Abstract
Summary
A central question in adult stem cell biology is elucidating the signaling pathways regulating their dynamics and function in diverse physiological and age-related contexts. Muscle stem cells in adults (Satellite Cells; SCs) are generally quiescent but can activate and contribute to muscle repair and growth. Here we tested the role of the MuSK-BMP pathway in regulating adult SC quiescence by deletion of the BMP-binding MuSK Ig3 domain (‘ΔIg3-MuSK’). At 3 months of age SC and myonuclei numbers and myofiber size were comparable to WT. However, at 5 months of age SC density was decreased while myofiber size, myonuclear number and grip strength were increased - indicating that SCs had activated and productively fused into the myofibers over this interval. Transcriptomic analysis showed that SCs from uninjured ΔIg3-MuSK mice exhibit signatures of activation. Regeneration experiments showed that ΔIg3-MuSK SCs maintain full stem cell function. Expression of ΔIg3-MuSK in adult SCs was sufficient to break quiescence and increase myofiber size. We conclude that the MuSK-BMP pathway regulates SC quiescence and myofiber size in a cell autonomous, age-dependent manner. Targeting MuSK-BMP signaling in muscle stem cells thus emerges a therapeutic strategy for promoting muscle growth and function in the settings of injury, disease, and aging.
Highlights
MuSK, in its role as a BMP co-receptor, regulates adult muscle stem cell quiescence
The MuSK-BMP pathway acts cell autonomously
Increased muscle size and function with preservation of myonuclear density and stemness in mice with attenuated MuSK-BMP signaling
Introduction
Adult muscle stem cells (Satellite Cells; SCs), are key arbiters of muscle growth, homeostasis and regeneration(Keefe et al., 2015; Murach et al., 2021; Pawlikowski et al., 2017; Sambasivan et al., 2011; Sousa-Victor et al., 2022). SC function is tailored to the state of the muscle as well as to age. For example, during the first weeks of life large scale SC proliferation and fusion are essential for achieving mature muscle size and myonuclear complement. In mice, SCs contribute to normal myofiber growth until ∼8 weeks of age(Bachman et al., 2018; Bachman and Chakkalakal, 2022; Cramer et al., 2020; Gattazzo et al., 2020; Pawlikowski et al., 2015; White et al., 2010). After this age SCs in uninjured muscles are generally quiescent, but can activate to support muscle growth in response to load or exercise(Egner et al., 2016; Goh et al., 2019; Goh and Millay, 2017; Murach et al., 2021). SCs can also activate and proliferate following injury to effect muscle regeneration(Murphy et al., 2011; Sambasivan et al., 2011; Zammit et al., 2002). Finally, dysregulation of SC function with aging is thought to contribute to sarcopenia(Blau et al., 2015; Brack et al., 2005; Sousa-Victor et al., 2022).
A key question in SC biology is elucidating the signaling pathways that regulate their dynamics, particularly in age-related contexts. Known pathways include Notch-Delta, Wnts, Collagens V and VI, Cadherin and BMPs(de Morree and Rando, 2023; Fuchs and Blau, 2020; Kann et al., 2021). Notch signaling controls both satellite cell quiescence and is necessary for SC self-renewal following activation(Bjornson et al., 2012; Gioftsidi et al., 2022; Zhang et al., 2021). Muscle-derived Wnt4 maintains SC quiescence(Eliazer et al., 2019). Members of the TGFß superfamily also play important roles. Myostatin (GDF8) is a potent regulator of SC dynamics during early postnatal development, with its absence resulting in massive increases in muscle size. However, myostatin does not regulate SC activation in adults(Lee, 2022; Murphy et al., 2010). TGFß signaling is a negative regulator of myoblast fusion(Girardi et al., 2021). Bone morphogenetic proteins (BMPs), regulate cell proliferation and subsequent SC-mediated muscle growth in both development and during regeneration(Gozo et al., 2013; Ono et al., 2011; Stantzou et al., 2017). However, a role for BMP signaling in SC quiescence in adult muscle has not been described.
We recently reported that the transmembrane protein MuSK, in addition to its well-established role as an agrin-LRP4 receptor, is also a BMP co-receptor that shapes BMP-mediated transcriptional output in myogenic cells(Fish and Fallon, 2020; Jaime et al., 2024; Yilmaz et al., 2016). MuSK binds to BMPs as well as to the type I BMP receptors BMPR1a and BMPR1b (also termed ALK3 and ALK6, respectively). Cultured myogenic cells expressing MuSK show enhanced pSmad1/5/8 signaling and express a distinct set of transcripts in response to BMP stimulation compared to MuSK-/- cells. MuSK-dependent BMP signaling is dependent on Type I BMP receptor activity, but MuSK tyrosine kinase activity is dispensable. Importantly, the Ig3 domain of MuSK is necessary for high affinity BMP binding, while this region is not required for agrin-LRP4 signaling (which is mediated by the Ig1 domain). The role of MuSK as a BMP co-receptor is thus structurally and functionally distinct from its function in agrin-LRP4 signaling. We recently created a germline knock-in mouse model lacking the MuSK Ig3 domain(Jaime et al., 2024). These ‘ΔIg3-MuSK’ mice are viable and fertile and survive to at least 27 months of age. As predicted, myogenic cells isolated from these mice show reduced pSMAD and transcriptional responses to BMP, but normal agrin-LRP4-dependent activity. In that study we characterized these mice at 3 months of age and showed that the MuSK-BMP pathway maintains muscle size in the slow soleus muscle (but not in the fast TA) by regulating myofiber-intrinsic Akt-mTOR signaling.
