RESUMO
Lipid nanoparticles (LNPs) are successfully used for RNA-based gene delivery. In the context of gene replacement therapies, however, delivery of DNA expression plasmids using LNPs as a non-viral vector could be a promising strategy for the induction of longer-lasting effects. Therefore, DNA expression plasmids (3 to 4 kbp) coding for fluorescent markers or luciferase were combined with LNPs. Different clinically used ionizable lipids (DLin-MC3-DMA, SM-102, and ALC-0315) were tested to compare their influence on DNA plasmid delivery. DNA-LNPs were characterized with respect to their colloidal properties (size, polydispersity, ζ-potential, morphology), in vitro performance (cellular uptake, DNA delivery, and gene expression), and in vivo characteristics (biodistribution and luciferase gene expression). At an optimized N/P ratio of 6, spherical, small and monodisperse particles with anionic ζ-potential were obtained. Efficient transgene expression was achieved with a minimum amount of 1 pg DNA per initially plated cells. Zebrafish studies allowed selection of DNA-LNPs, which demonstrated prolonged blood circulation, avoidance of macrophage clearance, and vascular extravasation. Our comparative study demonstrates a high impact of the ionizable lipid type on DNA-LNP performance. Superior transfection efficiency of DNA-LNPs containing the ionizable lipid ALC-0315 was confirmed in wildtype mice.
RESUMO
The delivery of nucleic acids relies on vectors that condense and encapsulate their cargo. Especially nonviral gene delivery systems are of increasing interest. However, low transgene expression levels and limited tolerability of these systems remain a challenge. The improvement of nucleic acid delivery using depolymerized chitosan-polyethylenimine DNA complexes (dCS-PEI/DNA) is investigated. The secore complexes are further combined with chitosan-based shells and functionalized with polyethylene glycol (PEG) and cell penetrating peptides. This modular approach allows to evaluate the effect of functional shell components on physicochemical particle characteristics and biological effects. The optimized ternary complex combines a core-dCS-linear PEI/DNA complex with a shell consisting of dCS-PEG-COOH, which results in improved nucleic acid encapsulation, cellular uptake and transfection potency in human hepatoma HuH-7cells and murine primary hepatocytes. Effects on transgene expression are confirmed in wild-type mice following retrograde intrabiliary infusion. After administration of only 100 ng complexed DNA, ternary complexes induced a high reporter gene signal for three days. It is concluded that ternary coreshell structured nanoparticles comprising functionalized chitosan can be used for in vitro andin vivo gene delivery.