213 results on '"Murach, Kevin"'
Search Results
2. Muscle weakness and mitochondrial stress occur before severe metastasis in a novel mouse model of ovarian cancer cachexia
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Delfinis, Luca J., Ogilvie, Leslie M., Khajehzadehshoushtar, Shahrzad, Gandhi, Shivam, Garibotti, Madison C., Thuhan, Arshdeep K., Matuszewska, Kathy, Pereira, Madison, Jones, Ronald G., III, Cheng, Arthur J., Hawke, Thomas J., Greene, Nicholas P., Murach, Kevin A., Simpson, Jeremy A., Petrik, Jim, and Perry, Christopher G.R.
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- 2024
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3. Exercise metabolism and adaptation in skeletal muscle
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Smith, Jonathon A. B., Murach, Kevin A., Dyar, Kenneth A., and Zierath, Juleen R.
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- 2023
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4. Precision and efficacy of RNA-guided DNA integration in high-expressing muscle loci
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Padmaswari, Made Harumi, Bulliard, Gabrielle, Agrawal, Shilpi, Jia, Mary S., Khadgi, Sabin, Murach, Kevin A., and Nelson, Christopher E.
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- 2024
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5. A muscle exercise research revolution powered by -omics at single cell and nucleus resolution
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Murach, Kevin A. and Peterson, Charlotte A.
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- 2023
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6. The roles of miRNAs in adult skeletal muscle satellite cells
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Koopmans, Pieter Jan, Ismaeel, Ahmed, Goljanek-Whysall, Katarzyna, and Murach, Kevin A.
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- 2023
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7. Senolytic treatment rescues blunted muscle hypertrophy in old mice
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Dungan, Cory M., Figueiredo, Vandre C., Wen, Yuan, VonLehmden, Georgia L., Zdunek, Christopher J., Thomas, Nicholas T., Mobley, C. Brooks, Murach, Kevin A., Brightwell, Camille R., Long, Douglas E., Fry, Christopher S., Kern, Philip A., McCarthy, John J., and Peterson, Charlotte A.
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- 2022
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8. Multi-transcriptome analysis following an acute skeletal muscle growth stimulus yields tools for discerning global and MYC regulatory networks
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Murach, Kevin A., Liu, Zhengye, Jude, Baptiste, Figueiredo, Vandre C., Wen, Yuan, Khadgi, Sabin, Lim, Seongkyun, Morena da Silva, Francielly, Greene, Nicholas P., Lanner, Johanna T., McCarthy, John J., Vechetti, Ivan J., and von Walden, Ferdinand
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- 2022
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9. The rRNA epitranscriptome and myonuclear SNORD landscape in skeletal muscle fibers contributes to ribosome heterogeneity and is altered by a hypertrophic stimulus.
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Cui, Minying, Jannig, Paulo, Halladjian, Maral, Figueiredo, Vandré C., Wen, Yuan, Vechetti, Ivan J., Krogh, Nicolai, Jude, Baptiste, Edman, Sebastian, Lanner, Johanna, McCarthy, John, Murach, Kevin A., Sejersen, Thomas, Nielsen, Henrik, and Walden, Ferdinand von
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SKELETAL muscle ,CYTOLOGY ,RIBOSOMAL RNA ,ORGANELLE formation ,MUSCLE growth ,RIBOSOMES - Abstract
In cell biology, ribosomal RNA (rRNA) 2′O-methyl (2′-O-Me) is the most prevalent posttranscriptional chemical modification contributing to ribosome heterogeneity. The modification involves a family of small nucleolar RNAs (snoRNAs) and is specified by box C/D snoRNAs (SNORDs). Given the importance of ribosome biogenesis for skeletal muscle growth, we asked if rRNA 2′-O-Me in nascent ribosomes synthesized in response to a growth stimulus is an unrecognized mode of ribosome heterogeneity in muscle. To determine the pattern and dynamics of 2′-O-Me rRNA, we used a sequencing-based profiling method called RiboMeth-seq (RMS). We applied this method to tissue-derived rRNA of skeletal muscle and rRNA specifically from the muscle fiber using an inducible myofiber-specific RiboTag mouse in sedentary and mechanically overloaded conditions. These analyses were complemented by myonuclear-specific small RNA sequencing to profile SNORDs and link the rRNA epitranscriptome to known regulatory elements generated within the muscle fiber. We demonstrate for the first time that mechanical overload of skeletal muscle 1) induces decreased 2′-O-Me at a subset of skeletal muscle rRNA and 2) alters the SNORD profile in isolated myonuclei. These findings point to a transient diversification of the ribosome pool via 2′-O-Me during growth and adaptation in skeletal muscle. These findings suggest changes in ribosome heterogeneity at the 2′-O-Me level during muscle hypertrophy and lay the foundation for studies investigating the functional implications of these newly identified "growth-induced" ribosomes. NEW & NOTEWORTHY: Ribosomal RNAs (rRNAs) are posttranscriptionally modified by 2′O-methyl (2′-O-Me). This study applied RiboMeth-seq (RMS) to detect changes in 2′-O-Me levels during skeletal muscle hypertrophy, uncovering transient diversification of the ribosome pool in skeletal muscle fibers. This work implies a role for ribosome heterogeneity in skeletal muscle growth and adaptation. [ABSTRACT FROM AUTHOR]
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- 2024
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10. Skeletal muscle hypertrophy: cell growth is cell growth.
