Project description:Coordinating mechanical sensing and transcription activation is essential for muscle stem cell (MuSC) function during muscle regeneration. Here we report that MPP7, localized at the apical side of quiescent MuSCs, is an important regulator in MuSC activation, including proliferation and self-renewal. Mechanistically, MPP7 translocates to cell nucleus in response to the change of actin polymerization state with its binding partner AMOT (an actin binding protein) upon MuSC activation and acts to enhance the transcription activity of YAP and TAZ in the MuSC. RNA-seq of MuSCs isolated from control (Con), Mpp7 conditional knockout (cKO), Amot cKO, and Yap and Taz double cKO (YapTaz cKO) after 48 hrs in culture (for activation) in 2 replicas was used to determine the downtream genes regulated by Mpp7, Amot, Yap and Taz. Carm1 was one of the commonly shared down-regulated genes in all 3 cKOs and has been shown to be critical for MuSC self-renewal. We further demonstrated that the MPP7-PDZ domain interacts with TAZ indirectly via AMOT, and the MPP7-L27 domain cooperates with TAZ and another trsncription factor YY1 to regulate a select set of donwstream genes, including Carm1, for MuSC proliferation and self-renewal. Our data identified a coordinated molecular network from mechanical sensing to transcription regulation for MuSC function during muscle regeneration.

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: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 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:Quiescent adult muscle stem cells (MuSCs) regenerate skeletal muscle upon injury throughout life. However, aged skeletal muscles fail to maintain stem cell quiescence, leading to declines in MuSC number and functionality. Although autophagy plays an important role in the maintenance of MuSC quiescence, how quiescent MuSCs and their autophagy levels are maintained throughout life is largely unknown. The current study reveals how GnRH, a hypothalamic hormone, maintains the quiescence of adult MuSCs by preventing the onset of senescence and how the decline of sex steroids in organismal ageing is implicated in MuSC ageing.

Project description:Adult skeletal muscle regeneration is mainly driven by muscle stem cells (MuSCs), which are highly heterogeneous. Although recent studies have started to characterize the heterogeneity of MuSCs, whether a subset of cells with distinct exists within MuSCs remains unanswered. Here, we found that a population of MuSCs, marked by Gli1 expression, is required for muscle regeneration. The Gli1+ MuSC population displayed advantages in proliferation and differentiation both in vitro and in vivo. Depletion of this population led to delayed muscle regeneration, while transplanted Gli1+ MuSCs supported muscle regeneration more effectively than Gli1- MuSCs. Further analysis revealed that even in the uninjured muscle, Gli1+ MuSCs had elevated mTOR signaling activity, increased cell size and mitochondrial numbers compared to Gli1- MuSCs, indicating Gli1+ MuSCs are displaying the features of primed MuSCs. Moreover, Gli1+ MuSCs greatly contributed to the formation of GAlert cells after muscle injury. Collectively, our findings demonstrate that Gli1+ MuSCs represent a distinct MuSC population which is more active in the homeostatic muscle and enters the cell cycle shortly after injury. This cell population functions as the tissue-resident sentinel that rapidly responds to injury and initiates muscle regeneration.

Project description:We report the expression profiles of MCF10A cells encapsulated in hydrogels of varying stiffness and composition. Cells were encapsulated for 7 days in either 1.) soft alginate and reconstituted basement membrane (rBM), 2.) stiff alginate and rBM, 3,) soft col-1 and rBM, or 4.) stiff col-1. We find global gene expression changes in response to enhanced ECM stiffness, independent of expression changes in response to col-1 exposure. These results provide a comprehensive study of the gene expression changes associated with increased ECM stiffness in addition to the gene expression changes associated with increased col-1 concentration in combination with, and independent of, ECM stiffness.

