Adeno Associated virus serotype 8 (AAV8) is of particular interest as a vector for pre-clinical and clinical trial for Duchenne Muscular Dystrophy (DMD). In several cell lines, this vector has been shown to enter cells through clathrin-mediated endocytosis followed by a trafficking through the microtubule network in various endosomal compartments toward the nucleus. To efficiently transduce cells, AAV must undergo multiple levels of regulation in these cellular compartments. In DMD, dystrophin deficiency results in disturbed balance of cellular events i.e., fiber centronucleation, disorganized cytoskeleton, presence of fibrosis. We have recently described a loss of virion genomes from both dogs and mice models of DMD treated with therapeutic molecules vectorized in AAV. Indeed, the pathophysiological state of DMD muscle should impact on virions fate and subsequently affect crucial steps for AAV effectiveness as viral uncoating, viral genome maintenance and consequently, the transduction efficiency of AAV. Our project aims to characterize cellular uptake and intracellular transport of AAV8 in DMD muscular cells, with the goal of optimizing AAV vector use to get the best transduction efficiency with the lowest AAV dose. Our first data showed that AAV8-GFP was less efficient to transduce DMD and control primary muscular cells compared to HeLa cells. Moreover, AAV8 traffics through same endosomal compartment in DMD and control myoblasts, but at different rates during early time points of the transduction. These results suggest that in muscle cells, AAV8 uses different entry and trafficking pathways from those previously described in HeLa cells and that dystrophic cellular status could affect subcellular processing of the vector particles. We will specify the relationship between AAV8 vector entry, trafficking, uncoating, and transduction efficiency in vitro in primary myoblasts/myotubes of DMD patients and controls.