Human MuStem cells are competent to fuse with nonhuman primate myofibers in a clinically relevant transplantation context: A proof-of-concept study

Human MuStem cells are competent to fuse with nonhuman primate myofibers in a clinically relevant transplantation context: A proof-of-concept study

We previously reported that human muscle-derived stem cells (hMuStem cells) contribute to tissue repair after local administration into injured skeletal muscle or infarcted heart in immunodeficient rodent models. However, extrapolation of these findings to a clinical context is problematic owing to...

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Veröffentlicht in:Journal of neuropathology and experimental neurology 2024-05, Vol.83 (8), p.684-694
Hauptverfasser: Charrier, Marine, Leroux, Isabelle, Pichon, Julien, Schleder, Cindy, Larcher, Thibaut, Hamel, Antoine, Magot, Armelle, Péréon, Yann, Lamirault, Guillaume, Tremblay, Jacques P, Skuk, Daniel, Rouger, Karl
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container_issue 8
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container_title Journal of neuropathology and experimental neurology
container_volume 83
creator Charrier, Marine
Leroux, Isabelle
Pichon, Julien
Schleder, Cindy
Larcher, Thibaut
Hamel, Antoine
Magot, Armelle
Péréon, Yann
Lamirault, Guillaume
Tremblay, Jacques P
Skuk, Daniel
Rouger, Karl
description We previously reported that human muscle-derived stem cells (hMuStem cells) contribute to tissue repair after local administration into injured skeletal muscle or infarcted heart in immunodeficient rodent models. However, extrapolation of these findings to a clinical context is problematic owing to the considerable differences often seen between in vivo findings in humans versus rodents. Therefore, we investigated whether the muscle regenerative behavior of hMuStem cells is maintained in a clinically relevant transplantation context. Human MuStem cells were intramuscularly administered by high-density microinjection matrices into nonhuman primates receiving tacrolimus-based immunosuppression thereby reproducing the protocol that has so far produced the best results in clinical trials of cell therapy in myopathies. Four and 9 weeks after administration, histological analysis of cell injection sites revealed large numbers of hMuStem cell-derived nuclei in all cases. Most graft-derived nuclei were distributed in small myofiber groups in which no signs of a specific immune response were observed. Importantly, hMuStem cells contributed to simian tissue repair by fusing mainly with host myofibers, demonstrating their capacity for myofiber regeneration in this model. Together, these findings obtained in a valid preclinical model provide new insights supporting the potential of hMuStem cells in future cell therapies for muscle diseases.
doi_str_mv 10.1093/jnen/nlae044
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title Human MuStem cells are competent to fuse with nonhuman primate myofibers in a clinically relevant transplantation context: A proof-of-concept study
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