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: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: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:Adult skeletal muscle stem cells (MuSCs), also known as satellite cells (SCs), are widely believed to be responsible for muscle regeneration, which is regulated by complex networks of intrinsic and extrinsic factors. Emerging evidence demonstrates extrinsic regulations from other cell types can significantly impact the regeneration process, especially in repetitive cycles of degeneration/regeneration environment. Here, we demonstrate that the transcription factor (TF) Yin Yang 1 (YY1) deletion in MuSCs of mdx mouse induces CCL5 expression by alleviating the repressive effect on 3D structural interactions on Ccl5 locus. This leads to the increased secretion of CCL5 from MuSCs to the muscle niche, which promotes the recruitment of macrophages (MPs) through the CCL5/CCR5 axis. Incremental MPs lead to continuous inflammation that promotes the survival of Fibro-adipogenic progenitors’ (FAP) through secreting elevated TGFβ1 to stimulate FAPs resisting apoptosis, resulting in aggravated dystrophic pathology manifested by exacerbated fibrosis. Inhibition of CCL5/CCR5 axis by Maraviroc injection effectively mitigates muscle dystrophy and enhances muscle performance in YY1 deletion mdx mouse. Altogether, our findings promote us to conclude that YY1 functions as a 3D structural protein to repress Ccl5 production at the transcriptional level in MuSCs, playing a critical role in orchestrating MuSC/MP/FAP crosstalk through CCL5/CCR5 and TGFβ1 signaling. Intrinsic deletion of YY1 in MuSCs disrupts the cellular interactions and leads to skewed muscle niche with aggravated muscle dystrophy upon chronic injury.

Project description:Adult skeletal muscle stem cells (MuSCs), also known as satellite cells (SCs), are widely believed to be responsible for muscle regeneration, which is regulated by complex networks of intrinsic and extrinsic factors. Emerging evidence demonstrates extrinsic regulations from other cell types can significantly impact the regeneration process, especially in repetitive cycles of degeneration/regeneration environment. Here, we demonstrate that the transcription factor (TF) Yin Yang 1 (YY1) deletion in MuSCs of mdx mouse induces CCL5 expression by alleviating the repressive effect on 3D structural interactions on Ccl5 locus. This leads to the increased secretion of CCL5 from MuSCs to the muscle niche, which promotes the recruitment of macrophages (MPs) through the CCL5/CCR5 axis. Incremental MPs lead to continuous inflammation that promotes the survival of Fibro-adipogenic progenitors’ (FAP) through secreting elevated TGFβ1 to stimulate FAPs resisting apoptosis, resulting in aggravated dystrophic pathology manifested by exacerbated fibrosis. Inhibition of CCL5/CCR5 axis by Maraviroc injection effectively mitigates muscle dystrophy and enhances muscle performance in YY1 deletion mdx mouse. Altogether, our findings promote us to conclude that YY1 functions as a 3D structural protein to repress Ccl5 production at the transcriptional level in MuSCs, playing a critical role in orchestrating MuSC/MP/FAP crosstalk through CCL5/CCR5 and TGFβ1 signaling. Intrinsic deletion of YY1 in MuSCs disrupts the cellular interactions and leads to skewed muscle niche with aggravated muscle dystrophy upon chronic injury.

Project description:Adult skeletal muscle stem cells (MuSCs), also known as satellite cells (SCs), are widely believed to be responsible for muscle regeneration, which is regulated by complex networks of intrinsic and extrinsic factors. Emerging evidence demonstrates extrinsic regulations from other cell types can significantly impact the regeneration process, especially in repetitive cycles of degeneration/regeneration environment. Here, we demonstrate that the transcription factor (TF) Yin Yang 1 (YY1) deletion in MuSCs of mdx mouse induces CCL5 expression by alleviating the repressive effect on 3D structural interactions on Ccl5 locus. This leads to the increased secretion of CCL5 from MuSCs to the muscle niche, which promotes the recruitment of macrophages (MPs) through the CCL5/CCR5 axis. Incremental MPs lead to continuous inflammation that promotes the survival of Fibro-adipogenic progenitors’ (FAP) through secreting elevated TGFβ1 to stimulate FAPs resisting apoptosis, resulting in aggravated dystrophic pathology manifested by exacerbated fibrosis. Inhibition of CCL5/CCR5 axis by Maraviroc injection effectively mitigates muscle dystrophy and enhances muscle performance in YY1 deletion mdx mouse. Altogether, our findings promote us to conclude that YY1 functions as a 3D structural protein to repress Ccl5 production at the transcriptional level in MuSCs, playing a critical role in orchestrating MuSC/MP/FAP crosstalk through CCL5/CCR5 and TGFβ1 signaling. Intrinsic deletion of YY1 in MuSCs disrupts the cellular interactions and leads to skewed muscle niche with aggravated muscle dystrophy upon chronic injury.

Project description:Adult skeletal muscle stem cells (MuSCs), also known as satellite cells (SCs), are widely believed to be responsible for muscle regeneration, which is regulated by complex networks of intrinsic and extrinsic factors. Emerging evidence demonstrates extrinsic regulations from other cell types can significantly impact the regeneration process, especially in repetitive cycles of degeneration/regeneration environment. Here, we demonstrate that the transcription factor (TF) Yin Yang 1 (YY1) deletion in MuSCs of mdx mouse induces CCL5 expression by alleviating the repressive effect on 3D structural interactions on Ccl5 locus. This leads to the increased secretion of CCL5 from MuSCs to the muscle niche, which promotes the recruitment of macrophages (MPs) through the CCL5/CCR5 axis. Incremental MPs lead to continuous inflammation that promotes the survival of Fibro-adipogenic progenitors’ (FAP) through secreting elevated TGFβ1 to stimulate FAPs resisting apoptosis, resulting in aggravated dystrophic pathology manifested by exacerbated fibrosis. Inhibition of CCL5/CCR5 axis by Maraviroc injection effectively mitigates muscle dystrophy and enhances muscle performance in YY1 deletion mdx mouse. Altogether, our findings promote us to conclude that YY1 functions as a 3D structural protein to repress Ccl5 production at the transcriptional level in MuSCs, playing a critical role in orchestrating MuSC/MP/FAP crosstalk through CCL5/CCR5 and TGFβ1 signaling. Intrinsic deletion of YY1 in MuSCs disrupts the cellular interactions and leads to skewed muscle niche with aggravated muscle dystrophy upon chronic injury.