Skeletal muscle is essential for mobility, stability and whole body metabolism, and muscle loss, for instance, during sarcopenia, has profound consequences. Satellite cells (muscle stem cells) have been hypothesized, but not yet demonstrated, to contribute to muscle homeostasis and a decline in their contribution to myofibre homeostasis to play a part in sarcopenia. To test their role in muscle maintenance, we genetically labelled and ablated satellite cells in adult sedentary mice. We demonstrate via genetic lineage experiments that, even in the absence of injury, satellite cells contribute to myofibres in all adult muscles, although the extent and timing differs. However, genetic ablation experiments showed that satellite cells are not globally required to maintain myofibre cross-sectional area of uninjured adult muscle.
Skeletal muscle is critical for locomotion, structural support and regulation of whole body metabolism. Consequently, homeostatic maintenance of muscle mass is essential for muscle function, and pathological loss of muscle has profound negative consequences1. During aging, even in otherwise healthy individuals, muscle mass and function are progressively lost, in a process termed sarcopenia1,2. Sarcopenia strongly affects quality of life by impairing locomotion, increasing the likelihood for injury and increasing the risk of insulin resistance and type 2 diabetes1. Thus, an understanding of the requirements for maintaining muscle homeostasis is a critical human health need.
Muscle is composed of multinucleate myofibres, and all myonuclei are terminally post-mitotic. Maintenance of muscle mass requires conservation of both the number and size of myofibres, and the number of myonuclei in a myofibre is an important regulator of myofibre size3. During sarcopenia, loss of muscle mass is due to both a loss of myofibres and a decrease in myofibres’ cross-sectional area (CSA), with fast contracting myofibres and hind limb muscles (in humans, mice and rats) being particularly vulnerable1,4. The mechanisms regulating muscle homeostasis and sarcopenia are complex and involve regulation of protein turnover by motor neurons, hormones, immune signals, nutrition and physical activity1.
Adult muscle contains a population of resident stem cells, called satellite cells, and an important unresolved question is whether satellite cells play a role in muscle homeostasis and sarcopenia4,5,6,7. Genetic labelling and ablation studies have definitively established that satellite cells are the endogenous stem cells necessary and sufficient for muscle regeneration8,9,10 and that they contribute to muscle hypertrophy as well11. In the absence of injury, satellite cells are thought to be quiescent and both myonuclear and myofibre number invariant4, but a limited number of studies indicate that new myonuclei are added to uninjured myofibres12,13,14. Because myonuclei are post-mitotic, this suggests that satellite cells contribute myonuclei during homeostasis. During aging, multiple studies show that myonuclei are lost3,15,16,17, leading to myofibre atrophy3, and suggest that in sarcopenia satellite cell replenishment of myonuclei may be inadequate. However, neither the hypothesis that satellite cells contribute to muscle homeostasis nor the hypothesis that a decline in satellite cell-mediated replenishment of myonuclei contributes to sarcopenia has been explicitly tested.
In this study, we use mouse genetics to specifically label or ablate satellite cells to test their role in muscle homeostasis. We demonstrate via genetic lineage experiments that during adulthood satellite cells contribute to uninjured myofibres in all muscles, including hind limb, diaphragm and extraocular (EOMs) muscles. However, genetic ablation experiments showed that satellite cells are not globally required to maintain myofibre CSA of uninjured adult muscle.
Satellite cell number differs between muscles and with age
The number of satellite cells resident in a particular muscle is potentially an important determinant of a muscle’s ability to maintain homeostasis. Multiple studies report that satellite cells differ between anatomical muscles18,19,20,21,22, are enriched in muscles with slow MyHCI myofibres17,19,20,22, and vary with age23. Cross-comparison of these studies has been hampered by the use of different species at diverse ages, and the use of different satellite cell markers and methodologies for quantification. To date, no single study has compared the number of satellite cells in multiple muscles concurrently and over time.
To explicitly compare satellite cell numbers in different muscles, we examined five hind limb muscles, the diaphragm and EOMs of adult male mice. We focused on hind limb muscles because these are highly susceptible to sarcopenia in humans and mice1,3,15,24,25,26. We examined the extensor digitorum longus (EDL), which is highly enriched in fast (myosin heavy chain MyHCIIb+) myofibres; the soleus, which has >50% slow (MyHCI+) myofibres27,28 and the tibialis anterior (TA), gastrocnemius and plantaris, which are composed of a range of myofibre types27,28. In addition, the diaphragm and EOMs were included because their molecular characteristics, morphology, function, innervation and aging are distinct from limb muscles21,29,30. We first analysed satellite cell content in sedentary 12-month-old male mice (this represents 46% of mean lifespan, based on average lifespan of 26 months for C57BL/6J mice), an age when muscle growth is complete31 and myofibre number and CSA have not been reported to decline. Sedentary mice were chosen to represent a ‘ground’, unexercised state (without acute or intentional injuries), and only males were analysed to minimize sex-specific differences. Satellite cells were identified and quantified on sections by Pax7, a transcription factor that specifically and robustly marks satellite cells in adult and aged mice22,32. We found that most limb muscles (EDL, TA, gastrocnemius and plantaris) had similar number of satellite cells, ∼2,000 cells per mm3 (Fig. 1a–d). The soleus and diaphragm muscles, which are enriched in slow myofibres, had 5,000 and 5,700 cells per mm3, respectively (Fig. 1e,f). EOMs had the greatest number of satellite cells, 9,800 satellite cells per mm3, potentially correlating with the higher density of myofibres in this muscle (Fig. 1g). Thus, satellite cell density varies nearly fivefold between muscles in the adult mouse.
