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: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:Disuse-induced muscle atrophy commonly occurs following illness, injury, or falls and becomes increasingly frequent with ageing. Whether skeletal muscle retains a “memory” of repeated disuse remains unknown. We investigated repeated lower- limb immobilization in young adults and a refined aged rat model, integrating physiological, multi-omic, immunohistochemical, biochemical, and primary human muscle stem cell (MuSC) analyses. To enable robust age comparisons, we integrated previously published young rat data with newly generated aged rat data. In young human muscle, repeated disuse elicited attenuated transcriptional perturbations in oxidative and mitochondrial pathways, suggestive of a protective molecular memory, despite similar atrophy to initial disuse. In contrast, aged muscle exhibited a detrimental memory, characterized by greater atrophy, exaggerated suppression of aerobic metabolism genes despite recovery after initial disuse, NAD+ and mitochondrial DNA depletion, and activation of proteasomal, extracellular-matrix, and DNA-damage pathways. Whereas young rats recovered muscle mass after initial disuse, aged rats failed to do so. Across species, repeated disuse induced DNA hypermethylation and downregulation of aerobic metabolism and mitochondrial gene networks. NR4A1 and NR4A3 were among the strongest disuse- suppressed genes; NR4A1 acquired recovery-phase hypermethylation that maintained its transcriptional repression, while NR4A3 was the most downregulated gene after initial atrophy and remained persistently suppressed into recovery. Acetylcholine receptor subunit genes (CHRNA1, CHRND) were epigenetically primed, demonstrating hypomethylation and strong upregulation after disuse, and further amplification after repeated atrophy, while CHRNG was selectively induced after repeated atrophy only. NMRK2, an NAD+ biosynthesis gene, was the most downregulated gene across both atrophy periods, and supplementation with its substrate, nicotinamide riboside (NR), improved myotube size in MuSCs derived post-atrophy. Overall, repeated disuse atrophy imprints a molecular memory in skeletal muscle shaping transcriptional resilience in young adults and exaggerated susceptibility in aged muscle.

Project description:Disuse-induced muscle atrophy commonly occurs following illness, injury, or falls and becomes increasingly frequent with ageing. Whether skeletal muscle retains a “memory” of repeated disuse remains unknown. We investigated repeated lower- limb immobilization in young adults and a refined aged rat model, integrating physiological, multi-omic, immunohistochemical, biochemical, and primary human muscle stem cell (MuSC) analyses. To enable robust age comparisons, we integrated previously published young rat data with newly generated aged rat data. In young human muscle, repeated disuse elicited attenuated transcriptional perturbations in oxidative and mitochondrial pathways, suggestive of a protective molecular memory, despite similar atrophy to initial disuse. In contrast, aged muscle exhibited a detrimental memory, characterized by greater atrophy, exaggerated suppression of aerobic metabolism genes despite recovery after initial disuse, NAD+ and mitochondrial DNA depletion, and activation of proteasomal, extracellular-matrix, and DNA-damage pathways. Whereas young rats recovered muscle mass after initial disuse, aged rats failed to do so. Across species, repeated disuse induced DNA hypermethylation and downregulation of aerobic metabolism and mitochondrial gene networks. NR4A1 and NR4A3 were among the strongest disuse- suppressed genes; NR4A1 acquired recovery-phase hypermethylation that maintained its transcriptional repression, while NR4A3 was the most downregulated gene after initial atrophy and remained persistently suppressed into recovery. Acetylcholine receptor subunit genes (CHRNA1, CHRND) were epigenetically primed, demonstrating hypomethylation and strong upregulation after disuse, and further amplification after repeated atrophy, while CHRNG was selectively induced after repeated atrophy only. NMRK2, an NAD+ biosynthesis gene, was the most downregulated gene across both atrophy periods, and supplementation with its substrate, nicotinamide riboside (NR), improved myotube size in MuSCs derived post-atrophy. Overall, repeated disuse atrophy imprints a molecular memory in skeletal muscle shaping transcriptional resilience in young adults and exaggerated susceptibility in aged muscle.