Here we investigated the role of the MuSK-BMP pathway in SCs in both uninjured and regenerating fast TA and EDL muscles. We show that MuSK transcript and protein are expressed in WT and ΔIg3-MuSK SCs in uninjured muscle. At 3 months of age the ΔIg3-MuSK TA shows normal myofiber size and SC numbers. However, at 5 months SCs are activated and myonuclear number, myofiber size, muscle weight and grip strength are elevated. Notably, 5- month-old mutant muscles efficiently regenerate after injury and the SC pool and myofiber size is restored to WT levels, indicating that the ΔIg3-MuSK SCs maintain full stem cell function. Finally, conditional mutants established that the role of MuSK in regulating quiescence is SC-autonomous and is active in the adult. We conclude that MuSK expressed in SCs regulates quiescence and muscle growth in an age-dependent manner via its role as a BMP co-receptor.
Results
MuSK is expressed in satellite cells
Previous transcriptomic analyses have detected MuSK mRNA in quiescent, activated and regenerating SCs(Petrany et al., 2020; Shcherbina et al., 2020; Yue et al., 2020). We confirmed that MuSK transcripts are expressed in SCs isolated from uninjured and regenerating muscle from both 3- and 5- month old mice using gel-based PCR analysis (Fig. 1a-c; Supp. Fig 1a, b). This analysis also showed that all MuSK detected in WT SCs harbors the Ig3 domain (encoded by exons 6 and 7). For clarity we refer to the form containing the Ig3 domain as Full-Length (FL)-MuSK. We did not detect transcripts lacking the Ig3 domain (ΔIg3-MuSK) in isolated WT SCs (Fig. 1c). To detect MuSK protein in SCs we isolated myofibers from adult muscle and double labeled them with antibodies recognizing Pax7 and MuSK. As shown in Fig. 1d, MuSK protein is expressed in SCs from both WT and ΔIg3-MuSK mice.
Myofiber diameter and SC numbers are comparable in 3-month-old WT and ΔIg3-MuSK TA muscle
As a first step towards assessing the role of the MuSK-BMP pathway in SC dynamics we compared both SC number and myofiber diameter in WT and ΔIg3-MuSK TA from 3-month-old mice. We chose this time point since adult SC number and myonuclear content are established by this age and SCs are in their adult quiescent state(Ancel et al., 2021; Bachman and Chakkalakal, 2022; Cramer et al., 2020). Analysis of Pax7+ cells showed that their density was comparable in both genotypes at 3 months (Fig. 2a, c). TA myofiber diameter was also comparable in both genotypes at this age (Fig. 2a, b), which is in agreement with results in a related study(Jaime et al., 2024). These results indicate that the MuSK-BMP pathway does not play a discernable role in the developmental and early postnatal events that establish myofiber size and SC pool numbers in fast muscle.
Myofiber diameter is increased while SC numbers are reduced in 5-month-old ΔIg3-MuSK TA muscle
To determine whether the MuSK-BMP pathway plays a role in SC quiescence in older mice, we next assessed SC number and myofiber diameter at 5 months of age. Both measures showed striking differences between genotypes at this age. SC density in the 5-month-old TA was reduced by almost half in ΔIg3-MuSK compared to WT mice (19±2.1 and 10.6±1.4mm2 in WT vs ΔIg3-MuSK, respectively; n=9-10, p=0.004; Fig. 2a, c). On the other hand, myofiber diameter in ΔIg3-MuSK muscle was increased by ∼10% compared to WT (37 ±0.8µm and 41 ± 1.0µm in WT vs ΔIg3-MuSK, respectively; n=8, p=0.006; Fig. 2a, b).
Grip strength is increased in 5-month-old ΔIg3-MuSK mice
We next asked whether the increase in myofiber size observed in 5-month-old mice was associated with improved muscle function. We performed grip strength analysis of ΔIg3-MuSK male mice at 3- and 5- months of age. As shown in Fig. 2, grip strength is comparable between ΔIg3-MuSK and WT mice at 3 months. In contrast, at 5 months, male ΔIg3-MuSK mice display increased grip strength performance (Fig. 2d). This increase in grip strength was observed in 3 cohorts of male mice (Supp. Fig. 2). We also tested grip strength in one cohort of female mice. Although the average grip strength was higher in 5 month old ΔIg3-MuSK females compared to controls, this effect did not reach statistical significance (Supp. Fig. 2). Thus, muscle function is improved in 5- month-old male ΔIg3-MuSK animals.
