active toward late endosomal/lysosomal membranes and thus can assist in the endosomal escape of pDNA following endocytosis. Binary/ternary cross-linked polyplexes remained stable toward counter polyanion exchange with dextran sulfate, but released pDNA following disulfide reduction. Ternary cross-linked polyplexes formed by addition of PEG-PAsp(DET-Aco) resulted in enhanced gene transfection efficiency in cultured cells (Huh-7 and HUVEC) without associated cytotoxicity. The enhanced gene transfection was found to be correlated with improved endosomal escape by observation of intracellular trafficking using confocal laser scanning microscopy. This multifunctional ternary cross-linked polyplex demonstrates the successful design of a gene delivery vehicle utilizing intracellular stimuli, and is a promising platform for further development toward practical use.