Non–fibro-adipogenic pericytes from human embryonic stem cells attenuate degeneration of the chronically injured mouse muscle
Gina M. Mosich, Regina Husman, Paras Shah, Abhinav Sharma, Kevin Rezzadeh, Temidayo Aderibigbe, Vivian J. Hu, Daniel J. McClintick, Genbin Wu, Jonathan D. Gatto, Haibin Xi, April D. Pyle, Bruno Péault, Frank A. Petrigliano, Ayelet Dar
Gina M. Mosich, Regina Husman, Paras Shah, Abhinav Sharma, Kevin Rezzadeh, Temidayo Aderibigbe, Vivian J. Hu, Daniel J. McClintick, Genbin Wu, Jonathan D. Gatto, Haibin Xi, April D. Pyle, Bruno Péault, Frank A. Petrigliano, Ayelet Dar
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Research Article Muscle biology Stem cells

Non–fibro-adipogenic pericytes from human embryonic stem cells attenuate degeneration of the chronically injured mouse muscle

Abstract

Massive tears of the rotator cuff (RC) are associated with chronic muscle degeneration due to fibrosis, fatty infiltration, and muscle atrophy. The microenvironment of diseased muscle often impairs efficient engraftment and regenerative activity of transplanted myogenic precursors. Accumulating myofibroblasts and fat cells disrupt the muscle stem cell niche and myogenic cell signaling and deposit excess disorganized connective tissue. Therefore, restoration of the damaged stromal niche with non–fibro-adipogenic cells is a prerequisite to successful repair of an injured RC. We generated from human embryonic stem cells (hES) a potentially novel subset of PDGFR-β+CD146+CD34–CD56– pericytes that lack expression of the fibro-adipogenic cell marker PDGFR-α. Accordingly, the PDGFR-β+PDGFR-α– phenotype typified non–fibro-adipogenic, non-myogenic, pericyte-like derivatives that maintained non–fibro-adipogenic properties when transplanted into chronically injured murine RCs. Although administered hES pericytes inhibited developing fibrosis at early and late stages of progressive muscle degeneration, transplanted PDGFR-β+PDGFR-α+ human muscle-derived fibro-adipogenic progenitors contributed to adipogenesis and greater fibrosis. Additionally, transplanted hES pericytes substantially attenuated muscle atrophy at all tested injection time points after injury. Coinciding with this observation, conditioned medium from cultured hES pericytes rescued atrophic myotubes in vitro. These findings imply that non–fibro-adipogenic hES pericytes recapitulate the myogenic stromal niche and may be used to improve cell-based treatments for chronic muscle disorders.

Authors

Gina M. Mosich, Regina Husman, Paras Shah, Abhinav Sharma, Kevin Rezzadeh, Temidayo Aderibigbe, Vivian J. Hu, Daniel J. McClintick, Genbin Wu, Jonathan D. Gatto, Haibin Xi, April D. Pyle, Bruno Péault, Frank A. Petrigliano, Ayelet Dar

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Figure 8

LR-PC–conditioned medium rescues myofiber atrophy.

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LR-PC–conditioned medium rescues myofiber atrophy. (A) Schematic illustr...
(A) Schematic illustration of the in vitro atrophy models and experimental design. DXM, dexamethasone; CM, conditioned medium. (B) Representative images of morphological changes of cultured C2C12 murine myotubes. Cultured myotubes were treated with 10 μM or 100 μM DXM for 24 hours or starved for induction of myofiber atrophy in the presence or absence of LR-PC–derived CM. (C and D) Quantification of average myotube width at the indicated conditions demonstrates that LR-PC CM attenuates both DXM- (C) or starvation-induced (D) atrophy of cultured myotubes. CM 24 hr, CM was collected at 24 hours; CM 48 hr, CM was collected at 48 hours. DMEM/10% FBS was used for DXM-induced atrophy and as feeding and control medium for starvation-induced atrophy. Data are expressed as mean ± SEM. *P < 0.0005 between DXM-treated and DXM CM–treated myofibers or between starved and starved CM-treated myotubes, and #P < 0.0005 between controls and DXM-treated or -starved myotubes (1-way ANOVA). n = 4 independent experiments, n = 20–25 myotubes per control group, n = 65–150 myotubes per DXM groups, and n = 70–180 myotubes per starved groups. Scale bars: 100 μm.