pH and redox dual-responsive multifunctional gene delivery with enhanced capability of transporting DNA into the nucleus.

Stimuli-responsive gene delivery vectors based on physiologically triggered structure changing have been recently recognized as a new therapeutic agent for their excellent performance in vivo. Herein, we present an intelligent gene delivery system based on the octa-arginine peptides (R)-conjugated polyamino acid derivatives noted as PPCRC (PVIm-(PAsp-Cystamine-R)-Cholesteryl), which processed pH responsive, surface charge-switching, intracellular redox-responsive and enhanced nucleus import of gene together. Due to the imidazole group in the PPCRC backbone, the DNA/PPCRC polyplexes not only exhibited the enhanced buffering capacity in the endosome after endocytosis, but also displayed the reversible surface charge from negative to positive with decreasing the pH value form pH 7.4 to pH 6.5-6.8, which would promote the cell membrane binding and cellular uptake. The disulfide bond for R peptides conjugation in the polymer side chain could be rapidly cleaved under reductive conditions, facilitating DNA release in the cytoplasm. Subsequently, the DNA would be still associated with the R peptides, which would promote the intracellular nucleus import of DNA. The luciferase gene expression level of COS-7 cells transfected by DNA/PPCRC polyplexes was almost 2000 folds higher than cells transfected by DNA/PPCC polyplexes (without R peptides modification) in growth-arrested cell model. Nearly 10 folds enhanced gene transfection efficiency was found on human bone mesenchymal stem cells (hBMSCs) using the same strategy, which revealed that this intelligent vector can be also utilized in transfection of non-dividing cells. Intravenous injection of the DNA/PPCRC polyplexes also achieved the effective transfection in subcutaneous tumor model. Taken together, PPCRC vector has great potential for both dividing and non-dividing cells transfection and in vivo gene delivery application.