To test whether satellite cell number changes over time, we quantified Pax7+ satellite cells at 20 months (77% of mean lifespan), a time at which sarcopenia of limb muscles has not been reported in mice3,25. Most limb muscles (EDL, TA, plantaris and soleus) had no change in satellite cell number at 20 months (Fig. 1a,b,d,e). However, in the gastrocnemius, diaphragm and EOMs, satellite cell numbers significantly declined 16–25% (Fig. 1c,f,g).
Satellite cells contribute to myofibres in all adult muscles
To test whether satellite cells contribute to myofibres during muscle homeostasis, we genetically labelled and followed the long-term fate of satellite cells in uninjured adult muscle (Fig. 2a). Satellite cells were labelled using Pax7CreERT2, an allele that we previously demonstrated specifically and efficiently induces recombination in >95% of Pax7+satellite cells after delivery of tamoxifen (TAM)9. We crossed these mice to the RosamTmG reporter, which ubiquitously expresses membrane-bound Tomato, until Cre-mediated recombination excises Tomato and results in membrane-bound green fluorescent protein (GFP) expression33. We generated male Pax7CreERT2/+;RosamTmG/+ mice, labelled satellite cells at 6 months, via TAM, and harvested muscles at 12 or 20 months. In these mice, the presence of GFP+ myofibres indicates at least one satellite cell contributed to those myofibres between 6 and 12 or 6 and 20 months. In the absence of TAM, RosamTmG/+ mice had no GFP+ myofibres (Supplementary Fig. 1d) and Pax7CreERT2/+;RosamTmG/+ mice had few GFP+ myofibres at 12 or 20 months (0–5.3% GFP/total myofibres; Supplementary Fig. 1), confirming that the Pax7CreERT2 allele is tightly TAM regulated.
In all muscles examined at 12 or 20 months, GFP+ myofibres were present, which indicates that at least one satellite cell contributed to these myofibres (Fig. 2). In longitudinal sections, GFP was often expressed along regions of the myofibre >950 μm in length (Fig. 2b). Given that gene products from a single myonucleus have been measured to spread 200 μm34 and up to 1,000 μm35 along the length of a myofibre, this suggests that potentially more than one satellite cell contributed to some GFP+ myofibres. Interestingly, while centralized myonuclei are a hallmark of satellite cell-mediated regenerated myofibres18, <1% of the GFP+ myofibres had centrally localized myonuclei (Fig. 2c).
The degree of satellite cell contribution to myofibres between 6 and 12 months differed between muscles (Fig. 2). In limb muscles, 8–36% of the myofibres were GFP+ (Fig. 2d–i), and in the diaphragm and EOM, 31 and 18% of myofibres were GFP+, respectively (Fig. 2k,m). Within individual muscles, the anatomical location of GFP+ myofibres varied: GFP+ myofibres were more prevalent in regions closer to the bone for the TA and gastrocnemius and in the global region of EOMs, but showed no positional bias in other muscles (Supplementary Fig. 1). The diaphragm and soleus muscles contained 10 and 55% slow MyHCI+ myofibres, respectively (Fig. 2h). Satellite cells contributed equally to slow and fast myofibres in the diaphragm, but contributed preferentially to fast myofibres in the soleus (Fig. 2j,l). Thus, while satellite cells contributed to all muscles between 6 and 12 months, the degree of contribution differed between muscles, within muscles, and by fibre type.
Examination of muscles at 20 months revealed that between 12 and 20 months satellite cells only continued to contribute to myofibres in a subset of muscles. In the EDL, TA, plantaris and soleus, the percentage of GFP+ myofibres did not significantly change from 12 to 20 months (Fig. 2d,e,g,i), indicating that satellite cells did not measurably contribute to additional myofibres after 12 months. In the gastrocnemius and EOM, the percentage of GFP+ myofibres increased (Fig. 2f,m), demonstrating that satellite cells contributed to an average of 1–2% of myofibres per month between 12 and 20 months (assuming continuous contribution). The diaphragm had the largest increase in GFP+ myofibres, indicating continued satellite cell contribution at a rate of 5% of myofibres per month (assuming continuous contribution; Fig. 2k). As in the 12-month cohort, satellite cells continued to contribute equally to diaphragm slow and fast myofibres. An examination of satellite cell contribution across muscles in individual mice in the 20-month cohort revealed variability between animals: one mouse had consistently high and another mouse had consistently low levels of satellite cell contribution in multiple muscles (P<0.003; Supplementary Fig. 2), despite the mice being littermates, housed together and receiving saturating levels of TAM. Together, these results demonstrate that satellite cells contribute to the myofibres of all adult muscles in the absence of injury, although the extent, distribution, rate and timing of the contribution vary between muscles and animals.
By 20 months myofibres decline in size in most limb muscles
myofibre CSA has been shown to decline in humans17,36,37 and mice3,15,25,38 with advanced age. Our evidence of satellite cell contribution to adult uninjured myofibres suggests that satellite cells may be important for replenishment of aging myonuclei and ultimately maintenance of myofibre CSA. We, therefore, quantified the CSA of individual myofibres in control muscles at 12 and 20 months.
