Comparative evaluation of liver-directed knockin strategies with viral and nonviral vectors in mouse inherited disease models.

Abstract

CRISPR-Cas9-mediated gene knockin has emerged as a promising strategy for early-onset genetic disease intervention. However, the therapeutic efficacy and editing outcomes of different knockin strategies remain incompletely understood. Here, we systematically evaluated three major liver-directed knockin strategies, namely homology-directed repair (HDR), homology-independent targeted integration (HITI), and homology-mediated end joining (HMEJ), using neonatal mouse models of mucopolysaccharidosis type I and hemophilia B. Although all three approaches effectively rescued disease phenotypes, we observed distinct editing outcomes. Notably, the HMEJ approach, delivered via a combined adeno-associated virus-lipid nanoparticle (AAV-LNP) system, exhibited superior integration efficiency (5.8%-5.9%) and fidelity (97%-98%) compared with HDR and HITI. In contrast, whole-genome sequencing indicated that HITI induced a higher risk of random AAV donor integration than HDR or HMEJ. Furthermore, long-read sequencing analyses revealed that the frequencies of inverted terminal repeat (ITR)-mediated transgene integration differed between the 5' and 3' genomic junctions among the three strategies. Specifically, in HDR- and HMEJ-treated mice, ITR-mediated integration events were 7.7- to 19.7-fold more common at the 3' junctions than at the 5' junctions. These findings highlight the comprehensive advantages of the AAV-LNP-mediated HMEJ approach for liver-directed knockin therapy and suggest its strong potential for clinical translation.