Project description:Sarcopenia, the age-related loss of muscle mass and strength, is characterized by impaired muscle repair and increased deposition of fibrotic tissue. Yet, the specific role of individual cell types in the development of fibrosis remains poorly defined. Here, we report that aged muscle stem cells (MuSCs) directly instruct fibro-adipogenic progenitors (FAPs) to proliferate and adopt a fibrogenic phenotype. Polycomb Ezh2-/- or aged mice exhibited regenerative defects, FAP expansion, fibrosis, and elevated levels of MuSC-secreted interleukin 6 (IL-6) and Spp1/Osteopontin. In aged MuSCs, H3K27me3 erosion at the NF-kB gene correlated with increased expression and enhanced chromatin recruitment at the IL-6 and Spp1 genes, leading to their activation. Blocking IL-6 and Spp1 signaling in co-cultures of aged MuSC and FAPs, or aged mice, reduced FAP proliferation and muscle fibrosis. In summary, our results indicate that aged MuSCs instruct FAPs to proliferate and acquire a fibrogenic phenotype through a mechanism involving epigenetically-mediated derepression of NF-kB and increased activation of IL-6 and Spp1- both of which are potential pharmacological targets.

Project description:Sarcopenia, the age-related loss of muscle mass and strength, is characterized by impaired muscle repair and increased deposition of fibrotic tissue. Yet, the specific role of individual cell types in the development of fibrosis remains poorly defined. Here, we report that aged muscle stem cells (MuSCs) directly instruct fibro-adipogenic progenitors (FAPs) to proliferate and adopt a fibrogenic phenotype. Polycomb Ezh2-/- or aged mice exhibited regenerative defects, FAP expansion, fibrosis, and elevated levels of MuSC-secreted interleukin 6 (IL-6) and Spp1/Osteopontin. In aged MuSCs, H3K27me3 erosion at the NF-kB gene correlated with increased expression and enhanced chromatin recruitment at the IL-6 and Spp1 genes, leading to their activation. Blocking IL-6 and Spp1 signaling in co-cultures of aged MuSC and FAPs, or aged mice, reduced FAP proliferation and muscle fibrosis. In summary, our results indicate that aged MuSCs instruct FAPs to proliferate and acquire a fibrogenic phenotype through a mechanism involving epigenetically-mediated derepression of NF-kB and increased activation of IL-6 and Spp1- both of which are potential pharmacological targets.

Project description:Sarcopenia, the age-related decline in muscle mass, strength, and function, is characterized by impaired muscle homeostasis, reduced regenerative potential of muscle stem cells (MuSCs), and increased fibrosis. Here, we report that aged MuSCs can autonomously instruct fibro-adipogenic progenitors (FAPs) to proliferate and acquire a fibrogenic phenotype, independent of other cell types. Both the Polycomb-deficient Ezh2-/- mouse model and aged mice exhibited defective regeneration, FAP expansion, fibrosis, and elevated secretion of interleukin 6 (IL-6) and Spp1/Osteopontin by MuSCs. In aged MuSCs, reduction of the histone H3K27me3 repressive mark at the Nfbk1 gene correlated with its increased expression, enhanced chromatin recruitment to the IL6 and Spp1 genes, leading to their activation. Pharmacological inhibition of IL-6 and Spp1 signaling in co-culture systems or in aged mice reduced FAP proliferation and muscle fibrosis. These findings indicate that epigenetic dysregulation of aged MuSCs contributes to aged-related muscle fibrosis.

Project description:Wagyu cattle are renowned for their premium beef characterized by abundant intramuscular fat (IMF). In contrast, Brahman, a popular breed in the southern coastal area of the US, generally produces tough meat with scarce IMF. However, the mechanisms underlying the differential meat quality between the two breeds are still largely unknown. Using single-cell RNAseq (scRNAseq), we identified many tissue-resident and immune cell types in Wagyu, Brahman, and Wagyu/Brahman crossbred cattle muscle. Multiple fibro/adipogenic progenitor (FAP) subpopulations were identified, including an endomysial adipogenic subpopulation and a perimysial fibrogenic subpopulation. Further analysis comparing individual FAP subpopulations between Wagyu and Brahman identified stronger pro-adipogenic gene expression in Wagyu adipogenic FAP subpopulation and higher pro-fibrogenic gene expression in Brahman fibrogenic FAP subpopulation. Overexpression of CFD, a gene upregulated in Wagyu adipogenic FAPs, enhanced the adipogenic efficiency of FAPs. Moreover, the expression of CFD in FAPs was positively correlated with the IMF content. Interestingly, the expression of CFD was identified in human FAPs but not FAPs of mouse models of intramuscular adipogenesis, suggesting that CFD is a species-specific regulator of IMF formation. Using a mouse line that allows lineage-tracing of FAPs expressing Postn, a gene upregulated in Brahman FAPs, we found that Postn expression was specifically activated during fibrogenic but not adipogenic programming. Cell-cell communication analysis revealed robust interactions between FAPs and other cell types, further suggesting the critical role of FAPs in bovine skeletal muscle growth, development, and homeostasis.

