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Review
. 2025 May 7;33(5):2035-2051.
doi: 10.1016/j.ymthe.2025.03.065. Epub 2025 Apr 2.

The road toward AAV-mediated gene therapy of Duchenne muscular dystrophy

Niclas E Bengtsson  1 Hichem Tasfaout  2 Jeffrey S Chamberlain  3
Affiliations
Review

The road toward AAV-mediated gene therapy of Duchenne muscular dystrophy

Niclas E Bengtsson et al. Mol Ther. .

Abstract

Forty years after the dystrophin gene was cloned, significant progress has been made in developing gene therapy approaches for Duchenne muscular dystrophy (DMD). The disorder has presented numerous challenges, including the enormous size of the gene (2.2 MB), the need to target muscles body wide, and immunogenic issues against both vectors and dystrophin. Among human genetic disorders, DMD is relatively common, and the genetics are complicated since one-third of all cases arise from a spontaneous new mutation, resulting in thousands of independent lesions throughout the locus. Many approaches have been pursued in the goal of finding an effective therapy, including exon skipping, nonsense codon suppression, upregulation of surrogate genes, gene replacement, and gene editing. Here, we focus specifically on methods using AAV vectors, as these approaches have been tested in numerous clinical trials and are able to target muscles systemically. We discuss early advances to understand the structure of dystrophin, which are crucial for the design of effective DMD gene therapies. Included is a summary of efforts to deliver micro-, mini-, and full-length dystrophins to muscles. Finally, we review current approaches to adapt gene editing to the enormous DMD gene with prospects for improved therapies using all these methods.

Keywords: AAV; CRISPR; DMD; Duchenne muscular dystrophy; adeno-associated viral vectors; dystrophin; gene therapy; micro-dystrophin; midi-dystrophin; mini-dystrophin; myotropic; split intein.

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Conflict of interest statement

Declaration of interests The University of Washington holds intellectual property related to μDys, mini-dystrophin, midi-dystrophin, AAV vectors, split-intein vectors, systemic gene delivery, muscle-specific expression cassettes, and gene editing of which the authors are inventors. J.S.C. and H.T. are members of the Scientific Advisory Board of Kinea Bio.

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