To quantify CSA of myofibres throughout an entire muscle, we used our newly developed analytical tool, MuscleQNT39. Muscles were harvested at 12 and 20 months from control male mice, sectioned and myofibres labelled with antibodies to laminin and slow MyHCI and analysed using MuscleQNT. MuscleQNT applies an adaptive thresholding method to locate myofibre boundaries and then erosion and dilation steps to isolate and quantify CSA of individual myofibres. Thus, MuscleQNT enables the unbiased, automated quantification of all myofibres in a muscle cross-section. It is best used for explicit comparison of two data sets analysed using identical input parameters, as CSA values are highly dependent on these parameters. Therefore, we analysed the sections of 12- and 20-month-old control muscles using identical input parameters (parameters for each muscle are listed in Supplementary Table 2). For each muscle, we generated histograms of 12- and 20-month-old myofibre CSA and determined whether the frequency of the myofibres in each bin was significantly different between 12 and 20 months via permutation tests (see Methods). We also tested for each muscle whether the overall size of myofibres was significantly different between the different aged cohorts using a hierarchical linear model with a random effect to control for intra-class correlation among measured myofibres within individual animals.
Analysis at 12 months showed that myofibre size differed considerably between the muscles (Fig. 3; Supplementary Fig. 3). The mean myofibre size in limb muscles ranged from 750 to 1,090 μm2 (Fig. 3a–e; Supplementary Fig. 3a). The mean diaphragm myofibre size was smaller (420 μm2; Fig. 3f; Supplementary Fig. 3a), and EOM myofibres were the smallest and most tightly constrained in size (120 μm2; Fig. 3g; Supplementary Fig. 3a).
Surprisingly, comparison of 12- and 20-month-old muscles revealed that in most limb muscles of older animals myofibres were already smaller (Fig. 3; Supplementary Fig. 3), although in mice sarcopenia has been described as beginning at 24–26 months3,15,24,26. In the diaphragm, the distribution of myofibre sizes and average myofibre size were unaffected with age (Fig. 3f; Supplementary Fig. 3a). In contrast, in the TA, gastrocnemius, plantaris and soleus, myofibres had shifted towards significantly smaller sizes (Fig. 3b–e; Supplementary Fig. 3a). In the plantaris, this shift resulted in a significantly smaller total muscle CSA (Supplementary Fig. 3b). In the soleus, the shift to smaller myofibres occurred in both fast and slow myofibres. Finally, in the 20-month-old EOMs, the majority of myofibres shifted to smaller sizes, while a minority of myofibres hypertrophied (possibly in compensation; Fig. 3g; Supplementary Fig. 3a).
Satellite cells are not required globally to maintain fibre CSA
Our analysis unexpectedly shows that by 20 months, myofibres in most limb muscles are undergoing an age-related decline in myofibre CSA. We also find that satellite cells contribute significantly to all muscles during this time. Therefore, we hypothesized that satellite cells may be critical for the maintenance of myofibre size. If this hypothesis is correct, ablation of satellite cells should lead to smaller myofibres and potentially exacerbate the decline in CSA seen in most muscles at 20 months.
To test the role of satellite cells in the maintenance of myofibre size, we genetically ablated satellite cells using Pax7CreERT2/+;RosaDTA/+ mice (Fig. 4a). In these mice, Cre activates the expression of diphtheria toxin A (DTA) and specifically kills Pax7+ satellite cells in response to TAM40,41. Satellite cells were ablated in male Pax7CreERT2/+;RosaDTA/+ mice via TAM at 6 months and harvested at either 12 or 20 months. Male Pax7+/+;RosaDTA/+ littermates given TAM were used as controls. In Pax7CreERT2/+;RosaDTA/+ mice given TAM, satellite cells were ablated with >97% efficiency in all muscles (Supplementary Fig. 4). Again, we used MuscleQNT to analyse myofibre CSA using input parameters empirically determined for each cohort of 12- or 20-month-old control and satellite cell-ablated muscles (see parameters in Supplementary Table 2).
Ablation of satellite cells variably affected different muscles. In most limb muscles (TA, gastrocnemius, plantaris and soleus) at 12 or 20 months, there was no difference in average myofibre sizes or their distribution with satellite cell ablation (Fig. 4c–g; Supplementary Fig. 5). In the diaphragm, satellite cell ablation had no effect on the majority of myofibres (which are fast) at 12 or 20 months, but slow myofibres shifted to smaller sizes at 12 months (Fig. 5a,b; Supplementary Fig. 5). Interestingly, in the EOMs, satellite cell ablation had no effect at 20 months, but at 12 months resulted in smaller myofibres (seen in shift in distribution of myofibres, but not in overall average size; Fig. 5c; Supplementary Fig. 5). In addition, while satellite cell ablation had no effect on the size of myofibres in the EDL at 12 months, at 20 months ablation resulted in a shift towards smaller myofibres and a significant 15% decline (P=0.049) in average myofibre size (Fig. 4b; Supplementary Fig. 5).
The observation that satellite cell ablation had an effect on the EDL, but a relatively minor effect on the diaphragm was unexpected. In the EDL, satellite cells only appreciably contributed to 30% of myofibres before 12 months. In contrast, in the diaphragm, satellite cells continuously contributed to myofibres, with 75% of myofibres having received satellite cell-derived myonuclei by 20 months. If satellite cell contribution is important for myonuclear replenishment, we reasoned that the difference in the effect of satellite cell ablation on EDL versus the diaphragm might be explained by a difference in myonuclear dynamics; satellite cell-mediated replenishment of myonuclei may only be functionally important in muscles where the number of myonuclei are declining.
