Project description:Purpose: To study the requirement of Osr1 expression for FAP function during skeletal muscle regeneration. Methods: We sequenced total mRNAs isolated from adult FAPs FACS sorted from 3 and 7 day post injured hindlimb skeletal muscle of Ctrl (Osr1flox/+ CAGG Cre+) and Osr1 cKO (Osr1flox/flox CAGG Cre+) mice. Results: Loss of Osr1 leads to pro-fibrotic orientation of FAPs and impairs both FAP-macrophage and FAP-MuSCs communication network resulting in impaired regenerative myogenesis and persistent fibrosis. Conclusions: Osr1 is a key transcriptional regulator of FAP regenerative function protecting FAPs from assuming a detrimental pro-fibrotic and anti-myogenic state.

Project description:During aging, the number and functionality of muscle stem cells (MuSCs) decreases leading to impaired regeneration of aged skeletal muscle. In addition to intrinsic changes in aged MuSCs, extracellular matrix (ECM) proteins deriving from other cell types, e.g., fibrogenic-adipogenic progenitor cells (FAPs), contribute to the aging phenotype of MuSCs and impaired regeneration in the elderly. So far, no comprehensive analysis on how age-dependent changes in the whole skeletal muscle proteome affect MuSC function have been conducted. Here, we investigated age-dependent changes in the proteome of different skeletal muscle types by applying deep quantitative mass spectrometry. We identified 183 extracellular matrix proteins that show different abundances in skeletal muscles of old mice. By integrating single cell sequencing data, we reveal that transcripts of those ECM proteins are mainly expressed in FAPs, suggesting that FAPs are the main contributors to ECM remodelling during aging. We functionally investigated one of those ECM molecules, namely Smoc2, which is aberrantly expressed during aging. We show that Smoc2 levels are elevated during regeneration and that its accumulation in the aged MuSC niche causes impairment of MuSCs function through constant activation of integrin/MAPK signaling. In vivo, supplementation of exogenous Smoc2 hampers the regeneration of young muscles following serial injuries, leading to a phenotype reminiscent of regenerating aged skeletal muscle. Taken together, we provide a comprehensive resource of changes in the composition of the ECM of aged skeletal muscles, we pinpoint the cell types driving these changes, and we identify a new niche protein causing functional impairment of MuSCs thereby hampering the regeneration capacity of skeletal muscles.

Project description:During aging, the number and functionality of muscle stem cells (MuSCs) decreases leading to impaired regeneration of aged skeletal muscle. In addition to intrinsic changes in aged MuSCs, extracellular matrix (ECM) proteins deriving from other cell types, e.g., fibrogenic-adipogenic progenitor cells (FAPs), contribute to the aging phenotype of MuSCs and impaired regeneration in the elderly. So far, no comprehensive analysis on how age-dependent changes in the whole skeletal muscle proteome affect MuSC function have been conducted. Here, we investigated age-dependent changes in the proteome of different skeletal muscle types by applying deep quantitative mass spectrometry. We identified 183 extracellular matrix proteins that show different abundances in skeletal muscles of old mice. By integrating single cell sequencing data, we reveal that transcripts of those ECM proteins are mainly expressed in FAPs, suggesting that FAPs are the main contributors to ECM remodelling during aging. We functionally investigated one of those ECM molecules, namely Smoc2, which is aberrantly expressed during aging. We show that Smoc2 levels are elevated during regeneration and that its accumulation in the aged MuSC niche causes impairment of MuSCs function through constant activation of integrin/MAPK signaling. In vivo, supplementation of exogenous Smoc2 hampers the regeneration of young muscles following serial injuries, leading to a phenotype reminiscent of regenerating aged skeletal muscle. Taken together, we provide a comprehensive resource of changes in the composition of the ECM of aged skeletal muscles, we pinpoint the cell types driving these changes, and we identify a new niche protein causing functional impairment of MuSCs thereby hampering the regeneration capacity of skeletal muscles.

Project description:In our study, we used hindlimb unloading rat model to study fibro-adipogenic progenitor cells (FAPs) condition in muscle atrophy. We have purified FAPs from m. soleus from control rats and after 7 and 14 days of immobilization (HS7, HS14). Also, we performed adipogenic differentiation of FAPS in vitro during 3 days.

Project description:Skeletal muscle experiences a decline in lean mass and regenerative potential with age, in part due to intrinsic changes in progenitor cells. However, it remains unclear if age-related changes in progenitors persist across a differentiation trajectory or if new age-related changes manifest in differentiated cells. To investigate this possibility, we performed single cell RNA-seq on muscle mononuclear cells from young and aged mice and profiled muscle stem cells (MuSCs) and fibro/adipose progenitors (FAPs) after differentiation. Differentiation increased the magnitude of age-related change in MuSCs and FAPs, but also masked a subset of age-related changes present in progenitors. Using a dynamical systems approach and RNA velocity, we found that aged MuSCs follow the same differentiation trajectory as young cells, but stall in differentiation near a commitment decision. Our results suggest that age-related changes are plastic across differentiation trajectories and that fate commitment decisions are delayed in aged myogenic cells.

