Project description:Skeletal muscle is composed of post-mitotic myofibers that form a syncytium containing hundreds of myonuclei. Using a progressive exercise training model in the mouse and single nucleus RNA-sequencing (snRNA-seq) for high resolution characterization of myonuclear transcription, we show myonuclear functional specialization in muscle from sedentary mice that is altered by 4 weeks of exercise training. Furthermore, in response to exercise, snRNA-seq reveals that resident muscle stem cells, satellite cells, were activated, but demonstrated limited lineage progression while contributing to muscle adaption. In the absence of satellite cells, trajectory analysis predicts the emergence of cryptic myonuclei that appear to lose their canonical identity. These data illustrate how myonuclear adaptation to exercise may be disrupted under conditions satellite cell compromise.

Project description:In cell biology, ribosomal RNA (rRNA) 2'O-methyl (2'-O-Me) is the most prevalent post-transcriptional chemical modification contributing to ribosome heterogeneity. The modification involves a family of small nucleolar RNAs (snoRNAs) and is specified by box C/D snoRNAs (SNORDs). Given the importance of ribosome biogenesis for skeletal muscle growth, we asked if rRNA 2'-O-Me in nascent ribosomes synthesized in response to a growth stimulus is an unrecognized mode of ribosome heterogeneity in muscle. To determine the pattern and dynamics of 2'-O-Me rRNA, we used a sequencing-based profiling method called RiboMeth-seq. We applied this method to tissue-derived rRNA of skeletal muscle and rRNA specifically from the muscle fiber using an inducible myofiber-specific RiboTag mouse in sedentary and mechanically overloaded conditions. These analyses were complemented by myonuclear-specific small RNA sequencing to profile SNORDs and link the rRNA epitranscriptome to known regulatory elements generated within the muscle fiber. We demonstrate for the first time that mechanical overload of skeletal muscle 1) induces decreased 2'-O-Me at a subset of skeletal muscle rRNAand 2) alters the SNORD profile in isolated myonuclei. These findings point to a transient diversification of the ribosome pool via 2'-O-Me during growth and adaptation in skeletal muscle. These findings suggest changes in ribosome heterogeneity at the 2'-O-Me level during muscle hypertrophy and lay the foundation for studies investigating the functional implications of these newly identified "growth-induced" ribosomes.

Project description:Skeletal muscle function and regenerative capacity decline during aging, yet factors driving these changes are incompletely understood. Muscle regeneration requires temporally coordinated transcriptional programs to drive myogenic stem cells to activate, proliferate, fuse to form myofibers, and to mature myonuclei, restoring muscle function after injury. We assessed global changes in myogenic transcription programs distinguishing muscle regeneration in aged mice from young mice by comparing pseudotime trajectories from single-nucleus RNA sequencing of myogenic nuclei. Aging-specific differences in coordinating myogenic transcription programs necessary for restoring muscle function occur following muscle injury, likely contributing to compromised regeneration in aged mice. Differences in pseudotime alignment of myogenic nuclei when comparing aged to young mice via Dynamic Time-Warping revealed pseudotemporal differences becoming progressively more severe as regeneration proceeds. Disruptions in timing of myogenic gene expression programs may contribute to incomplete skeletal muscle regeneration and declines in muscle function as organisms age.

Project description:Skeletal muscle myofibers accrue hundreds of nuclei during post-natal development via fusion with activated satellite cells (myoblasts), which is absolutely reliant on expression of the muscle fusogen myomaker (Mymk) in the myoblasts. Using an inducible genetic approach to render myoblasts non-fusogenic (by tamoxifen-inducible Pax7-CreER mediated recombination of the Mymk gene exclusively in satellite cells), we blocked myonuclear accrual at different time-points of post-natal development and thereby titrated the number of nuclei in resultant mutant myofibers. These Microarray assays were carried out on age day 28 (P28) using total RNA isolated from control and mutant muscle to determine changes in transcriptional profiles of these muscles to (a) assess effects of myonuclear titration, and (b) identify adaptive mechanisms elicited in mutant muscles in response to myonuclear deficiency. We used microarrays to generate information about transcriptional profiles in muscles with varying levels of myonuclear deficiencies.