To test for changes in myonuclear number, we quantified the number of myonuclei in control and satellite cell-ablated diaphragms, EDL and also the plantaris (which was unaffected by satellite cell ablation, but suffered satellite cell-independent decline in myofibre CSA) at 12 and 20 months. To control for age-related changes in myonuclear size3, we quantified the myonuclear length from longitudinal sections of these muscles and applied a correction factor to our myonuclear counts42. We found that between 12 and 20 months in the diaphragm and plantaris the number of myonuclei did not decline, even in the absence of satellite cell contribution (Figs 4h, 5d). In contrast, in the EDL, there was a significant 25% loss of myonuclei between 12 and 20 months in control mice (P<0.05; Fig. 4h). The decline in myonuclei between 12 and 20 months in ablated mice demonstrates that EDL myofibres suffer myonuclear decline independent of satellite cells. However, comparison of control and satellite cell-ablated mice at either 12 or 20 months shows that the presence of satellite cells did not detectably affect myonuclear numbers in EDL myofibres.
Satellite cells are the endogenous resident stem cells uniquely capable of replacing post-mitotic myonuclei and myofibres in the adult. It is well established that these stem cells are necessary and sufficient for regeneration of damaged myofibres8,10,41. However, satellite cells also have been hypothesized to contribute to muscle homeostasis and a decline in satellite cell-mediated replenishment of myonuclei may contribute to sarcopenia5,7.
By genetically labelling and following the long-term fate of satellite cells, we demonstrate for the first time that satellite cells contribute to myofibres in all adult muscles in the absence of injury (Fig. 6). The extent of this satellite cell addition varies widely between and within muscles and with age. After 12 months, satellite cells ceased to contribute to myofibres of most hind limb muscles, but not in the gastrocnemius, diaphragm and EOMs. Strikingly, only in these three muscles did the number of satellite cells decline with age. Thus, continued satellite cell contribution during homeostasis appears to deplete the pool of resident, quiescent satellite cells.
The substantial contribution of satellite cells to myofibres to adult uninjured myofibres raises the question: what signals recruit satellite cells? The signal is unlikely to be myonuclear loss. Our findings that satellite cells do not contribute to EDL myofibres after 12 months despite a clear loss of myonuclei and that, conversely, satellite cells continuously contribute to diaphragm myofibres that maintain a stable number of myonuclei contradict such a hypothesis. Our data do indicate that the signals are likely to be dynamic and both local and systemic. Satellite cell contribution varies over time and between muscles, within muscles, and between fibre types, and this suggests that local signals within the muscles dynamically regulate recruitment of satellite cells. Furthermore, our observation that a few mice had higher or lower levels of satellite cell contribution across most muscles implicates the presence of systemic signals, perhaps related to the recently described GAlert signals43 that globally modulate satellite cell recruitment to uninjured myofibres. Alternatively, this inter-animal variation may reflect differences in activity levels or other behavioural parameters. Determining the biomechanical, cellular and molecular signals regulating satellite cell recruitment will be an important area of future research.
Our experiments genetically ablating satellite cells in uninjured mice explicitly test whether satellite cell contribution is critical for the maintenance of adult myofibre size (Fig. 6). In most limb muscles (TA, gastrocnemius, plantaris and soleus), satellite cells were not required for the maintenance of myofibre CSA, although by 20 months these muscles suffered a satellite cell-independent decline of myofibre size. Surprisingly, despite high and continuous contribution of satellite cells to myofibres, diaphragm myofibres also did not require satellite cells for the maintenance of myofibre size (with the exception of slow myofibres, which constitute only 10% of myofibres, at 12 months). However, the stability of myonuclear numbers in the diaphragm between 12 and 20 months suggests that myonuclear replenishment may not be required during this time. A requirement for satellite cell contribution in the diaphragm and the four limb muscles may only become manifest in older (for example, 24 months) mice.
EOMs are unique among the skeletal muscles in having continuous myonuclear addition throughout life12,44. Consistent with these previous reports, we found that satellite cells continuously contributed to EOM myofibres. In addition, ablation of satellite cells shifted the distribution of EOM myofibre CSA to smaller sizes at 12 months, suggesting that satellite cell contribution may be important. By 20 months, satellite cells appeared not to be required for the myofibre maintenance. However, unlike the other skeletal muscles, there is evidence that EOMs contain another population of satellite cells that are Pax7−Pitx2+ (ref. 45), and Pitx2 is required for the development and maintenance of EOMs46,47,48,49. Thus, this alternative Pax7− satellite cell population may compensate in the older mice lacking Pax7+ satellite cells, a hypothesis to be tested in future experiments.
In mouse, the EDL is largely composed of fast MyHCIIb myofibres, and this muscle is particularly susceptible to myonuclear apoptosis, atrophy and neuromuscular dysfunction with age15,50,51,52. Consistent with these reports, we found that the EDL suffered a decline in myonuclear number between 12 and 20 months. Our lineage studies showed that satellite cells contributed to 30% of EDL myofibres before 12 months. Despite this modest contribution, ablation of satellite cells lead to a decline in myofibre CSA at 20 months. How satellite cells may play a role in maintaining EDL myofibre size is currently unclear. The most obvious hypothesis is that satellite cells replenish declining numbers of myonuclei. However, comparison of satellite cell-ablated versus control 20-month-old EDL muscles did not reveal a significant rescue of myonuclei when satellite cells were present.
Satellite cells are required for regeneration and we now also show that they contribute to uninjured adult myofibres. Intriguingly, our work suggests that the mechanisms regulating satellite cells’ contribution to regenerating and uninjured myofibres may differ significantly. First, self-renewal of satellite cells is an important property of regeneration, but in muscles with continuous satellite cell contribution to uninjured myofibres the satellite cell pool is not maintained. Second, a hallmark of regenerated myofibres is the presence of centralized myonuclei. However, despite the presence of many uninjured myofibres to which satellite cells had contributed, we found few centralized myonuclei (see also ref. 22). Dysregulation of satellite cells may also play a role in sarcopenia. A decline in satellite cell-mediated regeneration with age has been widely recognized23. In addition, a decline in satellite cell contribution to uninjured myofibres may contribute to sarcopenia. Recent satellite cell ablation studies53 found that depletion of satellite cells did not accelerate or exacerbate sarcopenia in aged mice. However, in this study, satellite cell ablation was incomplete (ranged from 64 to 87%), and in our study, we have not explicitly tested the role of satellite cells in uninjured muscle of aged (for example, 24 months) mice. Future satellite cell lineage and ablation studies of uninjured and exercised aged mice will be essential to establish whether a decline in satellite cell contribution to myofibres plays a role in sarcopenia.
