Abstract
BACKGROUND: Point mutations in mitochondrial DNA (mtDNA) cause a range of neurometabolic disorders that currently have no curative treatments. The m.8993T>G mutation in the Homo sapiens MT-ATP6 gene leads to neurogenic muscle weakness, ataxia, and retinitis pigmentosa (NARP) when heteroplasmy exceeds approximately 70%. METHODS: We engineered a split DddA-derived cytosine base editor (DdCBE), each half fused to programmable TALE DNA-binding domains and a mitochondrial targeting sequence, to correct the m.8993T>G mutation in patient-derived induced pluripotent stem cells (iPSCs). Seven days after plasmid delivery, deep amplicon sequencing showed 35 ± 3% on-target C•G→T•A conversion at position 8993, reducing mutant heteroplasmy from 80 ± 2% to 45 ± 3% with less than 0.5% editing at ten predicted off-target loci. RESULTS: Edited cells exhibited a 25% increase in basal oxygen consumption rate, a 50% improvement in ATP-linked respiration, and a 2.3-fold restoration of ATP synthase activity. Directed neural differentiation yielded 85 ± 2% Nestin-positive progenitors compared to 60 ± 2% in unedited controls. CONCLUSIONS: Edits remained stable over 30 days in culture. These results establish mitochondrial base editing as a precise and durable strategy to ameliorate biochemical and cellular defects in NARP patient cells.