DNA Release Dynamics from Bioreducible Poly(amido amine) Polyplexes

摘要

The molecular disassembly and DNA release dynamics of bioreducible poly(amido amine) polyplexes were studied in real time by atomic force microscopy (AFM). Molecular disassembly of polyplexes constitutes a critical step along the nonviral gene delivery pathway. DNA release is triggered by the depolymerization of high-molecular-weight polycations into low-molecular-weight oligocations utilizing the thiol and disulfide exchange reaction mechanism. The research is motivated by low cytotoxicity and higher transfection of the poly(amido amine)s containing the disulfide bond than those without the disulfide linkage. AFM images were captured in simulated physiological reducing environment by employing dithiothreitol (DTT). Distinctive stages of polyplex disassembly common to the polyplexes with different disulfide content, molecular weight, and polymer architecture are revealed though the DNA release rate is dependent on the disulfide content. In stage one, upon the depolymerization, polyplexes evolve from metastable structures into the thermodynamically favorable toroid structure. In the second stage, toroids aggregate and sometimes fuse into larger ones. In the last stage DNA gradually unravels from the polyplex resulting in highly decondensed wormlike chains and loops that are held by a central compact core. The results affirm the promising aspect of bioreducible poly(amido amine)s as controlled DNA delivery vectors. The study offers new physical insights into the DNA release pathway including intermediate structures with a high degree of structural heterogeneity and disassembly-induced particle growth. The study identifies disassembly-induced colloidal and morphological instability as an important issue to be addressed in the development of successful polyelectrolyte-based gene delivery systems.