Genetic characterisation of hDMD mice and the generation of a single-copy full-length hDMD transgenic mouse model of Duchenne Muscular Dystrophy

The development of sequence-specific precision treatments like CRISPR gene-editing therapies for Duchenne Muscular Dystrophy (DMD) requires sequence humanised animal models to enable the direct clinical translation of tested strategies. The current available transgenic mouse model containing the full-length human DMD gene, Tg(DMD)72Thoen/J (hDMDTg), has been found to have two copies of the transgene per locus in a tail-to-tail orientation, which does not accurately simulate the true copy number of the DMD gene. This duplication also complicates the analysis when testing CRISPR therapy editing outcomes, as large genetic alterations and rearrangements can occur between the cut sites on the two transgenes. To address this, we performed long read nanopore sequencing on hDMD mice to better understand the structure of the duplicated transgenes. Following that, we performed a megabase-scale deletion of one of the transgenes by CRISPR zygotic microinjection to generate a single-copy, full-length, humanised DMD transgenic mouse model (hDMDTgSc). Functional, molecular, and histological characterisation show that the single remaining human transgene retains its function and rescues the dystrophic phenotype caused by endogenous murine Dmd knockouts. Our unique hDMDTgSc mouse model can potentially be used to further generation of DMD disease models, suited for the pre-clinical assessment of sequence-specific therapies.