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Burke, Benjamin I., Ismaeel, Ahmed, Walden, Ferdinand von, Murach, Kevin A., and McCarthy, John J.
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CELL growth ,RESISTANCE training ,MUSCULAR hypertrophy ,SKELETAL muscle ,MUSCLE cells - Abstract
Roberts et al. have provided an insightful counterpoint to our review article on the utility of the synergist ablation model. The purpose of this review is to provide some further dialogue regarding the strengths and weaknesses of the synergist ablation model. Specifically, we highlight that the robustness of the model overshadows surgical limitations. We also compare the transcriptomic responses to synergist ablation in mice and resistance exercise in humans to identify common pathways. We conclude that "cell growth is cell growth" and that the mechanisms available to cells to accumulate biomass and increase in size are similar across cell types and independent of the rate of growth. [ABSTRACT FROM AUTHOR]
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- 2024
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11. Myonuclear transcriptional dynamics in response to exercise following satellite cell depletion
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Wen, Yuan, Englund, Davis A., Peck, Bailey D., Murach, Kevin A., McCarthy, John J., and Peterson, Charlotte A.
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- 2021
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12. Early satellite cell communication creates a permissive environment for long-term muscle growth
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Murach, Kevin A., Peck, Bailey D., Policastro, Robert A., Vechetti, Ivan J., Van Pelt, Douglas W., Dungan, Cory M., Denes, Lance T., Fu, Xu, Brightwell, Camille R., Zentner, Gabriel E., Dupont-Versteegden, Esther E., Richards, Christopher I., Smith, Jeramiah J., Fry, Christopher S., McCarthy, John J., and Peterson, Charlotte A.
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- 2021
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13. Exercise-Induced MYC as an Epigenetic Reprogramming Factor That Combats Skeletal Muscle Aging.
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Jones III, Ronald G., von Walden, Ferdinand, and Murach, Kevin A.
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Pulsatile Myc induction, through epigenetic alterations, mediates several aspects of the exercise response and may restore muscle plasticity with age. Of the "Yamanaka factors" Oct3/4 , Sox2 , Klf4 , and c-Myc (OSKM), the transcription factor c-Myc (Myc) is the most responsive to exercise in skeletal muscle and is enriched within the muscle fiber. We hypothesize that the pulsatile induction of MYC protein after bouts of exercise can serve to epigenetically reprogram skeletal muscle toward a more resilient and functional state. [ABSTRACT FROM AUTHOR]
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- 2024
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14. Division-Independent Differentiation of Muscle Stem Cells During a Growth Stimulus.
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Ismaeel, Ahmed, Goh, Jensen, Mobley, C Brooks, Murach, Kevin A, Brett, Jamie O, Morrée, Antoine de, Rando, Thomas A, Peterson, Charlotte A, Wen, Yuan, and McCarthy, John J
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STEM cells ,CELL growth ,MUSCLE cells ,DNA replication ,CELL populations - Abstract
Adult muscle stem cells (MuSCs) are known to replicate upon activation before differentiating and fusing to regenerate myofibers. It is unclear whether MuSC differentiation is intrinsically linked to cell division, which has implications for stem cell population maintenance. We use single-cell RNA-sequencing to identify transcriptionally diverse subpopulations of MuSCs after 5 days of a growth stimulus in adult muscle. Trajectory inference in combination with a novel mouse model for tracking MuSC-derived myonuclei and in vivo labeling of DNA replication revealed an MuSC population that exhibited division-independent differentiation and fusion. These findings demonstrate that in response to a growth stimulus in the presence of intact myofibers, MuSC division is not obligatory. [ABSTRACT FROM AUTHOR]
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- 2024
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15. Neuromuscular Dysfunction Precedes Cognitive Impairment in a Mouse Model of Alzheimer's Disease.