Myonuclei numbers and myofiber lengths are increased in ΔIg3-MuSK EDL muscles at 5 months of age
The observation that SC numbers are decreased while myofiber diameter is increased in 5- month-old ΔIg3-MuSK TA muscle suggested that SCs in these adult muscles became activated and fused into the myofiber, thus contributing to its growth. To test this idea directly we counted the number of myonuclei in isolated myofibers from 5-month-old ΔIg3-MuSK and WT EDL muscles, an accessible and readily quantifiable model for such measurements. As shown in Fig. 3a, b, the number of myonuclei/myofiber was increased in ΔIg3-MuSK EDL muscle. In addition, the ΔIg3-MuSK myofibers were also longer (Fig. 3a, c). Importantly, the proportion of myonuclei per myofiber length is equivalent at both ages, suggesting that the size of the myonuclear domain is conserved (Fig. 3d). Taken together, these findings indicate that between 3 and 5 months of age in ΔIg3-MuSK muscle SCs become activated, divide, and fuse into the myofiber - resulting in increased length. Further, the conserved proportion of myonuclei/myofiber length indicates that this growth increase scales with the addition of the myonuclei to the myofiber.
Muscle regeneration and restoration of SC numbers following injury to ΔIg3-MuSK muscle
We next queried the role of ΔIg3-MuSK in muscle regeneration, a chief function of adult SCs. TA muscles from 5-month-old WT and ΔIg3-MuSK TA were injured on day 0 by BaCl2 injection and muscles were harvested at 3-, 5-, 7-, 14-, 22-, and 29-days post-injury (dpi; Fig. 4). We assessed muscle morphology, myofiber diameter, and SC density at each timepoint. The ΔIg3-MuSK muscle regenerated efficiently, with full restoration of muscle structure achieved by 22 dpi, which was comparable to WT (Fig. 4b, c, e). The regeneration rate was increased as judged by histoarchitecture (Fig. 4b, c), increased Pax7+ density at 5 dpi (Fig. 4d) and, in the male animals, increased myofiber diameter at 7 dpi (Fig. 4e). The increased Pax7+ cells at 5 dpi and the increased myofiber size at 7dpi indicate that the early stages of muscle regeneration are accelerated in ΔIg3-MuSK mice.
Notably, the myofiber diameters at the completion of regeneration (22 dpi) were comparable in both genotypes (Fig. 4e). Moreover, the density of SCs in the regenerated muscle (22 and 29 dpi) was indistinguishable in WT and ΔIg3-MuSK (Fig. 4d). This comparable restoration of myofiber size and SC density indicates that the intrinsic regulatory mechanisms governing SC dynamics during regeneration, including stemness and regenerative capacity, are maintained in ΔIg3-MuSK muscle.
MuSK expressed in adult SCs governs quiescence and myofiber hypertrophy
The studies presented above utilized mice with constitutive (germline) knock-in of the ΔIg3-MuSK allele. However, MuSK is also highly expressed by neuromuscular junction (NMJ) myonuclei, and at lower levels in subsets of myonuclei and interstitial cells(Jaime et al., 2024; Petrany et al., 2020; Zeng et al., 2022; Zhang et al., 2021). Thus, there were two key questions outstanding: 1) Is the function of the MuSK-BMP pathway in SC dynamics cell autonomous; and 2) are there developmental events regulated by this pathway that might contribute to its role in adult SCs? To address both these points we utilized tamoxifen-inducible, conditional Pax7CreERT2;R26RLSL- tdTomato;MuSK-Ig3loxP/loxP mice. These mice license the expression of ΔIg3-MuSK only in cells expressing Pax7 and at the age determined by the tamoxifen administration. In addition, it marks them with the TdTomato reporter. As a control, we used Pax7CreERT2;R26RLSL-tdTomato, in which tamoxifen injection induces TdTomato expression in Pax7+ cells, but the MuSK allele is unaffected. We induced Cre-recombination using tamoxifen administered at 3 months of age and then harvested the TA muscles at 5 months of age (Fig. 5a). PCR analysis of RNA isolated from pre-fixed, FACS-sorted SCs confirmed that the Cre-recombination of the floxed Ig3 domain of MuSK was effective (Supp. Fig. 3a, b). As shown in Fig. 5, Cre-mediated expression of ΔIg3-MuSK in SCs at 3 months resulted in an ∼9% increase in both muscle weight and myofiber diameter when assessed at 5 months of age (0.035±0.0007 and 0.038±0.0007 g, n=5-8 mice/group, p=0.007; and 36.0±0.78 and 39.3±1.2 µ, n=5-7 mice/group, p=0.037 for weights and diameters, respectively; Fig. 5). Finally, we also counted the number of myonuclei per myofiber in EDL muscles from the same animals (see Methods). Fig. 5e shows that there was an ∼22% increase in the myonuclear number in the Pax7CreERT2;R26RLSL-tdTomato;MuSK-Ig3loxP/loxP compared to controls (Pax7CreERT2;R26RLSL-tdTomato; 234.2±9.8 and 286. ±16.2, respectively, t-test, p=0.008; n=3 per genotype). The increased TA weight, myofiber size and myonuclear number observed in these experiments indicates that MuSK acts in a SC-autonomous manner and that the expression of MuSK in the adult SC is sufficient for this role.