Project description:Volumetric muscle loss (VML) injuries result in chronic fibrosis, inflammation, and persistent functional deficits. Fibro-adipogenic progenitor (FAP) cells are a heterogeneous, muscle-resident stromal cell population that play a crucial role in muscle regeneration but also contribute to fibrosis in muscle disease. The role of FAPs in VML is not well established and may be a critical target to ensure functional muscle regeneration after VML. We utilized a critical VML model in the mouse quadriceps, compared with subcritical injuries and uninjured controls, to study the single-cell transcriptional profile of FAPs after VML. Our findings establish an aberrant FAP subpopulation that is elevated in VML injury and provide novel targets for future scarless muscle regeneration in VML.

Project description:Fibro-adipogenic progenitors (FAPs) are muscle-resident mesenchymal progenitors that can contribute to muscle tissue homeostasis and regeneration, as well as postnatal maturation and lifelong maintenance of the neuromuscular system. Recently, traumatic injury to the peripheral nerve was shown to activate FAPs, suggesting that FAPs can respond to nerve injury. However, questions of how FAPs can sense the anatomically distant peripheral nerve injury and whether FAPs can directly contribute to nerve regeneration remained unanswered. Here, utilizing single-cell transcriptomics and mouse models, we discovered that a subset of FAPs expressing GDNF receptors Ret and Gfra1 can respond to peripheral nerve injury by sensing GDNF secreted by Schwann cells. Upon GDNF sensing, this subset becomes activated and expresses Bdnf. FAP-specific inactivation of Bdnf (Prrx1-Cre; Bdnf-fl/fl) resulted in delayed nerve regeneration owing to defective remyelination, indicating that GDNF-sensing FAPs play an important role in the remyelination process during peripheral nerve regeneration. In aged mice, significantly reduced Bdnf expression in FAPs was observed upon nerve injury, suggesting the clinical relevance of FAP-derived BDNF in the age-related delays in nerve regeneration. Collectively, our study revealed the previously unidentified role of FAPs in peripheral nerve regeneration, and the molecular mechanism behind FAPs’ response to peripheral nerve injury.

Project description:Fibro-Adipogenic Progenitors (FAPs) are mesenchymal progenitor cells vital for muscle homeostasis and regeneration, but they also produce fibrosis and differentiate into intramuscular fat under pathological conditions. Insulin-like Growth Factor-I (IGF-I), a key regulator of muscle repair, influences satellite cell activity, macrophage polarization, and extracellular matrix (ECM) remodeling. Although FAPs are a major source of IGF-I in muscle, its specific role remains unclear. Thus, we generated inducible FAP-specific Igf1 knockout mice (FID mice) to determine the necessity of the FAP IGF-I source. After acute BaCl2 injury, FID mice exhibited impaired muscle regeneration, characterized by fewer Pax7+ cells, increased CD68+ macrophage accumulation, smaller fibers with lower proportions of EmbMHC+ fibers, and reduced ECM content compared to controls. FAP proliferation was impaired, with fewer total and Ki67+ FAPs in regenerating muscles from FID mice. Following glycerol injury, muscles from FID mice exhibited reduced adipocyte accumulation. To probe the autocrine role of FAP IGF-I, we isolated FAPs from muscles 3 days post-injury. Primary FAPs isolated from FID mice had blunted growth, accompanied by upregulation of immune-regulatory genes and downregulation of ECM and cell proliferation genes by RNASeq. Additionally, cultured FID FAPs had delayed differentiation and sustained PDGFRα expression in response to TGF-β, as well as impaired adipocyte differentiation in adipogenic media. Finally, FID FAPs entered a senescent state shortly after Cre recombination, showing high β-Gal expression in vivo and in vitro, and suppression of IGF-IR and IGF-I-dependent pathways. Taken together, our findings demonstrate that IGF-I derived from FAPs is a critical autocrine factor, with its absence leading to impaired function of FAPs for maintenance of muscle regenerative capacity

Project description:Fibro adipogenic progenitors (FAPs) promote satellite cell differentiation in adult skeletal muscle regeneration. However, in pathological conditions, FAPs are responsible for fibrosis and fatty infiltrations. Here we show that the NOTCH pathway negatively modulates FAP differentiation both in vitro and in vivo. However, FAPs isolated from young dystrophin- deficient mdx mice are insensitive to this control mechanism. An unbiased mass spectrometry-based proteomic analysis of FAPs from muscles of wild type and mdx mice, suggest that the synergistic cooperation between NOTCH and inflammatory signals controls FAP differentiation. Remarkably, we demonstrated that factors released by hematopoietic cells restore the sensitivity to NOTCH adipogenic inhibition in mdx FAPs. These results offer a basis for rationalizing pathological ectopic fat infiltrations in skeletal muscle and may suggest new therapeutic strategies to mitigate the detrimental effects of fat depositions in muscles of dystrophic patients.

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: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.