Abstract
Highly compacted DNA nanoparticles (DNPs) composed of polyethylene glycol linked to a 30-mer of poly-l-lysine via a single cysteine residue (CK(30)PEG) have previously been shown to provide efficient gene delivery to the brain, eyes and lungs. In this study, we used a combination of flow cytometry, high-resolution live-cell confocal microscopy, and multiple particle tracking (MPT) to investigate the intracellular trafficking of highly compacted CK(30)PEG DNPs made using two different molecular weights of PEG, CK(30)PEG(10k) and CK(30)PEG(5k). We found that PEG MW did not have a major effect on particle morphology nor nanoparticle intracellular transport. CK(30)PEG(10k) and CK(30)PEG(5k) DNPs both entered human bronchial epithelial (BEAS-2B) cells via a caveolae-mediated pathway, bypassing degradative endolysosomal trafficking. Both nanoparticle formulations were found to rapidly accumulate in the perinuclear region of cells within 2h, 37±19% and 47±8% for CK(30)PEG(10k) and CK(30)PEG(5k), respectively. CK(30)PEG(10k) and CK(30)PEG(5k) DNPs moved within live cells at average velocities of 0.09±0.04μm/s and 0.11±0.04μm/s, respectively, in good agreement with reported values for caveolae. These findings show that highly compacted DNPs employ highly regulated trafficking mechanisms similar to biological pathogens to target specific intracellular compartments.