SCs are activated in uninjured ΔIg3-MuSK muscle
The results presented above indicate that the MuSK-BMP pathway is important for maintaining SC quiescence in resting adult muscle, and that perturbation of this pathway leads to the activation of these stem cells. To provide direct evidence for such activation and to gain insight to the mechanistic basis of this state change we interrogated the gene expression of FACs-sorted SCs from uninjured 5-month-old WT and ΔIg3-MuSK muscle (n= 6 animals/genotype). To preclude artefactual activation during cell isolation, animals were perfusion-fixed prior to harvest. We then used the NanoString nCounter Stem Cell Characterization Panel to assess gene expression in WT and ΔIg3-MuSK SCs. This panel includes 770 genes involved in multiple stem cell types including stem-cell regulatory signaling pathways, epigenetics, metabolism, differentiation signaling, and lineage specification. Hierarchical clustering revealed significant changes (p < 0.05) in the expression of 21 of the genes in this panel. Nineteen of the differentially expressed genes (DEGs) were upregulated including TBLX1, HDAC2, PPP2R2A, SMAD4, CAP2, CREBBP, MDH1, NCOR1, RRAGC and CUL1; while two genes, XIST and CACYBP, were downregulated (Fig. 6a, b).
We next asked whether the set of DEG SC genes detected in uninjured ΔIg3-MuSK were characteristic of an activated state. We compared the hits in the ΔIg3-MuSK nCounter set to a published RNAseq dataset of SC DEGs from resting and injured (1 dpi) WT muscle from young (2-3 months) and aged (20-22 months) muscle (GSE121589; Shcherbina et al., 2020). Our analysis revealed striking similarities in the sets of SC DEGs from uninjured ΔIg3-MuSK and damaged WT muscles. As shown in Fig. 6a, b, 17 of the 19 upregulated genes in uninjured ΔIg3-MuSK SCs are also upregulated in SCs from old and/or young activated WT SCs. XIST, one of the two genes downregulated in ΔIg3-MuSK SCs, was also reduced in both young and aged SCs from damaged WT muscle. This concordance of gene expression patterns indicates that ΔIg3-MuSK SCs in 5-month-old uninjured muscle are in a state of early activation.
Discussion
Our results establish that the BMP co-receptor MuSK regulates SC quiescence in adult muscle in a cell-autonomous fashion. Importantly, perturbation of this pathway leads to SC activation, proliferation, and fusion - culminating in increased muscle weight and grip strength. Stemness is maintained (Fig. 7). Below we discuss these novel features of adult SC quiescence and MuSK function as well as their implications for therapeutic development for muscle wasting conditions.
MuSK regulates SC quiescence in a cell autonomous manner. MuSK transcript and protein are expressed in SCs (Fig. 1). This finding is in accord with snRNAseq studies showing MuSK transcript in quiescent SCs(Petrany et al., 2020; Shcherbina et al., 2020; Tabula Muris Consortium et al., 2018; Zeng et al., 2022). Our results also show that quiescent SCs express ‘full length’ MuSK transcript encoding the Ig3 domain (Fig. 1; Supp. Fig. 1). This point is noteworthy since the Ig3 domain can be endogenously spliced(Garcia-Osta et al., 2006; Hesser et al., 1999). Finally, conditional expression of ΔIg3-MuSK in SCs at 3 months of age is sufficient to phenocopy the increase in myofiber size and myonuclear numbers observed in germ line mutants. Thus, MuSK containing its Ig3 domain is necessary for maintaining adult SC quiescence.