Mice and TAM delivery
All mouse lines were previously reported: Pax7CreERT2 (ref. 41); RosamTmG (ref. 33); and RosaDTA/+ (ref. 40). Pax7CreERT2 mice were backcrossed >8 generations onto C57BL/6J background. Only male mice were used, and at least five mice were used for each cohort in control and ablation studies. At 6 months of age, satellite cell-labelled (Pax7CreERT2/+;RosamTmG/+, n=4 at 12 months, n=6 at 20 months), satellite cell-ablated (Pax7CreERT2/+;RosaDTA/+, n=8 at 12 months, n=6 at 20 months) and littermate control (Pax7+/+;RosaDTA/+, n=7 at 12 months, n=5 at 20 months) mice were given five 10-mg doses (50 mg total) of TAM by gavage. To ensure continuous ablation/labelling, additional 10-mg doses were given once per month until 12 months, and mice were subsequently harvested at 12 or 20 months. In addition, a small cohort of Pax7CreERT2/+;RosamTmG/+ mice was housed separately, not given TAM and harvested at 12 or 20 months. It was noted that long-term TAM treatment led to inguinal hernias in some mice as has been reported previously54, though this phenotype was observed in equal ratios in control and mutant cohorts. All mice were otherwise healthy at harvest. Mice were housed in the University of Utah animal facility located at 5,000-ft elevation. No statistical method was used to predetermine sample size; all animals were included; and the experiments were not randomized. Animal experiments were performed in accordance with protocols approved by the Institutional Animal Care and Use Committee at the University of Utah.
Immunofluorescence and microscopy
EDL, TA, gastrocnemius, plantaris, soleus, diaphragm and EOM muscles from each animal were harvested, flash-frozen and sectioned at 8 or 12 μm (cross-sections) or 20 μm (longitudinal sections). For section immunofluorescence, slides were fixed in 4% paraformaldehyde (PFA) for 5 min, washed in 1 × PBS, and then if needed (see Supplementary Table 1), subjected to antigen retrieval (heated in 1.8 mM citric acid, 8.2 mM sodium citrate in H20 in a 2100 PickCell Retriever). Sections that required tyramide signal amplification were quenched in 3% H2O2 for 5 min. All slides were blocked in 5% serum or 0.5% TNB blocking reagent (PerkinElmer) in 1 × PBS for 60 min, and incubated in 1° antibody (Supplementary Table 1) overnight at 4 °C. Slides were washed in 1 × PBS, incubated in 2° antibody 2 h at room temperature (Supplementary Table 1), washed in 1 × PBS, and when needed (Supplementary Table 1) incubated in Vector ABC (Vector Laboratories) for 3 h, washed in 1 × PBS and labelled with tyramide signal amplification (Fluorescein or Cy3; PerkinElmer) for 10 min. Slides were washed in PBS, post-fixed in 4% PFA, incubated with 0.4 μg ml−1 Hoechst and mounted with Fluoromount-G (SouthernBiotech). Immunofluorescent sections were imaged on a Nikon AR1 confocal or Nikon Widefield CCD Microscope. Each confocal image is a composite of maximum projections, derived from stacks of optical sections.
Quantification of Pax7 and GFP contribution
For the analysis of satellite cell numbers, cross-sections from the EDL, TA, gastrocnemius, plantaris, soleus, EOM and diaphragm muscles from control (Pax7+/+;RosaDTA/+) and satellite cell ablation (Pax7CreERT2/+;RosaDTA/+) cohorts were immunofluorescently labelled with Pax7. All Pax7+ nuclei were counted by hand (observer blinded to genotype and age), and divided by the muscle volume for each section. Volume was determined from the whole muscle CSA (using ImageJ Analyze Particles function) multiplied by the thickness of the section.
To quantify satellite cell contribution to myofibres in Pax7CreERT2/+;RosamTmG/+ mice, we immunofluorescently labelled sections for Tomato, GFP, and Hoechst and adjacent sections with MyHCI and laminin to identify slow (MyHCI+) and fast (MyHCI−) myofibres. All sections were imaged with identical exposure times and then green levels were adjusted identically in Photoshop based on the levels in control Pax7CreERT2/+;RosammTmG.+ mice (without TAM and excluding obvious GFP+ myofibres). Only myofibres with membrane-bound GFP were counted. To quantify the percentage of GFP+ myofibres, we counted all myofibres within each muscle, and subsequently counted GFP+ fibres. For the gastrocnemius, only the lateral and intermediate muscle heads were counted, and for the diaphragm, a region containing 100 slow fibres was counted. These images were then overlaid with images from adjacent sections labelled with MyHCI and laminin to identify GFP+ slow or fast fibres (soleus and diaphragm only). All images were counted by hand, with observer blinded to age or genotype. To determine whether individual 20-month-old mice had higher or lower GFP contribution across the majority of muscles, we recorded the percentile rank of the %GFP+ myofibres in each animal in each muscle. These percentile ranks across the seven muscles for an individual mouse were used to perform t-tests (with Bonferroni correction) between animals.
