Base editing repairs an SGCA mutation in human primary muscle stem cells
Helena Escobar, … , Florian Heyd, Simone Spuler
Helena Escobar, … , Florian Heyd, Simone Spuler
Published April 13, 2021
Citation Information: JCI Insight. 2021;6(10):e145994. https://doi.org/10.1172/jci.insight.145994.
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Research Article Stem cells Therapeutics

Base editing repairs an SGCA mutation in human primary muscle stem cells

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.

Authors

Helena Escobar, Anne Krause, Sandra Keiper, Janine Kieshauer, Stefanie Müthel, Manuel García de Paredes, Eric Metzler, Ralf Kühn, Florian Heyd, Simone Spuler

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Figure 4

ABE repairs the SGCA c.157G>A mutation in patient and carrier primary MuSC without detectable off-target editing.

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ABE repairs the SGCA c.157G>A mutation in patient and carrier primary...
(A) Experimental design. Primary MuSC from the patient and the carrier were transfected with ABE7.10_4.1/gRNA#1 or without gRNA. FACS was performed to enrich for Venus+ cells, which were subsequently analyzed. (B) EditR analysis of nucleotide rates at each protospacer in patient MuSC transfected with ABE7.10_4.1/gRNA#1. (C) Percentage of reads containing c.157G/A, bystander editing of A10, and indels in patient and carrier MuSC transfected with a range of ABE7.10_4.1/gRNA#1 vector concentrations. (D) A SNP located 332 bp downstream of the mutation and heterozygous in the patient was included in the amplicon to rule out allele detection bias. The plot shows the percentage of reads aligned to each allele. (E) Amplicon sequencing analysis of the 4 predicted exonic off-target sites. Amplicon sequencing data were analyzed using CRISPResso2.