Several lines of evidence indicate that MuSK in SCs functions through its role as a BMP co-receptor, and not as an agrin-LRP4 receptor. Biochemical studies show that MuSK binds BMPs with high affinity in a manner requiring its Ig3 domain(Yilmaz et al., 2016). Quiescent SCs express BMP signaling machinery, including BMP4 as well as BMPR1a, which also binds to MuSK(Petrany et al., 2020; Shcherbina et al., 2020; Yilmaz et al., 2016; Zeng et al., 2022). Cultured ΔIg3-MuSK myoblasts have reduced BMP4 responses as assessed by pSMAD signaling and transcriptional output(Jaime et al., 2024). In contrast, the data does not support a role for MuSK acting as an agrin-LRP4 receptor in SCs: 1) Agrin-induced AChR clustering, which is mediated by its interaction with LRP4, is comparable in ΔIg3-MuSK and WT myotubes(Jaime et al., 2024); 2) NMJ formation, maintenance, AChR density and cholinergic signaling is comparable in WT and ΔIg3-MuSK muscle. Interestingly, NaV1.4 density and muscle excitability is reduced, suggesting that the MuSK-BMP pathway plays distinct roles from agrin-LRP4 at the NMJ (Fish et al., 2023); ( 3) MuSK’s function as a BMP co-receptor requires neither its TK activity nor the juxtamembrane tyrosine critical for DOK7 binding – features necessary for agrin-LRP4 activity(Jaime et al., 2024). 4) The MuSK Ig3 domain is dispensable for agrin-LRP binding and signaling, which is mediated by its Ig1 domain(Hesser et al., 1999; Stiegler et al., 2006; Yilmaz et al., 2016; Zong et al., 2012). To our knowledge this is the first report implicating BMP signaling in adult SC quiescence. It will be of interest to test whether MuSK also plays a role in the BMP-mediated quiescence regulation in other settings, such as neural stems cells(Díaz-Moreno et al., 2018; Mira et al., 2010; Tunc-Ozcan et al., 2021). Finally, the deployment of MuSK, which has a highly restricted cell type and tissue distribution, as a co-receptor could be an evolutionary solution to the general problem of conferring context selectivity to the near-universally expressed BMPs and their core signaling machinery(Hogan, 1996; Massagué, 2012).
Our results show that adult ΔIg3-MuSK satellite cells are activated in uninjured muscle. First, SCs density decreases by ∼50% from 3- to 5- months of age in the ΔIg3-MuSK TA. Second, transcriptomic analysis shows that the expression profile of SCs from uninjured adult muscle is remarkably similar to that observed in WT muscle 1 day post injury (Fig. 6;(Shcherbina et al., 2020). Third, the accelerated muscle regeneration following injury observed in ΔIg3-MuSK mice mirrors that observed in other settings where SCs are activated, such as deletion of the myofiber-derived quiescence factor Wnt4 or injury to the contralateral muscle(Eliazer et al., 2019; Rodgers et al., 2014). This accelerated regeneration likely reflects a more rapid re-entry into the cell cycle(Siegel et al., 2011).
MuSK plays a selective role in maintaining adult SC quiescence. SCs are highly dynamic and assume multiple critical states including, quiescence, activation, proliferation, fusion into myofibers, and re-entry into quiescence. Adult SCs expressing ΔIg3-MuSK SC break quiescence and become activated, but their ability to proliferate and fuse into myofibers is preserved. By 5- months of age the ΔIg3-MuSK EDL has increased length, adding an average of 40 myonuclei/myofiber compared to WT (Fig. 3a, c). As EDL myofibers contain only ∼7 SCs each, the activated SCs must undergo at least 3 rounds of cell division over this time span, followed by fusion into the myofiber. These traits distinguish the MuSK-BMP pathway from many other mechanisms mediating quiescence. For example, manipulation of Notch, Foxo3 or Pten signaling breaks quiescence, but the SC pool is depleted and self-renewal is impaired(García-Prat et al., 2020; Gioftsidi et al., 2022; Yue et al., 2017). Disruption of the M- and N- cadherins or Wnt4a from the myofiber results in expansion of the SC pool, but no fusion or changes in myofiber diameter were reported(Eliazer et al., 2019; Goel et al., 2017). Finally, interfering with the ColV-Calcitonin receptor pathway in SCs leads to spontaneous differentiation and fusion, but SCs were fewer and myofibers smaller following damage(Baghdadi et al., 2018; Zhang et al., 2019). Taken together, these results indicate that MuSK-BMP signaling restrains SC activation, but is dispensable for proliferation and productive fusion into uninjured myofibers. Notably, all three of these activities are critical for SCs to contribute to the muscle growth and improved strength such as observed here. Importantly, following injury myofiber size and SC complement are restored to WT levels, indicating that MuSK-BMP signaling is not required for regeneration, to maintain stemness, or for re-entry into the SC niche. Moreover, the normal fiber size and SC complement observed in germ line mutants at 3 months indicates that the MuSK-BMP pathway does not play a discernable role in SCs in developing and young mice, a conclusion supported by the results with conditional expression of ΔIg3-MuSK in SCs starting at 3 months (Fig. 5). Finally, the adult-selective role of the MuSK-BMP pathway is distinct from myostatin (GDF8), which has profound effects on SCs proliferation and hyperplasia during early postnatal development, but does not regulate SC quiescence in adult muscle(Lee, 2022; Murphy et al., 2010).