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Brisendine, Matthew H, Nichenko, Anna S, Bandara, Aloka B, Willoughby, Orion S, Amiri, Niloufar, Weingrad, Zach, Specht, Kalyn S, Bond, Jacob M, Addington, Adele, Jones III, Ronald G, Murach, Kevin A, Poelzing, Steven, Craige, Siobhan M, Grange, Robert W, and Drake, Joshua C
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NEUROMUSCULAR transmission ,ALZHEIMER'S disease ,SKELETAL muscle ,COGNITION disorders ,LABORATORY mice ,ACTION potentials ,ANIMAL disease models - Abstract
Alzheimer's disease (AD) develops along a continuum that spans years prior to diagnosis. Decreased muscle function and mitochondrial respiration occur years earlier in those that develop AD; however, it is unknown what causes these peripheral phenotypes in a disease of the brain. Exercise promotes muscle, mitochondria, and cognitive health and is proposed to be a potential therapeutic for AD, but no study has investigated how skeletal muscle adapts to exercise training in an AD-like context. Utilizing 5xFAD mice, an AD model that develops ad-like pathology and cognitive impairments around 6 mo of age, we examined in vivo neuromuscular function and exercise adapations (mitochondrial respiration and RNA sequencing) before the manifestation of overt cognitive impairment. We found 5xFAD mice develop neuromuscular dysfunction beginning as early as 4 mo of age, characterized by impaired nerve-stimulated muscle torque production and compound nerve action potential of the sciatic nerve. Furthermore, skeletal muscle in 5xFAD mice had altered, sex-dependent, adaptive responses (mitochondrial respiration and gene expression) to exercise training in the absence of overt cognitive impairment. Changes in peripheral systems, specifically neural communication to skeletal muscle, may be harbingers for AD and have implications for lifestyle interventions, like exercise, in AD. Graphical Abstract Integrated model for the development of neuromuscular dysfunction in the AD-like pathology of 5xFAD mice. (A) At 3 mo of age, nerve-stimulated muscle function is normal across genotypes and sexes. (B) By as early as 4 mo of age, nerve-stimulated muscle function declines, and (C) corresponds to impaired sciatic nerve function in 5xFAD mice. Peripheral neuromuscular dysfunction (D) corresponds to an altered mitochondrial and transcriptional response of skeletal muscle to exercise training. (E) These peripheral phenotypes of the early AD-like pathology of 5xFAD mice were present in the absence of overt cognitive decline, particularly in male mice. Created in Biorender. [ABSTRACT FROM AUTHOR]
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- 2024
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16. Coordinated Regulation of Myonuclear DNA Methylation, mRNA, and miRNA Levels Associates With the Metabolic Response to Rapid Synergist Ablation-Induced Skeletal Muscle Hypertrophy in Female Mice.
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Ismaeel, Ahmed, Thomas, Nicholas T, McCashland, Mariah, Vechetti, Ivan J, Edman, Sebastian, Lanner, Johanna T, Figueiredo, Vandré C, Fry, Christopher S, McCarthy, John J, Wen, Yuan, Murach, Kevin A, and von Walden, Ferdinand
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SKELETAL muscle ,MOLECULAR biology ,MUSCULAR hypertrophy ,DNA methylation ,DNA analysis ,IMPRINTED polymers - Abstract
The central dogma of molecular biology dictates the general flow of molecular information from DNA that leads to a functional cellular outcome. In skeletal muscle fibers, the extent to which global myonuclear transcriptional alterations, accounting for epigenetic and post-transcriptional influences, contribute to an adaptive stress response is not clearly defined. In this investigation, we leveraged an integrated analysis of the myonucleus-specific DNA methylome and transcriptome, as well as myonuclear small RNA profiling to molecularly define the early phase of skeletal muscle fiber hypertrophy. The analysis of myonucleus-specific mature microRNA and other small RNA species provides new directions for exploring muscle adaptation and complemented the methylation and transcriptional information. Our integrated multi-omics interrogation revealed a coordinated myonuclear molecular landscape during muscle loading that coincides with an acute and rapid reduction of oxidative metabolism. This response may favor a biosynthesis-oriented metabolic program that supports rapid hypertrophic growth. Graphical Abstract [ABSTRACT FROM AUTHOR]
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- 2024
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17. Biological sex divergence in transcriptomic profiles during the onset of hindlimb unloading-induced atrophy.
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Tsitkanou, Stavroula, da Silva, Francielly Morena, Cabrera, Ana Regina, Schrems, Eleanor R., Murach, Kevin A., Washington, Tyrone A., Rosa-Caldwell, Megan E., and Greene, Nicholas P.
