Project description:During aging, the regenerative capacity of skeletal muscle decreases due to intrinsic changes in muscle stem cells (MuSCs) and alterations in their niche. Here, we used quantitative mass spectrometry to characterize intrinsic changes in the MuSC proteome and remodeling of the MuSC niche during aging. We generated a network connecting age-affected ligands located in the niche and cell surface receptors on MuSCs. Thereby, we revealed signaling via Integrins, Lrp1, Egfr and Cd44 as the major cell communication axes perturbed through aging. We investigated the effect of Smoc2, a secreted protein that accumulates with aging, originating from fibro-adipogenic progenitors. Increased levels of Smoc2 contribute to the aberrant Itgb1/MAPK signaling observed during aging, thereby causing impaired MuSC functionality and muscle regeneration. By connecting changes in the proteome of MuSCs to alterations of their niche, our work will enable a better understanding of how MuSCs are affected during aging.

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:The function of skeletal muscle stem cells (MuSC) declines during aging, contributing to the advent of age-related myopathies. However, whether this decline is the result of accumulating cellular damage, altered heterogeneity in stem cell populations or due to the effect of the changing niche environment remains largely unknown. By scRNA-Seq, we show that the age-related reduction in the MuSC pool is not stochastic, with different subpopulations being distinctly affected in aging. Using an in vivo allogeneic stem cell transplantation model, we show that exposure of MuSCs from old mice to a youthful niche environment significantly restores the gene expression of genes that are altered in aging. We show that age-related changes in the MuSC transcriptome are mainly driven by alterations in chromatin and transcription but are not due to posttranscriptional mechanisms affecting RNA stability. Furthermore, our data indicates that the portion of the genome that is activated in aging is significantly more responsive to restoration by niche factors compared to the repressed counterpart. Taken together, our data reveals that the niche environment plays a decisive role in controlling the transcriptional activity of MuSCs.

Project description:The function of skeletal muscle stem cells (MuSC) declines during aging, contributing to the advent of age-related myopathies. However, whether this decline is the result of accumulating cellular damage, altered heterogeneity in stem cell populations or due to the effect of the changing niche environment remains largely unknown. By scRNA-Seq, we show that the age-related reduction in the MuSC pool is not stochastic, with different subpopulations being distinctly affected in aging. Using an in vivo allogeneic stem cell transplantation model, we show that exposure of MuSCs from old mice to a youthful niche environment significantly restores the gene expression of genes that are altered in aging. We show that age-related changes in the MuSC transcriptome are mainly driven by alterations in chromatin and transcription but are not due to posttranscriptional mechanisms affecting RNA stability. Furthermore, our data indicates that the portion of the genome that is activated in aging is significantly more responsive to restoration by niche factors compared to the repressed counterpart. Taken together, our data reveals that the niche environment plays a decisive role in controlling the transcriptional activity of MuSCs.

Project description:The function of skeletal muscle stem cells (MuSC) declines during aging, contributing to the advent of age-related myopathies. However, whether this decline is the result of accumulating cellular damage, altered heterogeneity in stem cell populations or due to the effect of the changing niche environment remains largely unknown. By scRNA-Seq, we show that the age-related reduction in the MuSC pool is not stochastic, with different subpopulations being distinctly affected in aging. Using an in vivo allogeneic stem cell transplantation model, we show that exposure of MuSCs from old mice to a youthful niche environment significantly restores the gene expression of genes that are altered in aging. We show that age-related changes in the MuSC transcriptome are mainly driven by alterations in chromatin and transcription but are not due to posttranscriptional mechanisms affecting RNA stability. Furthermore, our data indicates that the portion of the genome that is activated in aging is significantly more responsive to restoration by niche factors compared to the repressed counterpart. Taken together, our data reveals that the niche environment plays a decisive role in controlling the transcriptional activity of MuSCs.