Project description:The purpose of this study is to investigate how GDF10 regulates early myoblast differentiation and fusion. We found that melatonin can enhance fibro-adipogenic progenitors (FAPs) paracrine signaling to support muscle regeneration. Through combining transcriptome analysis and single-cell transcriptome analysis, we identified GDF10 as a type of myogenic factor specifically secreted by FAPs, which plays a beneficial role in promoting muscle fiber development and regeneration. To determine the underlying mechanism by which GDF10 regulates myogenesis, we performed RNA-seq on myoblasts treated with GDF10 or vehicle for 6 hours in vitro. We found that GDF10 promoted myoblast fusion by regulating LKB1-AMPK-MYOG-MYMK signaling during differentiation. In summary, our study revealed novel insights into the mechanism by which melatonin promotes muscle regeneration by mediating the interplay between FAPs and muscle stem cells (MuSCs).

Project description:Injured skeletal muscle regenerates, but with age or in muscular dystrophies, muscle is replaced by fat. Upon injury, muscle-resident fibro/adipogenic progenitors (FAPs) proliferated and gave rise to adipocytes. These FAPs dynamically produced primary cilia, structures that transduce intercellular cues such as Hedgehog (Hh) signals. Genetically removing cilia from FAPs inhibited intramuscular adipogenesis, both after injury and in a mouse model of Duchenne muscular dystrophy. Blocking FAP ciliation also enhanced myofiber regeneration after injury and reduced myofiber size decline in the muscular dystrophy model. Hh signaling through FAP cilia regulated the expression of TIMP3, a secreted metalloproteinase inhibitor, that inhibited MMP14 to block adipogenesis. A pharmacological mimetic of TIMP3 blocked the conversion of FAPs into adipocytes, pointing to a strategy to combat fatty degeneration of skeletal muscle. We conclude that ciliary Hh signaling by FAPs orchestrates the regenerative response to skeletal muscle injury.

Project description:The purpose of this study is to investigate how immune cells (macrophages) are closely linked with fibro-adipogenic progenitors (FAPs) during recovery processe. We report that the depletion of Mrc1+ (gene encoding CD206) M2-like macrophages promoted the recovery of muscle after injury. A total RNA sequence analysis of whole muscle or isolated FAPs revealed that the depletion of Mrc1+ M2-like macrophages resulted in the activation of FAPs. Activated FAPs secrete follistatin (Fst), a promyogenic factor, boosting the recovery process. We further determined that the knockdown of FAPs-derived Fst delayed the recovery process. Mechanistically, Mrc1+ M2-like macrophages-specific TGF-b1 inhibited the activation of FAPs, and the FAPs failed to secrete Fst.

Project description:In Duchenne Muscular Dystrophy (DMD), the absence of the subsarcolemmal dystrophin protein leads to repeated myofiber damages inducing cycles of muscle regeneration that is driven by muscle stem cells (MuSCs). With time, MuSC regenerative capacities are overwhelmed, leading to fibrosis and muscle atrophy. Whether MuSCs from DMD muscle have intrinsic alterations or are primed by their degenerative/regenerative environment is still debated. We investigated gene expression in human using primary MuSCs derived from DMD or healthy muscles. Cells were isolated from the muscle and bulk expanded then purified as CD56positive cells (CD56 is a myogenic marker that characterizes the myogenic nature of the cells). Human MuSCs loose the expression of the CD56 with time. We analyzed gene expression by CD56positive and CD56negative cells originating from the same initial CD56positive MuSC population.

Project description:A mechanistic understanding of the age-related impairment to skeletal muscle regrowth following disuse atrophy as well as therapies to augment recovery in the aged are currently lacking. Mechanotherapy in the form of cyclic compressive loading has been shown to benefit skeletal muscle under a variety of paradigms, but not during the recovery from disuse in aged muscle. To determine whether mechanotherapy promotes extracellular matrix (ECM) remodeling, a critical aspect of muscle recovery after atrophy, we performed single cell RNA sequencing (scRNA-seq) of gastrocnemius muscle cell populations, stable isotope tracing of intramuscular collagen, and histology of the ECM in adult and aged rats recovering from disuse, with and without mechanotherapy. ECM remodeling-related gene expression in fibro-adipose progenitor cells (FAPs) was absent in aged compared to adult muscle following 7 days of recovery, and instead were enriched in chemoattractant genes. There was a significantly lower expression of genes related to phagocytic activity in aged macrophages during recovery, despite enriched chemokine gene expression of numerous stromal cell populations, including FAPs and endothelial cells. Mechanotherapy reprogrammed the transcriptomes of both FAPs and macrophages in aged muscle recovering from disuse to restore ECM-and phagocytosis-related gene expression, respectively. Stable isotope labeling of intramuscular collagen and histological evaluation confirmed mechanotherapy-mediated remodeling of the ECM in aged muscle recovering from disuse. In summary, our results highlight mechanisms underlying age-related impairments during the recovery from disuse atrophy and promote mechanotherapy as an intervention that reprograms the muscle transcriptional environment more similar to that of adult skeletal muscle.