Project description:Impaired phagocytic function in CX3CR1+ tissue-resident skeletal muscle macrophages prevents muscle recovery after influenza A virus-induced pneumonia in aged mice

Project description:In this study, we investigated signaling pathways in Skeletal muscle precursors that are altered with aging and age-related deficits in muscle regenerative potential. We performed fluorescence activated cell sorting (FACS) to obtain highly purified skeletal muscle satellite cells from young, middle-aged and old mice. Parabiosis experiments indicate that impaired regeneration in aged mice is reversible by exposure to a young circulation, suggesting that young blood contains humoral "rejuvenating" factors that can restore regenerative function. Here, we demonstrate that the circulating protein growth differentiation factor 11 (GDF11) is a rejuvenating factor for skeletal muscle. Supplementation of systemic GDF11 levels, which normally decline with age, by heterochronic parabiosis or systemic delivery of recombinant protein, reversed functional impairments and restored genomic integrity in aged muscle stem cells (satellite cells). Increased GDF11 levels in aged mice also improved muscle structural and functional features and increased strength and endurance exercise capacity. These data indicate that GDF11 systemically regulates muscle aging and may be therapeutically useful for reversing age-related skeletal muscle and stem cell dysfunction. We used Affymetrix Mouse Genome array to identify global transcriptional changes associated with age in skeletal muscle precursors.

Project description:Skeletal muscle aging results in a gradual loss of skeletal muscle mass, skeletal muscle function and decreased regenerative capacity, which can lead to sarcopenia and increased mortality. While the mechanisms underlying sarcopenia remain unclear, the skeletal muscle stem cell, or satellite cell, is required for muscle regeneration. Therefore, identification of signaling pathways affecting satellite cell function during aging may provide insights into therapeutic targets for combating sarcopenia. Here, we show that a cell-autonomous loss in self-renewal occurs via novel alterations in FGF and p38αβ MAPK signaling in old satellite cells. We further demonstrate that pharmacological manipulation of these pathways can ameliorate age-associated self-renewal defects. Thus, our data highlight an age-associated deregulation of a satellite cell homeostatic network and reveals potential therapeutic opportunities for the treatment of progressive muscle wasting. Satellite cells were isolated from young (3-6mo) and aged (20-25mo) adult mice; individual date files represent 2 independent pools of RNA from 4-8 mice at each timepoint.

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.

Project description:Satellite cells are responsible for the long-term regenerative capacity of adult skeletal muscle. The diminished muscle performance and regenerative capacity of aged muscle is thought to reflect progressive fibrosis and atrophy. Whether this reduction in muscle competency also involves a diminishment in the intrinsic regulation of satellite cell self-renewal remains unknown. We used microarray to identify gene expression changes underlying the marked reduction in the capacity of satellite cells to self-renew, contribute to regeneration and repopulate the niche as they age. Skeletal muscles from heterozygous Pax7-ZsGreen mice were isolated at defined stages: E17.5 (fetal - whole forelimb and hindlimb), postnatal day 21 (adolescent - hindlimb), 2-3 month old (young adult - hindlimb) and >1 year old (older adult - hindlimb) mice. ZsGreen-positive skeletal muscle satellite cells were isolated by FACS and pooled (fetal n=4, adolescent n=6, young adult n=8 and older adult n=8 mice).

Project description:Loss of muscle mass and strength following disuse followed by impaired muscle recovery likely contribute to sarcopenia in older adults. Metformin and leucine individually have shown positive effects in skeletal muscle during atrophy conditions but have not been evaluated in combination nor under the conditions of disuse atrophy and recovery in aging. The purpose of this study was to determine if a dual treatment of metformin and leucine (MET+LEU) would prevent disuse-induced atrophy and/or promote muscle recovery in aged mice (22-24 mo). We were also interested if these muscle responses correspond to changes in satellite cells and ECM abundance. Aged mice were subjected to 14 days of hindlimb unloading (HU) followed by 7 or 14 days of reloading (7 or 14d RL). Metformin (MET), leucine (LEU), or MET+LEU was administered via drinking water and were compared to Vehicle-treated mice. We observed that MET+LEU increased whole body grip strength, muscle specific force and satellite cell abundance during HU but did not alter muscle size during HU or RL. Moreover, MET+LEU treatment increased ECM turnover driven by a decrease in collagen IV   content during 7 and 14d RL. Transcriptome analysis revealed that MET+LEU altered Gene Set Enrichment Analysis hallmark pathways related to inflammation and myogenesis during HU. Together  , MET+LEU was able to improve muscle quality during disuse and recovery in aging possibly by increasing muscle satellite cell content and reducing excessive ECM accumulation.