Project description:The function of skeletal muscle stem cells (MuSC) declines during aging, contributing to the advent of age-related myopathies. However, whether this decline is the result of accumulating cellular damage, altered heterogeneity in stem cell populations or due to the effect of the changing niche environment remains largely unknown. By scRNA-Seq, we show that the age-related reduction in the MuSC pool is not stochastic, with different subpopulations being distinctly affected in aging. Using an in vivo allogeneic stem cell transplantation model, we show that exposure of MuSCs from old mice to a youthful niche environment significantly restores the gene expression of genes that are altered in aging. We show that age-related changes in the MuSC transcriptome are mainly driven by alterations in chromatin and transcription but are not due to posttranscriptional mechanisms affecting RNA stability. Furthermore, our data indicates that the portion of the genome that is activated in aging is significantly more responsive to restoration by niche factors compared to the repressed counterpart. Taken together, our data reveals that the niche environment plays a decisive role in controlling the transcriptional activity of MuSCs.

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:Muscle stem cells (MuSC) exhibit distinct behaviors during successive phases of developmental myogenesis. However, how their transition to adulthood is regulated is poorly understood. Here we show that fetal MuSC resist progenitor specification and exhibit altered division dynamics, intrinsic features that are progressively lost postnatally. Following transplantation, fetal MuSC more efficiently expand and contribute to muscle repair. Conversely, the efficiency of niche colonization increases in adulthood, indicating a balance between muscle growth and stem cell pool repopulation. Gene expression profiling identified several extracellular matrix (ECM) molecules preferentially expressed in fetal MuSC, including tenascin-C, fibronectin and collagen VI. Loss-of-function experiments confirmed their essential and stage-specific role in regulating MuSC function. Finally, fetal-derived paracrine factors were able to enhance adult MuSC regenerative potential. Together, these findings demonstrate that MuSC change the way in which they remodel their microenvironment to direct stem cell behavior in support of the unique demands of muscle development or repair. MuSCs were isolated through fluorescent-activate cell sorting usinf alpha7-integirn and CD34 as markers to identify the cell population. Total mRNA was then isolated, and samples at different developmental times were compared.

Project description:A progressive loss of protein homeostasis is characteristic of aging and a driver of neurodegeneration. To investigate this process quantitatively, we characterized proteome dynamics during brain aging in the short-lived vertebrate Nothobranchius furzeri combining transcriptomics and proteomics. We detected a progressive reduction in the correlation between protein and mRNA mainly due to post-transcriptional mechanisms that account for over 40% of the age-regulated proteins. These changes cause a progressive loss of stoichiometry in several protein complexes, including ribosomes, which show impaired assembly and are enriched in protein aggregates in old brains. Mechanistically, we show that reduction of proteasome activity is an early event during brain aging and is sufficient to induce proteomic signatures of aging and loss of stoichiometry in vivo. Using longitudinal transcriptomic data, we show that the magnitude of early life decline in proteasome levels is the major risk factor for mortality. Our work defines causative events in the aging process that can be targeted to prevent loss of protein homeostasis and delay the onset of age-related neurodegeneration.

Project description:During aging and neuromuscular diseases, there is a progressive loss of skeletal muscle volume and function, which is often associated with denervation and a loss of muscle stem cells (MuSCs). A relationship between MuSCs and innervation has not been established however. Herein, we administered neuromuscular trauma to a MuSC lineage tracing model and observed a subset of MuSCs specifically engraft in a position proximal to the neuromuscular junction (NMJ). In aging and in a model of neuromuscular degeneration (Sod1-/-), this localized engraftment behavior was reduced. Genetic rescue of motor neurons in Sod1-/- mice reestablished integrity of the NMJ and partially restored MuSC ability to engraft into NMJ proximal positions. Using single cell RNA-sequencing of MuSCs, we demonstrate that a subset of MuSCs are molecularly distinguishable from MuSCs responding to myofiber injury. These data reveal unique features of MuSCs that respond to synaptic perturbations caused by aging and other stressors.