Quantification of myofibre CSA
For analysis of myofibre CSA, we immunofluorescently labelled sections with laminin to identify myofibre borders and MyHCI to identify slow myofibres in 12- and 20-month cohorts of control Pax7+/+;RosaDTA/+ and satellite cell-ablated Pax7CreERT2/+;RosaDTA/+ mice. myofibre CSA was quantified via MuscleQNT (developed by S.F. and M.Y. and available at https://github.com/stevendflygare/muscleQNT). MuscleQNT works by first applying an adaptive thresholding method to locate muscle fibres and then uses steps of erosion and dilation to isolate individual muscle fibres. The adaptive thresholding, erosion and dilation steps are parametric, and parameters used to score images were determined empirically (blinded to control or experimental status) for each cohort of muscles so as to best outline and isolate individual myofibres (parameters are listed in Supplementary Table 2). For comparison of 12- and 20-month-old control muscles (Fig. 3), 12-month parameters were used (though 20-month parameters used on the same data showed identical trends, but with slightly different absolute values for fibre sizes). When using MuscleQNT, it is essential to do pairwise comparison of data sets, using exactly the same input parameters (erosion, box size, off set, minimum and maximum fibre size; Supplementary Table 2) as absolute CSA values are dependent on the input parameters. Once fibres are located and isolated in an image, the size of each fibre is assigned as the number of pixels it occupies. In addition, myofibres were identified as slow myofibres if more than x% (x can be specified) of a fibre’s pixels overlap MyHCI+ pixels (colocalization function). Fibre sizes of each image are written to an output file and summary statistics generated for each image. From this data, histograms are generated comparing the distribution of myofibres between 12- and 20-month-old muscles of control and satellite cell-ablated muscles. To determine the significance of differences between 12 and 20 months or control and satellite cell-ablated muscles, permutation tests were conducted. For permutation tests, the 12- or 20-month (or control or mutant) status of the mice is randomly permuted and myofibres were randomly sampled from each of the 12/20-month-old (or control/mutant) mice. The observed differences in each histogram bin between the counts of the 12- and 20-month-old (or control and mutant) mice were recorded and compared with the differences in the corresponding histogram bins of the original 12- and 20-month-old (or control and mutant) mice. The relative proportion of times a permuted difference is as great as or greater than the observed difference in a specific histogram bin allows us to determine for a specific histogram bin the significance of the observed difference in the counts between 12- and 20-month-old (or control and mutant) mice.
In addition to the analysis of the distribution of myofibre sizes, we also used a hierarchical linear regression model with a random effect to model the effect of mouse age and control/mutant status on muscle fibre size. The model leverages a random effect to control for intra-class correlation among myofibres that come from the same animal.
Quantification of myonuclei
The number of myonuclei per fibre for control Pax7+/+;RosaDTA/+ and satellite cell-ablated Pax7CreERT2/+;RosaDTA/+ mice for 12- and 20-month cohorts was determined using the EDL, diaphragm and plantaris cross-sections stained with laminin and Hoechst. Myonuclei were identified by their location inside the basal lamina and the number of myonuclei was counted (by an individual blinded as to section genotype and age) in the 150–250 EDL myofibres, 250–450 diaphragm myofibres and 350–525 plantaris myofibres.
Myonuclear counts in cross-section can over-represent myonuclear number if myonuclei significantly change shape. To correct for this, we used a formula42 that takes into account the observed myonuclear length in each muscle at either 12 or 20 months. We present our data as the number of myonuclei per mm of fibre length by equation (1): x=N*L/(lm+d), where x is the number of myonuclei in a fibre segment of length L (in our case, 1 mm), N is the number of nuclei per myofibre in cross-section, lm is the average myonuclear length at 12 or 20 months and d is the thickness of the section.
Myonuclear length was determined using longitudinal sections of the diaphragm and EDL (myonuclear length for EDL was used for EDL and plantaris) from Pax7CreERT2/+;RosamTmG/+ mice harvested at 12 or 20 months. Sections were immunofluorescently labelled with GFP, laminin and Hoechst and imaged on a Nikon AR1 confocal. Optical stacks were rendered in FluoRender55. Myonuclei were identified by their location inside the basal lamina and measured end to end using FluoRender. For each cohort, 30 nuclei per field were analysed and average myonuclear length was determined.
How to cite this article: Keefe, A.C. et al. Muscle stem cells contribute to myofibres in sedentary adult mice. Nat. Commun. 6:7087 doi: 10.1038/ncomms8087 (2015).
Narici, M. V. & Maffulli, N. Sarcopenia: characteristics, mechanisms and functional significance. Br. Med. Bull. 95, 139–159 (2010).
Rosenberg, I. R. Summary comments. Am. J. Clin. Nutr. 50, 1231–1233 (1989).
Brack, A. S., Bildsoe, H. & Hughes, S. M. Evidence that satellite cell decrement contributes to preferential decline in nuclear number from large fibres during murine age-related muscle atrophy. J. Cell Sci. 118, 4813–4821 (2005).
Rai, M., Nongthomba, U. & Grounds, M. D. Skeletal muscle degeneration and regeneration in mice and flies. Curr. Top. Dev. Biol. 108, 247–281 (2014).
Kadi, F. & Ponsot, E. The biology of satellite cells and telomeres in human skeletal muscle: effects of aging and physical activity. Scand. J. Med. Sci. Sports 20, 39–48 (2010).
Pallafacchina, G., Blaauw, B. & Schiaffino, S. Role of satellite cells in muscle growth and maintenance of muscle mass. Nutr. Metab. Cardiovasc. Dis. 23, (Suppl 1): S12–S18 (2012).