Project description:In this study, we investigated signaling pathways in Skeletal muscle precursors that are altered with aging and age-related deficits in muscle regenerative potential. We performed fluorescence activated cell sorting (FACS) to obtain highly purified skeletal muscle satellite cells from young, middle-aged and old mice. Parabiosis experiments indicate that impaired regeneration in aged mice is reversible by exposure to a young circulation, suggesting that young blood contains humoral "rejuvenating" factors that can restore regenerative function. Here, we demonstrate that the circulating protein growth differentiation factor 11 (GDF11) is a rejuvenating factor for skeletal muscle. Supplementation of systemic GDF11 levels, which normally decline with age, by heterochronic parabiosis or systemic delivery of recombinant protein, reversed functional impairments and restored genomic integrity in aged muscle stem cells (satellite cells). Increased GDF11 levels in aged mice also improved muscle structural and functional features and increased strength and endurance exercise capacity. These data indicate that GDF11 systemically regulates muscle aging and may be therapeutically useful for reversing age-related skeletal muscle and stem cell dysfunction.

Project description:Skeletal muscle is the most common tissue in the body. Its continued maintenance and regeneration throughout life is essential to the function of the organism. Satellite cells are critical to regeneration of the skeletal muscle and strategies to improve function of satellite cells are of great importance. Muscle-resident Fibro-Adipogenic Precursors (FAPs) cells are a critical component of the satellite cell niche and help orchestrate efficient muscle regeneration and potentiate satellite cell differentiation via soluble or secreted factors. Populations with similar phenotype and function to muscle FAPs have been isolated from the skin and white adipose tissue. Interactions between tissue-specific FAP cells and resident stem cells in those tissues might be conserved. Therefore, defining specific factors that mediate the relationship between muscle FAPs and satellite cells would have implications for other organs.

Project description:The satellite cell is considered the major tissue-resident stem cell underlying muscle regeneration, however, multiple non-satellite cell myogenic progenitors have been identified. PW1/Peg3 is expressed in satellite cells as well as a subset of interstitial cells with myogenic potential termed PICs (PW1+ Interstitial Cells). PICs differ from satellite cells by their anatomical location (satellite cells are sublaminal and PICs are interstitial), they do not express any myogenic marker and arise from a Pax3-independent lineage. Upon isolation from juvenile muscle (1 to 3 weeks old), PICs are capable to form both skeletal and smooth muscle suggesting they constitute a more plastic population compared to satellite cells. We used microarrays to gain insight into the relantionship between PICs and satellite cells. PICs and satellite cells were isolated from 1-week old mouse muscle and subsequent RNA extraction was performed.

Project description:Adult muscle stem cells, also known as muscle satellite cells, which are the resident tissue stem cells of skeletal muscle, provide myonuclei for postnatal muscle growth and for maintenance and regeneration in adults. Satellite cells specifically express the transcription factor pax7. The purpose of this study was to identify pax7 target genes and clarify the role of pax7 in muscle stem cell maintenance. We succeeded in generating Pax7-YFP knockin mice (Pax7-YFP KI) that can visualize endogenous pax7 expressed in satellite cells with YFP fluorescent protein. Novel pax7 target genes were identified by ChIP-sequencing (chromatin immunoprecipitation) analysis with muscle stem cells of Pax7-YFP KI mice.