The MuSK-BMP pathway represents an attractive therapeutic target to combat muscle wasting and promote regeneration. Muscle size and function are compromised in settings including muscular dystrophies, cancer cachexia, disuse atrophy, age-related sarcopenia, and GLP-1 agonist use (Bikou et al., 2024; Chamberlain and Olwin, 2010; Ham et al., 2022; Shavlakadze et al., 2019). Muscle growth is limited by myonuclear complement(Cramer et al., 2020). SCs are present in these situations and represent a potential source of new myonuclei. However, the SCs in disease and aging are often in deep quiescence due to degradation of the niche and the accumulation of negative signals countering activation(Brunet et al., 2023; Cosgrove et al., 2014; Kimmel et al., 2020; Liu et al., 2017). Notably, MuSK levels are increased in mouse models of denervation and Myasthenia Gravis as well as in aging humans, suggesting that full length MuSK may generate one such negative signal(Bowen et al., 1998; Lehallier et al., 2019; Mori et al., 2023). Targeting this pathway could also promote longevity and healthy aging. Reducing MuSK-BMP signaling to promote SC activation is an attractive, highly specific target given the restricted tissue distribution of MuSK(Tabula Muris Consortium et al., 2018), combined with the precise modulation of the Ig3 domain as demonstrated genetically in this report. Pharmacological targeting could be achieved, for example, by splice-modulating antisense oligonucleotides or antibodies directed against the MuSK Ig3 domain. The normal life span of mice with germ line expression of ΔIg3-MuSK suggests a favorable safety profile for such therapeutic interventions.
Materials and methods
Mice
Mice were bred and housed at the Brown University Animal Care Facility (ACF). Animals were group-housed in cages of up to five animals. All procedures were approved by the Institutional Animal Care and Use Committee (IACUC) at Brown University and done in accordance with institutional guidelines for animal care.
Germ line MuSKΔIg3/ΔIg3 mice, referred to throughout this paper as ‘ΔIg3-MuSK’ mice, were generated by Crispr-mediated removal of exons 6 and 7 of MuSK, which encode the Ig3 domain and were on the C57Bl/6 background. Details of the production and characterization of this model have been reported(Jaime et al., 2024).
For conditional mutations we generated a MuSK-Ig3loxP/loxP mouse using CRISPR/Cas9, in which the exons encoding the Ig3 domain of MuSK (exons 6 and 7) are flanked with loxP sites. Tamoxifen-inducible Pax7CreERT2;R26RLSL-tdTomatomice were provided by Bradley Olwin(Pawlikowski et al., 2015). These lines were crossed to generate Pax7CreERT2;R26RLSL-tdTomato;MuSK-Ig3loxP/loxPmice. Recombination was induced with five daily intraperitoneal (IP) injections of tamoxifen (Sigma-Aldrich) in corn oil dosed at 0.1 mg tamoxifen/ g mouse weight. Mice were treated with tamoxifen at 3 months of age to induce Cre-recombination (Supp. Fig. 2).
Muscle Harvest
For Pax7 antibody staining muscles were harvested from perfusion-fixed animals. Briefly, animals were anesthetized using 2,2,2-Tribromoethanol (250 mg/kg, Sigma Aldrich) followed by perfusion with 20mL of 4% PFA in PBS prior to TA harvest. Muscles were dehydrated in 30% sucrose in PBS overnight, frozen in OCT using liquid nitrogen, and stored at −80°C. In other experiments mice were euthanized with CO2 followed by cervical dislocation. TA muscles were then flash frozen using freezing isopentane and stored at −80°C.
Immunohistochemistry
Frozen sections (10µm) were obtained on a Leica Cryostat. Sections from flash frozen muscle were post-fixed in 4% paraformaldehyde (PFA) for 10 minutes at room temperature. Tissue sections and isolated myofibers were permeabilized with 0.25% Triton-X100 (Sigma-Aldrich) in PBS followed by blocking with 2% bovine serum albumin (Sigma-Aldrich) and 5% goat serum (Thermo Fisher) in PBS. Sections and myofibers that were stained with anti-Pax7 antibody (DSHB) also included a block with 1:50 Mouse on Mouse Ig Blocking Reagent (MKB-2213, Vector Labs). Incubation with primary antibody was at 4°C overnight followed by incubation with secondary antibody at room temperature for 1 hr. To visualize EdU incorporation, the Click-it Plus EdU Cell Proliferation kin, Alexa flour-488 kit (C10637, Thermo-Fisher) was used following the manufacturer’s instructions. Primary antibodies were 1:20 anti-Pax7 (Developmental Studies Hybridoma Bank), 1:1000 rabbit anti-laminin (L9393, Sigma-Aldrich), MuSK myasthenia gravis (MG) patient IgG4 fraction was generously provided by M. Huijbers(Huijbers et al., 2013). Secondary antibodies against IgG1 or IgG of the appropriate species were conjugated to Alexa-488, Alexa-555, or Alexa-647 (Invitrogen) and used at 1:1000. Myofibers were incubated with 1µg/mL DAPI (D1306, Invitrogen) for 5 minutes at room temperature and then mounted in Mowiol supplemented with DABCO (Sigma-Aldrich) as an anti-fade agent. Sections were mounted with Vectashield+DAPI as an anti-fade agent (Vector Laboratories).
Immunofluorescence
Immunofluorescence imaging was performed using a Nikon E800, a Nikon Ti2-E Widefield, or a Zeiss LSM 800 Confocal Microscope. Data acquisition was performed using the Zen software (blue edition, Zeiss). Images used for Pax7 counting and myofiber size analysis were collected and scored blinded.
