Hydrogen bonds in polycation improve the gene delivery efficiency in the serum-containing environment

Abstract

Cationic polymers with high charge density could effectively condense the DNA and achieve gene transfection; however, it often brings non-negligible cytotoxicity. Notably, the high charge density gene vector fails in the serum environment, limiting further application in vivo. In this paper, an efficient and reliable non-viral gene vector of poly (amidoamine) (PAA) was designed by introducing diacryolyl-2,6-diaminopyridine (DADAP) onto the PAA backbone through Michael-addition polymerization, which provides high transfection efficiency in a serum-containing environment. Diacryolyl-2,6-diaminopyridine and cationic parts provided multiple interactions between gene vectors and DNA, including hydrogen bond and electrostatic interactions. The introduction of hydrogen bonding can effectively reduce the charge density of polyplexes without reducing the DNA condensing ability, incorporating the diaminopyridine group and cationic part in PAA chains successfully consolidated cellular uptake, endosome destabilization, and transfection efficiency for the PAA/DNA complexes with low cytotoxicity. The constructed vector with multiple interactions presented 6 times higher transfection efficiency in serum-free and 9 times in serum-containing environment than that of branched polyethyleneimine (PEI 25K) in 293T cells in vitro. Therefore, introducing the hydrogen band to form low charge density polyplexes with high transfection efficiency and low cytotoxicity has a great potential in gene delivery.