Nerve growth factor improves the muscle regeneration capacity of muscle stem cells in dystrophic muscle

M Lavasani, A Lu, H Peng, J Cummins… - Human gene therapy, 2006 - liebertpub.com
M Lavasani, A Lu, H Peng, J Cummins, J Huard
Human gene therapy, 2006liebertpub.com
Researchers have attempted to use gene-and cell-based therapies to restore dystrophin
and alleviate the muscle weakness that results from Duchenne muscular dystrophy (DMD).
Our research group has isolated populations of muscle-derived stem cells (MDSCs) from the
postnatal skeletal muscle of mice. In comparison with satellite cells, MDSCs display an
improved transplantation capacity in dystrophic mdx muscle that we attribute to their ability to
undergo long-term proliferation, self-renewal, and multipotent differentiation, including …
Researchers have attempted to use gene- and cell-based therapies to restore dystrophin and alleviate the muscle weakness that results from Duchenne muscular dystrophy (DMD). Our research group has isolated populations of muscle-derived stem cells (MDSCs) from the postnatal skeletal muscle of mice. In comparison with satellite cells, MDSCs display an improved transplantation capacity in dystrophic mdx muscle that we attribute to their ability to undergo long-term proliferation, self-renewal, and multipotent differentiation, including differentiation toward endothelial and neuronal lineages. Here we tested whether the use of nerve growth factor (NGF) improves the transplantation efficiency of MDSCs. We used two methods of in vitro NGF stimulation: retroviral transduction of MDSCs with a CL-NGF vector and direct stimulation of MDSCs with NGF protein. Neither method of NGF treatment changed the marker profile or proliferation behavior of the MDSCs, but direct stimulation with NGF protein significantly reduced the in vitro differentiation ability of the cells. NGF stimulation also significantly enhanced the engraftment efficiency of MDSCs transplanted within the dystrophic muscle of mdx mice, resulting in the regeneration of numerous dystrophin-positive muscle fibers. These findings highlight the importance of NGF as a modulatory molecule, the study of which will broaden our understanding of its biologic role in the regeneration and repair of skeletal muscle by musclederived cells.
Mary Ann Liebert