Myofiber cross sectional size
ΔIg3-MuSK mouse muscles used for myofiber cross sectional size analysis were from perfusion fixed animals and Pax7CreERT2;R26RLSL-tdTomato;MuSK-Ig3loxP/loxP muscles used for myofiber cross sectional size analysis were from flash frozen muscle. Images of TA muscle sections immunostained with anti-laminin antibody (L9393, Sigma-Aldrich) and captured using a Nikon E800 fluorescent microscope or with a Zeiss LSM 800 Confocal Microscope with a 20X objective (images within the same experiment were captured using the same microscope). Images were processed using MyoVision software to determine minimum Feret diameter measurements for each myofiber(Briguet et al., 2004; Wen et al., 2018). Output images were manually examined, and any misidentified fibers were excluded, 650-1800 fibers examined per mouse. Representative images were acquired with a Zeiss LSM 800 Confocal Laser Scanning Microscope with a 20x objective. The average myofiber min Feret diameter for each mouse was used for statistical analysis using an unpaired t-test in GraphPad Prism 9. Analysis was done blinded.
Intact myofiber isolation
Extensor digitorum longus (EDL) muscle was dissected and enzymatically digested in 400-U/mL collagenase II (Worthington) at 37°C for 1.5 hours. Collagenase was inactivated by the addition of DMEM supplemented with 15% horse serum. Flame-polished Pasteur pipettes were used to agitate and separate individual myofibers, which were then immediately fixed in 4% paraformaldehyde for 10 minutes, followed by 3 washes of PBS prior to any immunostaining.
Intact myofiber myonuclei and length quantification
After immunostaining myofibers (see “Immunohistochemistry” methods), z-stacked tiled images were taken of whole myofibers with a Nikon Ti2-E Widefield Fluorescence Microscope using Zen software (blue edition, Zeiss). The automated measurement function was used to quantify all DAPI stained nuclei as well as total myofiber length.
Grip Strength
Grip strength analysis was done to assess front-limb muscle strength of WT and ΔIg3-MuSK male and female mice at 3 and 5.5 months of age. Mice were lifted by their tail and guided to use both front paws to grasp the pull-bar assembly connected to the grip strength meter (Columbus Instruments). The mouse was pulled away from the sensor until their grip on the bar was broken and the peak amount of force in kilograms per unit force (KGF) was recorded. Five trials were performed sequentially per animal and then averaged together and normalized to mouse weight. Analysis was done blinded to genotype.
Muscle injury & EdU delivery
Briefly, 5-month-old mice were anesthetized with isoflurane (induced with 4% isoflurane, maintained at ∼1.5% isoflurane and 400 mL O2 per min) and placed on a temperature-controlled platform to maintain core body temperature between 35°C and 37°C. Injury to the left TA muscle was induced by first piercing the muscle with a 28-gauge needle ∼15 times followed by injection of 50μL of 1.2% BaCl2 in PBS. To relieve pain, mice were treated with 0.5mg/mL of Buprenorphine Sustained-Release (Bup-SR) at the time of injury. For EdU labeling, mice received 50mg/kg 5- ethynyl-2’-deoxyuridine (EdU, Thermo Fisher) in PBS by intraperitoneal injection 24 hr before harvest. Injured muscle was harvested at 3-, 5-, 7-, 14-, 22-, and 29-days post injury (dpi). Control muscle from uninjured mice was also collected.
Satellite cell isolation and FACS sorting
To prevent artificial activation of quiescent SCs during isolation, mice were perfusion fixed with 0.5% PFA and then muscle was digested with collagenase II (Worthington) as described(Yue et al., 2020; Yue and Cheung, 2020). Pooled hind limb muscles were used for analysis of SCs from resting muscle and pooled TA muscles were used for analysis of SCs from regenerating muscle 5 dpi. The resulting cell suspension was blocked with DMEM + 15% horse serum (Cytiva sh30074) for 10 min at 4°C with rocking. Cells were then incubated for 45 min at 4°C with rocking with 1:250 of each of the following antibodies: Negative selection markers: BV421 Rat anti-mouse anti-CD31 (562939, BD Biosciences), and BV421 Rat anti-mouse CD45 (563890, BD Biosciences), BV421 Rat anti-Mouse Ly-6aA/E (562729, BD Biosciences); positive selection marker: Mouse anti-integrin alpha 7 Alexa fluor 647 (FAB3518R, R&D Systems). Cells were rinsed, resuspended in PBS and sorted using a BD FACSAria IIu cell sorter equipped with 355nm, 407nm, 488nm, 561nm, and 633nm lasers. The machine was optimized for purity and viability. UltaComp eBeads were used for calibration (01-222-41, Thermo Scientific). Total RNA was isolated from FACS-sorted SCs using a miRNeasy FFPE Kit (Qiagen) as described(Yue and Cheung, 2020).