Project description:Background: Skeletal muscle function crucially depends on motor innervation and after injury on the resident muscle stem cells (MuSCs). However, it is poorly understood how innervation affects MuSC properties. Methods: We investigated the alterations of MuSCs and their immediate niche, the myofiber, after denervation in a surgery-based mouse model of unilateral sciatic nerve transection. FACS-isolated MuSCs were subjected to transcriptomics and proteomics analyses to investigate which changes occur after denervation. We performed Cardiotoxin-induced muscle injury, MuSC transplantation and floating myofiber cultures to assess MuSC functionality after denervation in addition to bioinformatics and histological analyses. Results: We observed a significant increase in the number of MuSCs (Pax7 positive; p-value= 0.0441), proliferating MuSCs (Pax7/Ki67 positive; p-value= 0.0023), activated MuSCs (MyoD positive; p-value= 0.0016) and differentiating MuSCs (Myog positive; p-value= 0.0057) after denervation. This aberrant activation and premature commitment of MuSCs to the myogenic lineage was accompanied by profound alterations on the mRNA (2613 differentially expressed genes, adj. p-value <0.05) and protein (1096 differentially abundant proteins, q-value <0.05) level after denervation. MuSCs from denervated hosts still engrafted and fused to form new myofibers irrespective of the innervation status of the recipient, suggesting the MuSC niche is driving alterations in MuSCs after denervation. The myofiber transcriptome after denervation showed massive changes in the general expression profile (10492 DEGs, p-value <0.05) and in several predicted secreted factors. Incubation of myofiber-associated MuSCs with supernatant from denervated myofibers increased cluster formation, reinforcing myofibers as a source of secreted factors driving MuSC alterations after denervation. Opn and Tgfb1 showed an increased secretion by denervated myofibers (30-fold and 6000-fold, respectively), and incubation with Tgfb1 alone induced Junb expression in myogenic cells, one of the genes highly upregulated in MuSCs after denervation (p-value= 1.85e-18, log2fc= 3.27), demonstrating that myofiber-secreted ligands influence MuSC gene expression. A combination of skeletal muscle injury and denervation led to reduced numbers of proliferating MuSCs (Sham: 47 vs DEN: 19.75 cells per cross section 10 days post-injury) and sustained high levels of developmental myosin heavy chain (Sham: 1 % vs DEN: 40 % of all myofibers 21 days post-injury), indicating hampered MuSC functionality due to changes in the microenvironment. Conclusion: Denervation of skeletal muscle causes alterations in myofiber secretion, leading to activation and profound changes of MuSCs, ultimately resulting in a reduced regenerative capacity. As these alterations are partially reversible, MuSCs are a promising target for novel treatment options for neuromuscular disorders and peripheral nerve injuries.

Project description:Background: Skeletal muscle function crucially depends on motor innervation and after injury on the resident muscle stem cells (MuSCs). However, it is poorly understood how innervation affects MuSC properties. Methods: We investigated the alterations of MuSCs and their immediate niche, the myofiber, after denervation in a surgery-based mouse model of unilateral sciatic nerve transection. FACS-isolated MuSCs were subjected to transcriptomics and proteomics analyses to investigate which changes occur after denervation. We performed Cardiotoxin-induced muscle injury, MuSC transplantation and floating myofiber cultures to assess MuSC functionality after denervation in addition to bioinformatics and histological analyses. Results: We observed a significant increase in the number of MuSCs (Pax7 positive; p-value= 0.0441), proliferating MuSCs (Pax7/Ki67 positive; p-value= 0.0023), activated MuSCs (MyoD positive; p-value= 0.0016) and differentiating MuSCs (Myog positive; p-value= 0.0057) after denervation. This aberrant activation and premature commitment of MuSCs to the myogenic lineage was accompanied by profound alterations on the mRNA (2613 differentially expressed genes, adj. p-value <0.05) and protein (1096 differentially abundant proteins, q-value <0.05) level after denervation. MuSCs from denervated hosts still engrafted and fused to form new myofibers irrespective of the innervation status of the recipient, suggesting the MuSC niche is driving alterations in MuSCs after denervation. The myofiber transcriptome after denervation showed massive changes in the general expression profile (10492 DEGs, p-value <0.05) and in several predicted secreted factors. Incubation of myofiber-associated MuSCs with supernatant from denervated myofibers increased cluster formation, reinforcing myofibers as a source of secreted factors driving MuSC alterations after denervation. Opn and Tgfb1 showed an increased secretion by denervated myofibers (30-fold and 6000-fold, respectively), and incubation with Tgfb1 alone induced Junb expression in myogenic cells, one of the genes highly upregulated in MuSCs after denervation (p-value= 1.85e-18, log2fc= 3.27), demonstrating that myofiber-secreted ligands influence MuSC gene expression. A combination of skeletal muscle injury and denervation led to reduced numbers of proliferating MuSCs (Sham: 47 vs DEN: 19.75 cells per cross section 10 days post-injury) and sustained high levels of developmental myosin heavy chain (Sham: 1 % vs DEN: 40 % of all myofibers 21 days post-injury), indicating hampered MuSC functionality due to changes in the microenvironment. Conclusion: Denervation of skeletal muscle causes alterations in myofiber secretion, leading to activation and profound changes of MuSCs, ultimately resulting in a reduced regenerative capacity. As these alterations are partially reversible, MuSCs are a promising target for novel treatment options for neuromuscular disorders and peripheral nerve injuries.

Project description:Muscle stem cells (MuSCs) are required for muscle regeneration. In resting muscles, MuSCs are kept in quiescence. After injury, MuSCs undergo rapid activation, proliferation and differentiation to repair damaged muscles. Age-associated impairments in stem cell functions correlate with a decline in somatic tissue regeneration capacity during aging. However, the mechanisms underlying the molecular regulation of adult stem cell aging remain elusive. Here, we obtained quisecent MuSCs from young, old, geriatric mice for high resolution mass spectrometry Bruker timsTOF Pro. By comparison of young proteome to old MuSCs proteome or geriatric MuSC proteome, we identified the pathways that are differentially during aging.