Project description:Our study aimed to characterize sarcopenia in C57BL/6J mice using a clinically relevant definition and age range and investigate the underlying mechanisms leading to sarcopenia. Aged male C57BL/6J mice (23-32 months) were classified as non-sarcopenic (no deficit), probable sarcopenic (1 deficit), and sarcopenic (2-3 deficits) based on assessments of grip strength, muscle mass, and treadmill running time and using 2 standard deviations below the mean of the young (4-9 months) as cut-off points. A 9-22% prevalence of sarcopenia was identified in 23-26-month-old mice. Age-related declines in muscle function were more severe than in muscle mass and outcomes of all three assessments were positively correlated in aged mice. As sarcopenia progressed, there were decreases in specific force as well as fiber size and number of IIB skeletal muscle fibers. Mitochondrial biogenesis, oxidative capacity, and AMPK-autophagy signaling decreased significantly while no increase in atrogenes was detected. Our study is the first to characterize sarcopenia in C57BL/6J mice using a clinically relevant definition and highlights the different trajectories of age-related declines in muscle mass and function. These critical insights into the molecular changes associated with sarcopenia progression will facilitate future development of therapeutic interventions.

Project description:With aging, skeletal muscle plasticity is attenuated in response to exercise. Here, we report that senescent cells, identified using senescence markers senescence-associated β-Galactosidase (SA β-Gal) and p21 are very infrequent in resting muscle but emerge approximately two-weeks after a bout of resistance exercise in humans. We hypothesized that these cells contribute to blunted hypertrophic potential in old age. Using synergist ablation-induced mechanical overload of the plantaris muscle to model resistance training in adult (5-6 month) and old (23-24 month) male C57BL/6J mice, we found increased senescent cells in both age groups during hypertrophy. Consistent with the human data, there were negligible senescent cells in adult and old sham controls, but old mice had significantly more senescent cells 7- and 14-days following overload relative to young. Old mice had blunted whole muscle hypertrophy when compared to adult mice, along with smaller muscle fibers, specifically glycolytic Type 2x+2b fibers. To ablate senescent cells using a hit-and-run approach, old mice were treated with vehicle or a senolytic cocktail consisting of 5 mg/kg dasatinib and 50 mg/kg quercetin (D+Q) on day 7 and 10 during 14-days of overload; control mice underwent sham surgery with or without senolytic treatment. Old mice given D+Q had larger muscles and muscle fibers after 14 days of overload, fewer senescent cells when compared to vehicle-treated old mice, and changes in the expression of genes (i.e., Igf1, Ddit4, Mmp14) that are associated with hypertrophic growth . Our data collectively show that senescent cells emerge in human and mouse skeletal muscle following a hypertrophic stimulus, and that D+Q improves muscle growth in old mice.

Project description:During neonatal development, skeletal muscle grows dramatically by myonuclei accretion to existing fibers and hypertophic growth of fibers with protein synthesis. To understand molecular mechanism underlying neonatal muscle growth, we used RNAseq to profile the global program of gene expressions especially involved in myoblast fusion, migration, and muscle fiber growth by itself. We used two biological replicates for each time point.

Project description:Transcriptome analysis of skeletal muscle during hypertrophic growth in aged mice Global gene expression patterns were determined from microarray results on day 1, 3, 5, 7, 10 and 14 during plantaris muscle hypertrophy induced by synergist ablation in old adult mice (25 months).

Project description:During neonatal development, skeletal muscle grows dramatically by myonuclei accretion to existing fibers and hypertophic growth of fibers with protein synthesis. To understand molecular mechanism underlying neonatal muscle growth, we used microarray to profile the global program of gene expressions especially involved in myoblast fusion, migration, and muscle fiber growth by itself.

Project description:Excess glucocorticoids induce a skeletal muscle myopathy by changing gene expression. Advanced age augments glucocorticoid-mediated muscle phenotypes, although transcriptional responses underlying those augmented phenotypes are unclear. The purpose of this study was to determine glucocorticoid-induced transcriptional landscapes in young and aged muscle following acute exposure to the hormone and following longer glucocorticoid treatment. Young (4-month-old) or aged (24-month-old) male mice were administered an acute injection of dexamethasone (DEX) or vehicle or treated with DEX or vehicle for 7 days. Muscles were harvested 6.5 h after the only/last injection(s). The tibialis anterior (TA) was analyzed because mass was lower following DEX treatment only in aged males. RNA from the TA was subjected to RNA sequencing. In silico analyses determined pathways associated with glucocorticoid-sensitive genes and predicted transcription factors regulating transcriptional changes. Acute DEX altered similar numbers of genes in young (950) vs. aged males (913) although aged males had greater magnitudes of fold change. The transcriptional response in aged males following 7 days of DEX treatment was greater than acute exposure (1,196 vs 913) whereas the transcriptional response in young males was less pronounced after 7 days (599 vs 950). The glucocorticoid-sensitive genes in aged males were related to growth regulation regardless of treatment duration whereas that predominant enrichment was not evident in young males. Despite transcriptional differences, the transcription factors predicted to regulate the glucocorticoid-sensitive genes were similar in young and aged males. These data expand our understanding of transcriptional changes elicited by glucocorticoids in response to advanced age