Nanostring nCounter assay
RNA from SCs of 5 - 5.5-month-old resting muscle (n=6/genotype) was isolated as outlined above and samples from all mice were kept separate. Gene expression was analyzed with a Nanostring nCounter Stem Cell Characterization panel (NanoString Technologies). Multiplex gene expression with 770 genes was performed by measurement of the abundance of each mRNA transcript of interest using multiplexed hybridization and digital readouts of fluorescent bar-coded probes that are hybridized to each transcript. Hybridization of samples was performed, and the obtained products were run according to the manufacturer’s instructions. Data were collected on the nCounter Sprint profiler and further analyzed by ROSALIND® (https://rosalind.bio/), with a HyperScale architecture developed by ROSALIND, Inc. (San Diego, CA). Read Distribution percentages, violin plots, identity heatmaps, and sample MDS plots were generated as part of the QC step.
ROSALIND® follows the nCounter® Advanced Analysis protocol of dividing counts within a lane by the geometric mean of the normalizer probes from the same lane. Housekeeping probes to be used for normalization are selected based on the geNorm algorithm as implemented in the NormqPCR R library(Perkins et al., 2012). Fold changes and p values are calculated using the fast method as described in the nCounter® Advanced Analysis 2.0 User Manual. P-value adjustment is performed using the Benjamini-Hochberg method of estimating false discovery rates (FDR). Clustering of genes for the final heatmap of differentially expressed genes was done using the Partitioning Around Medoids method using the fpc R library(Hennig, n.d.) that takes into consideration the direction and type of all signals on a pathway, and the position, role and type of every gene. Hypergeometric distribution was used to analyze the enrichment of pathways, gene ontology, domain structure, and other ontologies. The topGO R library(Alexa and Rahnenfuhrer, n.d.) was used to determine local similarities and dependencies between GO terms in order to perform Elim pruning correction. Several database sources were referenced for enrichment analysis, including Interpro(Mitchell et al., 2019), NCBI(Geer et al., 2010), MsigDB(Liberzon et al., 2011; Subramanian et al., 2005), REACTOME (Fabregat et al., 2018), WikiPathways(Slenter et al., 2018). Enrichment was calculated relative to a set of background genes relevant for the experiment. Gene expression data was exported and heat maps were generated in GraphPad prism 9.
RNA-sequencing analysis of SC dataset
An RNA-sequencing dataset (GSE121589) from NCBI’s Gene Expression Omnibus database was analyzed(Shcherbina et al., 2020). This data set includes bulk RNA-seq of isolated SCs from young (2-3 mo. old) and aged (22-24 mo. old) muscle from uninjured and from regenerating muscle at 1, 3, 5, and 7 dpi. The raw data files were reprocessed by trimming adapters and low quality reads using TrimGalore! followed by alignment to the Ensembl GRCm38 mouse genome using HiSat2(Kim et al., 2015). StringTie was used to determine the transcripts per million (TPM) of genes in each sample and DESeq2 was used to identify differentially expressed genes (DEGs)(Love et al., 2014; Pertea et al., 2016). Expression of DE genes identified with the nCounter panel were assessed. Highly regulated genes between quiescent SCs (day 0) and early-activated SCs (day 1 and 3 post injury) were indicated by significant (<0.05) change in TPM.
Statistics
Statistical analysis was performed with GraphPad Prism software using appropriate tests and minimum of 95% confidence interval for significance. Specific details of the statistical tests are given in the figure legends.
Acknowledgements
We thank Beth McKechnie for expert technical assistance and Youngwook Ahn of the Brown Transgenic core for generating the ΔIg3-MuSK mice. We thank K. O’Connor for generously providing the anti-MuSK monoclonal antibody and M. Huibers for the MuSK-MG patient IgG4 fraction. We thank G. Williams and the Brown Leduc Bioimaging Facility, K. Carlson & the Brown Flow Cytometry and Cell Sorter Facility, and C. Schorl and the Brown Genomics Facility for experimental assistance. Support: Brown University COBRE Center for Computational Biology: P20 GM10903; Mouse Transgenic and Gene Targeting Facility: P30 GM103410; Genomic Facility: P30 RR031153, P20 RR018728, S10 RR02763, NSF EPSCoR 0554548; DJ: 4R25GM083270 and 2T32AG041688; JRF: NIH awards U01 NS064295, R41 AG073144, R21 NS112743, R21 AG073743, and ALS Finding a Cure.
Data Availability
The primary data, mouse models and reagents related to this work will be available to interested researchers upon reasonable request.
Additional information
Author contributions
LAM designed, performed, and interpreted all experiments, wrote manuscript; DJ created the MuSKΔIg3/ΔIg3 (ΔIg3-MuSK) and MuSK-Ig3loxP/loxP mice; IC analyzed data, edited the manuscript and created Fig. 7. JRF designed and interpreted experiments, wrote manuscript.
Competing Interests
The authors are co-inventors on patents to Brown University covering manipulation of the MuSK-BMP pathway. JRF is a co-founder of Bolden Therapeutics, which has licensed these patents.
Supplemental material
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