Genomic integration of the full-length dystrophin coding sequence in Duchenne muscular dystrophy induced pluripotent stem cells.

This study focused on genetic engineering strategies to address Duchenne muscular dystrophy. The gene mutated in this disorder is very large. Therefore, special methods were needed to assemble and express the full-length DMD gene in bacteria. Plasmids that carried the entire gene DMD gene were developed that also include useful marker genes like luciferase and mCherry, for tracking plasmid expression in cells and tissues. The plasmid carry two intron sequences in the DMD gene that improve the yield of plasmid DNA in bacteria. The plasmid also carries a DNA sequence that allows the vector to become integrated into the genome of human cells in the presence of a site-specific recombinase enzyme called phiC31 integrase. In this work, we demonstrated the incorporation of the DMD plasmid into human chromosomes in human tissue culture cells and expression of the DMD gene. In addition, we demonstrated incorporation of the DMD plasmid into induced pluripotent stem cells derived from a patient with DMD. The iPS cells previously did not express any DMD, but after incorporation of our plasmid, they expressed the correct DMD protein. Furthermore, the plasmid was used in gene therapy experiments to introduce the DMD gene into the hind limb muscles of a mouse model of DMD. The plasmid was introduced by a vascular muscle infusion method and resulted in muscle fibers that now expressed DMD, whereas no DMD expression is normally present in these mice. Therefore, the plasmids we developed have utility in cell and gene therapy strategies to treat Duchenne muscular dystrophy.