Project description:Disuse-induced muscle atrophy commonly occurs following illness, injury, or falls and becomes increasingly frequent with ageing. Whether skeletal muscle retains a “memory” of repeated disuse remains unknown. We investigated repeated lower- limb immobilization in young adults and a refined aged rat model, integrating physiological, multi-omic, immunohistochemical, biochemical, and primary human muscle stem cell (MuSC) analyses. To enable robust age comparisons, we integrated previously published young rat data with newly generated aged rat data. In young human muscle, repeated disuse elicited attenuated transcriptional perturbations in oxidative and mitochondrial pathways, suggestive of a protective molecular memory, despite similar atrophy to initial disuse. In contrast, aged muscle exhibited a detrimental memory, characterized by greater atrophy, exaggerated suppression of aerobic metabolism genes despite recovery after initial disuse, NAD+ and mitochondrial DNA depletion, and activation of proteasomal, extracellular-matrix, and DNA-damage pathways. Whereas young rats recovered muscle mass after initial disuse, aged rats failed to do so. Across species, repeated disuse induced DNA hypermethylation and downregulation of aerobic metabolism and mitochondrial gene networks. NR4A1 and NR4A3 were among the strongest disuse- suppressed genes; NR4A1 acquired recovery-phase hypermethylation that maintained its transcriptional repression, while NR4A3 was the most downregulated gene after initial atrophy and remained persistently suppressed into recovery. Acetylcholine receptor subunit genes (CHRNA1, CHRND) were epigenetically primed, demonstrating hypomethylation and strong upregulation after disuse, and further amplification after repeated atrophy, while CHRNG was selectively induced after repeated atrophy only. NMRK2, an NAD+ biosynthesis gene, was the most downregulated gene across both atrophy periods, and supplementation with its substrate, nicotinamide riboside (NR), improved myotube size in MuSCs derived post-atrophy. Overall, repeated disuse atrophy imprints a molecular memory in skeletal muscle shaping transcriptional resilience in young adults and exaggerated susceptibility in aged muscle.

Project description:Disuse-induced muscle atrophy commonly occurs following illness, injury, or falls and becomes increasingly frequent with ageing. Whether skeletal muscle retains a “memory” of repeated disuse remains unknown. We investigated repeated lower- limb immobilization in young adults and a refined aged rat model, integrating physiological, multi-omic, immunohistochemical, biochemical, and primary human muscle stem cell (MuSC) analyses. To enable robust age comparisons, we integrated previously published young rat data with newly generated aged rat data. In young human muscle, repeated disuse elicited attenuated transcriptional perturbations in oxidative and mitochondrial pathways, suggestive of a protective molecular memory, despite similar atrophy to initial disuse. In contrast, aged muscle exhibited a detrimental memory, characterized by greater atrophy, exaggerated suppression of aerobic metabolism genes despite recovery after initial disuse, NAD+ and mitochondrial DNA depletion, and activation of proteasomal, extracellular-matrix, and DNA-damage pathways. Whereas young rats recovered muscle mass after initial disuse, aged rats failed to do so. Across species, repeated disuse induced DNA hypermethylation and downregulation of aerobic metabolism and mitochondrial gene networks. NR4A1 and NR4A3 were among the strongest disuse- suppressed genes; NR4A1 acquired recovery-phase hypermethylation that maintained its transcriptional repression, while NR4A3 was the most downregulated gene after initial atrophy and remained persistently suppressed into recovery. Acetylcholine receptor subunit genes (CHRNA1, CHRND) were epigenetically primed, demonstrating hypomethylation and strong upregulation after disuse, and further amplification after repeated atrophy, while CHRNG was selectively induced after repeated atrophy only. NMRK2, an NAD+ biosynthesis gene, was the most downregulated gene across both atrophy periods, and supplementation with its substrate, nicotinamide riboside (NR), improved myotube size in MuSCs derived post-atrophy. Overall, repeated disuse atrophy imprints a molecular memory in skeletal muscle shaping transcriptional resilience in young adults and exaggerated susceptibility in aged muscle.

Project description:Aged skeletal muscle is characterized by impaired muscle recovery following disuse and coincides with an impaired muscle pro-inflammatory macrophage response. Macrophage inflammatory status (polarization) is regulated by its metabolic state, but to date, little is understood of macrophage metabolism and its relation to macrophage polarization in the context of muscle recovery and aging. Therefore, the purpose of this study was to thoroughly characterize macrophage metabolism and polarization in aged muscle during early recovery from disuse atrophy using single cell RNA sequencing and functional assays. Young (4-5 mo) and old (20-22 mo) male C57BL/6 mice underwent 14 days of hindlimb unloading followed by 4 days of ambulatory recovery. CD45+ cells were isolated from solei muscles and analyzed using 10x Genomics single cell RNA sequencing. We found that aged M1 macrophage clusters were characterized with an impaired inflammatory and glycolytic transcriptome and this impairment was accompanied by a suppression of HIF-1α and its immediate downstream target GLUT1.

