Therapeutic Knock-in Genome Editing Using Single AAV Vectors in Mouse Models of Inherited Liver Disease

Gene knock-in therapy has the potential to cure inherited liver diseases but is limited by low efficiency and delivery complexity. Here, we developed a single adeno-associated virus (AAV) vector system comprising a compact CRISPR effector, enAsCas12f, a guide RNA, and a donor template to enable therapeutic genome editing via non-homologous end joining (NHEJ). We targeted the system to the murine Alb locus and applied it to mouse models of hemophilia B, protein C (PC) deficiency, and ornithine transcarbamylase (OTC) deficiency. NHEJ-mediated knock-in showed higher efficiency than homology-directed repair, with successful therapeutic gene insertion in both neonatal and adult mice. The strategy restored plasma factor IX activity in hemophilia B ( F9 ^−/− ) mice, prolonged survival of PC-deficient ( Proc ^−/− ) mice, and prevented hyperammonemia and weight loss in OTC-deficient ( Otc ^spf-ash ) mice upon high protein challenge. Importantly, gene integration was restricted to the liver, with no evidence of germline transmission. This compact, all-in-one AAV knock-in platform simplifies vector production, enables efficient delivery, and achieves reliable transgene expression in vivo . Our findings highlight the potential of liver-targeted knock-in genome editing as a transplant-independent treatment for neonatal-onset metabolic diseases, offering a clinically feasible path towards curative gene therapies for a wide range of monogenic liver disorders.