Open Access
Prepubertal skeletal muscle growth requires Pax7-expressing satellite cell-derived myonuclear contribution
Author(s) -
John F. Bachman,
Alanna Klose,
Wenxuan Liu,
Nicole D. Paris,
R Blanc,
Melissa Schmalz,
Emma Knapp,
Joe V. Chakkalakal
Publication year - 2018
Publication title -
development
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.754
H-Index - 325
eISSN - 1477-9129
pISSN - 0950-1991
DOI - 10.1242/dev.167197
Subject(s) - prepuberty , biology , skeletal muscle , endocrinology , medicine , myocyte , weaning , cell growth , muscle hypertrophy , genetics , hormone
The functional role of Pax7-expressing satellite cells (SCs) in postnatal skeletal muscle development beyond weaning remains obscure. Therefore, the relevance of SCs during prepubertal growth, a period after weaning but prior to the onset of puberty, has not been examined. Here, we have characterized mouse skeletal muscle growth during prepuberty and found significant increases in myofiber cross-sectional area that correlated with SC-derived myonuclear number. Remarkably, genome-wide RNA-sequencing analysis established that post-weaning juvenile and early adolescent skeletal muscle have markedly different gene expression signatures. These distinctions are consistent with extensive skeletal muscle maturation during this essential, albeit brief, developmental phase. Indelible labeling of SCs with Pax7 CreERT2/+ ; Rosa26 nTnG/+ mice demonstrated SC-derived myonuclear contribution during prepuberty, with a substantial reduction at puberty onset. Prepubertal depletion of SCs in Pax7 CreERT2/+ ; Rosa26 DTA/+ mice reduced myofiber size and myonuclear number, and caused force generation deficits to a similar extent in both fast and slow-contracting muscles. Collectively, these data demonstrate SC-derived myonuclear accretion as a cellular mechanism that contributes to prepubertal hypertrophic skeletal muscle growth.