Thornell, L. E. Sarcopenic obesity: satellite cells in the aging muscle. Curr. Opin. Clin. Nutr. Metab. Care 14, 22–27 (2011).
Lepper, C., Partridge, T. A. & Fan, C. M. An absolute requirement for Pax7-positive satellite cells in acute injury-induced skeletal muscle regeneration. Development 138, 3639–3646 (2011).
Murphy, M. & Kardon, G. Origin of vertebrate limb muscle: the role of progenitor and myoblast populations. Curr. Top. Dev. Biol. 96, 1–32 (2011).
Sambasivan, R. et al. Pax7-expressing satellite cells are indispensable for adult skeletal muscle regeneration. Development 138, 3647–3656 (2011).
Fry, C. S. et al. Regulation of the muscle fiber microenvironment by activated satellite cells during hypertrophy. FASEB J. 28, 1654–1665 (2014).
McLoon, L. K., Rowe, J., Wirtschafter, J. & McCormick, K. M. Continuous myofiber remodeling in uninjured extraocular myofibres: myonuclear turnover and evidence for apoptosis. Muscle Nerve 29, 707–715 (2004).
Schmalbruch, H. & Lewis, D. M. Dynamics of nuclei of muscle fibers and connective tissue cells in normal and denervated rat muscles. Muscle Nerve 23, 617–626 (2000).
Spalding, K. L., Bhardwaj, R. D., Buchholz, B. A., Druid, H. & Frisen, J. Retrospective birth dating of cells in humans. Cell 122, 133–143 (2005).
Bruusgaard, J. C., Liestol, K. & Gundersen, K. Distribution of myonuclei and microtubules in live muscle fibers of young, middle-aged, and old mice. J. Appl. Physiol. (1985) 100, 2024–2030 (2006).
Kawai, M., Saitsu, K., Yamashita, H. & Miyata, H. Age-related changes in satellite cell proliferation by compensatory activation in rat diaphragm muscles. Biomed. Res. 33, 167–173 (2012).
Verdijk, L. B. et al. Satellite cells in human skeletal muscle; from birth to old age. Age (Dordr) 36, 545–547 (2014).
Collins, C. A. et al. Stem cell function, self-renewal, and behavioral heterogeneity of cells from the adult muscle satellite cell niche. Cell 122, 289–301 (2005).
Düsterhöft, S., Yablonka-Reuveni, Z. & Pette, D. Characterization of myosin isoforms in satellite cell cultures from adult rat diaphragm, soleus and tibialis anterior muscles. Differentiation 45, 185–191 (1990).
Gibson, M. C. & Schultz, E. The distribution of satellite cells and their relationship to specific fiber types in soleus and extensor digitorum longus muscles. Anat. Rec. 202, 329–337 (1982).
Kallestad, K. M. et al. Sparing of extraocular muscle in aging and muscular dystrophies: a myogenic precursor cell hypothesis. Exp. Cell Res. 317, 873–885 (2011).
Shefer, G., Van de Mark, D. P., Richardson, J. B. & Yablonka-Reuveni, Z. Satellite-cell pool size does matter: defining the myogenic potency of aging skeletal muscle. Dev. Biol. 294, 50–66 (2006).
Brack, A. S. & Rando, T. A. Intrinsic changes and extrinsic influences of myogenic stem cell function during aging. Stem Cell Rev. 3, 226–237 (2007).
Brooks, S. V. & Faulkner, J. A. Contractile properties of skeletal muscles from young, adult and aged mice. J. Physiol. 404, 71–82 (1988).
Sousa-Victor, P. et al. Geriatric muscle stem cells switch reversible quiescence into senescence. Nature 506, 316–321 (2014).
Shavlakadze, T., McGeachie, J. & Grounds, M. D. Delayed but excellent myogenic stem cell response of regenerating geriatric skeletal muscles in mice. Biogerontology 11, 363–376 (2010).
Agbulut, O., Noirez, P., Beaumont, F. & Butler-Browne, G. Myosin heavy chain isoforms in postnatal muscle development of mice. Biol. Cell 95, 399–406 (2003).
Bloemberg, D. & Quadrilatero, J. Rapid determination of myosin heavy chain expression in rat, mouse, and human skeletal muscle using multicolor immunofluorescence analysis. PLoS One 7, e35273 (2012).
Porter, J. D. Extraocular muscle: cellular adaptations for a diverse functional repertoire. Ann. N. Y. Acad. Sci. 956, 7–16 (2002).
Stuelsatz, P., Keire, P., Almuly, R. & Yablonka-Reuveni, Z. A contemporary atlas of the mouse diaphragm: myogenicity, vascularity, and the Pax3 connection. J. Histochem. Cytochem. 60, 638–657 (2012).
White, R. B., Bierinx, A. S., Gnocchi, V. F. & Zammit, P.S. Dynamics of muscle fibre growth during postnatal mouse development. BMC. Dev. Biol. 10, 21 (2010).
Seale, P. et al. Pax7 is required for the specification of myogenic satellite cells. Cell 102, 777–786 (2000).
Muzumdar, M. D., Tasic, B., Miyamichi, K., Li, L. & Luo, L. A global double-fluorescent Cre reporter mouse. Genesis 45, 593–605 (2007).
Blaveri, K. et al. Patterns of repair of dystrophic mouse muscle: studies on isolated fibers. Dev. Dyn. 216, 244–256 (1999).
Kinoshita, I., Vilquin, J. T., Asselin, I., Chamberlain, J. & Tremblay, J. P. Transplantation of myoblasts from a transgenic mouse overexpressing dystrophin prduced only a relatively small increase of dystrophin-positive membrane. Muscle Nerve 21, 91–103 (1998).
