Biomolecules (Dec 2024)
Lipid Nanoparticles Enable Efficient In Vivo DNA Knock-In via HITI-Mediated Genome Editing
Abstract
In vivo genome editing holds great therapeutic potential for treating monogenic diseases by enabling precise gene correction or addition. However, improving the efficiency of delivery systems remains a key challenge. In this study, we investigated the use of lipid nanoparticles (LNPs) for in vivo knock-in of ectopic DNA. Our in vitro experiments demonstrated that the homology-independent targeted integration (HITI)-mediated genome-editing method achieved significantly higher knock-in efficiency at the Alb locus in hepatic cells compared to the traditional homology-directed repair (HDR)-mediated approach. By optimizing LNP composition and administration routes, we successfully achieved HITI-mediated GFP knock-in (2.1–2.7%) in the livers of mice through intravenous delivery of LNP-loaded genome editing components. Notably, repeated intravenous dosing led to a twofold increase in liver GFP knock-in efficiency (4.3–7.0%) compared to a single dose, highlighting the potential for cumulative genome editing effects. These findings provide a solid foundation for the use of LNPs in in vivo knock-in strategies, paving the way for future genome-editing therapies.
Keywords
