Abstract
Skeletal muscle can regenerate from muscle stem cells and their myogenic precursor cell progeny, myoblasts. However, precise gene editing in human muscle stem cells for autologous cell replacement therapies of untreatable genetic muscle diseases has not yet been reported. Loss-of-function mutations in SGCA, encoding α-sarcoglycan, cause limb-girdle muscular dystrophy 2D/R3, an early-onset, severe, and rapidly progressive form of muscular dystrophy affecting both male and female patients. Patients suffer from muscle degeneration and atrophy affecting the limbs, respiratory muscles, and heart. We isolated human muscle stem cells from 2 donors, with the common SGCA c.157G>A mutation affecting the last coding nucleotide of exon 2. We found that c.157G>A is an exonic splicing mutation that induces skipping of 2 coregulated exons. Using adenine base editing, we corrected the mutation in the cells from both donors with > 90% efficiency, thereby rescuing the splicing defect and α-sarcoglycan expression. Base-edited patient cells regenerated muscle and contributed to the Pax7+ satellite cell compartment in vivo in mouse xenografts. Here, we provide the first evidence to our knowledge that autologous gene–repaired human muscle stem cells can be harnessed for cell replacement therapies of muscular dystrophies.
Highlights
Limb-girdle muscular dystrophies (LGMD) include almost 30 different monogenic diseases characterized by progressive weakness and atrophy presenting in the shoulder and pelvic girdle muscles
We isolated and characterized primary muscle stem cells (MuSC) from muscle biopsy specimens obtained from a 10-year-old male LGMD2D patient carrying a compound heterozygous SGCA c.157G>A mutation and from a related carrier (Figure 1, A–D)
Therapeutic gene editing in muscular dystrophies is developing into a realistic scenario
Summary
Limb-girdle muscular dystrophies (LGMD) include almost 30 different monogenic diseases characterized by progressive weakness and atrophy presenting in the shoulder and pelvic girdle muscles. Skeletal muscle is the most abundant tissue in the body; developing cell replacement therapies for MD patients poses substantial challenges. Precise and efficient gene repair in primary somatic stem and progenitor cells ex vivo is increasingly plausible due to the rapid development of CRISPR/Cas9-based tools for base editing that are independent from the cellular DNA repair pathway choice. We found a potentially new pathomechanism for a loss-of-function SGCA c.157G>A mutation and corrected it with > 90% efficiency in primary MuSC from a LGMD2D patient and a related carrier using ABE, without detectable editing at predicted off-target loci.
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