Project description:Skeletal muscle atrophy is dictated by the balance between protein synthesis and protein breakdown, known as proteostasis. With advanced age, muscle atrophy contributes to development of co-morbidities, loss of strength and independence, and all-cause mortality. Aging also coincides with the accumulation of senescent cells within skeletal muscle that produce inflammatory products, known as the senescence associated secretory phenotype. Previously, we found that a metformin + leucine (MET+LEU) combination treatment had synergistic effects in aged mice to improve skeletal muscle structure and function during disuse atrophy. Therefore, the objective of this study was to determine the mechanisms by which MET+LEU exhibits muscle atrophy protection in vitro and if this occurs through cellular senescence. C2C12 myoblasts differentiated into myotubes were used to determine MET+LEU mechanisms during serum-deprivation (SD) atrophy. Single myofibers were isolated from aged (22-23 mo) C57Bl6/J mice, and human primary myoblasts were extracted from a healthy older adult donor. 25 + 125 µM MET+LEU treatment increased differentiation of myotubes and prevented SD induced atrophy. Low concentration (0.1 + 0.5 µM) MET+LEU had unique effects to prevent myotube atrophy and cause transcriptional reprogramming compared to individual therapies. SD increased inflammatory and cellular senescence pathways that was reversed with MET+LEU treatment. SD resulted in dysregulated proteostasis that was rescued with MET+LEU, and proteasome inhibition with MG-132 also rescued myotube atrophy. Cellular senescence transcriptional pathways and markers increased by SD were reversed with MET+LEU treatment, and dasatinib + quercetin (D+Q) senolytic treatment prevented myotube atrophy similar to MET+LEU. In aged myofibers, MET+LEU prevented SD atrophy, and in human primary myotubes MET+LEU prevented reductions in myonuclei fusion. These data provide evidence that MET+LEU has muscle cell intrinsic properties to prevent atrophy by reversing senescence and improving proteostasis

Project description:Our laboratory previously demonstrated that perivascular stem/stromal cells (CD146+ pericytes) can effectively recover muscle mass after a period of immobilization in young adult mice. However, cell-based therapies are problematic in aged mouse models due to lack of viability upon transplantation. Therefore, the purpose of this study was to develop a pericyte-based, cell-free strategy to recover muscle mass after disuse in aged mice. Single-cell RNA sequencing (scRNA-Seq) was performed on adult mouse skeletal muscle after two weeks of unilateral hindlimb immobilization, which revealed that muscle-resident pericytes uniquely upregulate the long noncoding RNA Malat1, a negative regulator of Nrf2, and fail to induce antioxidant gene expression in response to reactive oxygen species (ROS; H2O2). This information was used to guide the design of a strategy in which healthy donor pericytes were stimulated with ROS to produce small extracellular vesicles (EVs) that were subsequently transplanted into 4- and 24-26-month-old C57BL/6 mice after two weeks of unilateral hindlimb immobilization. H2O2-primed healthy muscle-derived pericytes produced EVs in culture that effectively reduced restored myofiber CSA in both adult (p=0.009) and aged (p=0.006) muscle after disuse. In contrast, unprimed pericyte-derived EVs did not influence myofiber size. Neither primed, nor unprimed EVs recovered capillary density, yet both stimulated collagen turnover. Healthy ROS-primed pericyte-derived small EVs effectively improve skeletal muscle recovery after immobilization, representing a novel cell-free approach to rebuild muscle mass in older adults after a period of disuse.

Project description:Skeletal muscle dysfunction in survivors of pneumonia is a major cause of lasting morbidity that disproportionately affects older individuals. We found that skeletal muscle recovery was impaired in aged compared with young mice after influenza A virus-induced pneumonia. In young mice, recovery of muscle loss was associated with expansion of tissue-resident skeletal muscle macrophages and downregulation of MHC II expression, followed by a proliferation of muscle satellite cells. These findings were absent in aged mice and in mice deficient in Cx3cr1. Transcriptomic profiling of tissue-resident skeletal muscle macrophages from aged compared with young mice showed downregulation of pathways associated with phagocytosis and proteostasis, and persistent upregulation of inflammatory pathways. Consistently, skeletal muscle macrophages from aged mice failed to downregulate MHCII expression during recovery from influenza A virus induced pneumonia and showed impaired phagocytic function in vitro. Like aged animals, mice deficient in the phagocytic receptor Mertk showed no macrophage expansion, MHCII downregulation or satellite cell proliferation and failed to recover skeletal muscle function after influenza A pneumonia. Our data suggest that a loss of phagocytic function in a CX3CR1+ tissue-resident skeletal muscle macrophage population in aged mice precludes satellite cell proliferation and recovery of skeletal muscle function after influenza A pneumonia.