Cristea, A. et al. Effects of aging and gender on the spatial organization of nuclei in single human skeletal muscle cells. Aging Cell 9, 685–697 (2010).
Lexell, J., Taylor, C. C. & Sjostrom, M. What is the cause of the ageing atrophy? Total number, size and proportion of different fiber types studied in whole vastus lateralis muscle from 15- to 83-year-old men. J. Neurol. Sci. 84, 275–294 (1988).
Greising, S. M., Mantilla, C. B., Gorman, B. A., Ermilov, L. G. & Sieck, G. C. Diaphragm muscle sarcopenia in aging mice. Exp. Gerontol. 48, 881–887 (2013).
Murphy, M. et al. Transiently active Wnt/b-catenin signaling is not required but must be silenced for stem cell function during muscle regeneration. Stem Cell Rep. 3, 475–488 (2014).
Wu, S., Wu, Y. & Capecchi, M. R. Motoneurons and oligodendrocytes are sequentially generated from neural stem cells but do not appear to share common lineage-restricted progenitors in vivo. Development 133, 581–590 (2006).
Murphy, M. M., Lawson, J. A., Mathew, S. J., Hutcheson, D. A. & Kardon, G. Satellite cells, connective tissue fibroblasts and their interactions are crucial for muscle regeneration. Development 138, 3625–3637 (2011).
Schmalbruch, H. & Hellhammer, U. The number of nuclei in adult rat muscles with special reference to satellite cells. Anat. Rec. 189, 169–175 (1977).
Rodgers, J. T. et al. mTORC1 controls the adaptive transition of quiescent stem cells from G0 to G(Alert). Nature 510, 393–396 (2014).
McLoon, L. K. & Wirtschafter, J. Activated satellite cells are present in uninjured extraocular muscles of mature mice. Trans. Am. Ophthalmol. Soc. 100, 119–123 discussion 123–124 (2002).
Hebert, S. L., Daniel, M. L. & McLoon, L. K. The role of Pitx2 in maintaining the phenotype of myogenic precursor cells in the extraocular muscles. PLoS One 8, e58405 (2013).
Gage, P. J., Suh, H. & Camper, S. A. Dosage requirement of Pitx2 for development of multiple organs. Development 126, 4643–4651 (1999).
Kitamura, K. et al. Mouse Pitx2 deficiency leads to anomalies of the ventral body wall, heart, extra- and periocular mesoderm and right pulmonary isomerism. Development 126, 5749–5758 (1999).
Sambasivan, R. et al. Distinct regulatory cascades govern extraocular and pharyngeal arch muscle progenitor cell fates. Dev. Cell 16, 810–821 (2009).
Zhou, Y. et al. An altered phenotype in a conditional knockout of Pitx2 in extraocular muscle. Invest. Ophthalmol. Vis. Sci. 50, 4531–4541 (2009).
Marzetti, E. et al. Effects of short-term GH supplementation and treadmill exercise training on physical performance and skeletal muscle apoptosis in old rats. Am. J. Physiol. Regul. Integr. Comp. Physiol. 294, R558–R567 (2008).
Rice, K. M. & Blough, E. R. Sarcopenia-related apoptosis is regulated differently in fast- and slow-twitch muscles of the aging F344/N x BN rat model. Mech. Ageing Dev. 127, 670–679 (2006).
Smith, D. O. Muscle-specific decrease in presynaptic calcium dependence and clearance during neuromuscular transmission in aged rats. J. Neurophysiol. 59, 1069–1082 (1988).
Fry, C. S. et al. Inducible depletion of satellite cells in adult, sedentary mice impairs muscle regenerative capacity without affecting sarcopenia. Nat. Med. 21, 76–80 (2015).
Reinert, R. B. et al. Tamoxifen-induced Cre-loxP recombination is prolonged in pancreatic islets of adult mice. PLoS One 7, e33529 (2012).
Wan, Y., Otsuna, H., Chien, C. B. & Hansen, C. An interactive visualization tool for multi-channel confocal microscopy data in neurobiology research. IEEE Trans. Vis. Comput. Graph. 15, 1489–1496 (2009).
We thank M.M. Murphy for technical advice; L.K. McLoon and C.A. Peterson for helpful discussions; D.D. Cornelison and A.J. Merrell for critiques of the manuscript; and C. Rodesch and the Imaging Facility for microscopy support. Development of MuscleQNT by S.D.F. and M.Y. was supported by NIH R01GM088269 to M.Y. A.C.K was supported by NIH Hematology Grant (T32 DK007115) and M.P.C was supported by NIH Developmental Biology Grant (T32 HD07491). This work was supported by NIH R01 HD053728 and MDA 130903 to G.K.
The authors declare no competing financial interests.
About this article
Cite this article
Keefe, A., Lawson, J., Flygare, S. et al. Muscle stem cells contribute to myofibres in sedentary adult mice. Nat Commun 6, 7087 (2015). https://doi.org/10.1038/ncomms8087
Excess Glucose Impedes the Proliferation of Skeletal Muscle Satellite Cells Under Adherent Culture Conditions
Frontiers in Cell and Developmental Biology (2021)
Characterisation of stemness and multipotency of ovine muscle‐derived stem cells from various muscle sources
Journal of Anatomy (2021)
Comprehensive Reviews in Food Science and Food Safety (2021)
Mesenchymal Bmp3b expression maintains skeletal muscle integrity and decreases in age-related sarcopenia
Journal of Clinical Investigation (2021)