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BIOLOGICAL divergence ,PROTEOLYSIS ,SEX (Biology) ,INTENSIVE care patients ,MUSCULAR atrophy ,HINDLIMB ,ATROPHY - Abstract
Disuse-induced muscle atrophy is a common clinical problem observed mainly in older adults, intensive care units patients, or astronauts. Previous studies presented biological sex divergence in progression of disuse-induced atrophy along with differential changes in molecular mechanisms possibly underlying muscle atrophy. The aim of this study was to perform transcriptomic profiling of male and female mice during the onset and progression of unloading disuse-induced atrophy. Male and female mice underwent hindlimb unloading (HU) for 24, 48, 72, and 168 h (n = 8/group). Muscles were weighed for each cohort and gastrocnemius was used for RNA-sequencing analysis. Females exhibited muscle loss as early as 24 h of HU, whereas males after 168 h of HU. In males, pathways related to proteasome degradation were upregulated throughout 168 h of HU, whereas in females these pathways were upregulated up to 72 h of HU. Lcn2, a gene contributing to regulation of myogenesis, was upregulated by 6.46- to 19.86-fold across all time points in females only. A reverse expression of Fosb, a gene related to muscle degeneration, was observed between males (4.27-fold up) and females (4.57-fold down) at 24-h HU. Mitochondrial pathways related to tricarboxylic acid (TCA) cycle were highly downregulated at 168 h of HU in males, whereas in females this downregulation was less pronounced. Collagen-related pathways were consistently downregulated throughout 168 h of HU only in females, suggesting a potential biological sex-specific protective mechanism against disuse-induced fibrosis. In conclusion, females may have protection against HU-induced skeletal muscle mitochondrial degeneration and fibrosis through transcriptional mechanisms, although they may be more vulnerable to HU-induced muscle wasting compared with males. [ABSTRACT FROM AUTHOR]
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- 2023
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18. Response
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Murach, Kevin A., Dungan, Cory M., Peterson, Charlotte A., and McCarthy, John J.
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- 2019
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19. Muscle Fiber Splitting Is a Physiological Response to Extreme Loading in Animals
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Murach, Kevin A., Dungan, Cory M., Peterson, Charlotte A., and McCarthy, John J.
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- 2019
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20. Life-long reduction in myomiR expression does not adversely affect skeletal muscle morphology
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Vechetti, Jr, Ivan J., Wen, Yuan, Chaillou, Thomas, Murach, Kevin A., Alimov, Alexander P., Figueiredo, Vandre C., Dal-Pai-Silva, Maeli, and McCarthy, John J.
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- 2019
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21. MicroRNAs, heart failure, and aging: potential interactions with skeletal muscle
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Murach, Kevin A. and McCarthy, John J.
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- 2017
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22. Characterizing a Novel Rodent Exercise Model to Explore the Permanency of Myonuclear Accretion During Muscle Adaptation: 3263 Board #132 June 2 9: 30 AM - 11: 00 AM
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Dungan, Cory M., Murach, Kevin A., Vechetti, Ivan, Jr, McCarthy, John J., and Peterson, Charlotte A.
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- 2018
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23. The life and times of cellular senescence in skeletal muscle: friend or foe for homeostasis and adaptation?
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Dungan, Cory M., Wells, Jaden M., and Murach, Kevin A.
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A gradual decline in skeletal muscle mass and function is closely tied to increased mortality and disease risk during organismal aging. Exercise training is the most effective way to enhance muscle health, but the adaptive response to exercise as well as muscle repair potential is blunted in older individuals. Numerous mechanisms contribute to the loss of muscle mass and plasticity as aging progresses. An emerging body of recent evidence implicates an accumulation of senescent ("zombie") cells in muscle as a contributing factor to the aging phenotype. Senescent cells cannot divide but can release inflammatory factors and create an unfavorable environment for homeostasis and adaptation. On balance, some evidence indicates that cells with senescent characteristics can be beneficial for the muscle adaptive process, specifically at younger ages. Emerging evidence also suggests that multinuclear muscle fibers could become senescent. In this review, we summarize current literature on the prevalence of senescent cells in skeletal muscle and highlight the consequences of senescent cell removal on muscle mass, function, and adaptability. We examine key limitations in the field of senescence specifically in skeletal muscle and identify areas of research that require future investigation. [ABSTRACT FROM AUTHOR]
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- 2023
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24. MicroRNA control of the myogenic cell transcriptome and proteome: the role of miR-16.
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Seongkyun Lim, Lee, David E., Morena da Silva, Francielly, Koopmans, Pieter J., Vechetti Jr, Ivan J., von Walden, Ferdinand, Greene, Nicholas P., and Murach, Kevin A.
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MYOBLASTS ,CYTOLOGY ,PROGENITOR cells ,TRANSCRIPTOMES ,P53 antioncogene ,PROTEOMICS ,RNA metabolism - Abstract
MicroRNAs (miRs) control stem cell biology and fate. Ubiquitously expressed and conserved miR-16 was the first miR implicated in tumorigenesis. miR-16 is low in muscle during developmental hypertrophy and regeneration. It is enriched in proliferating myogenic progenitor cells but is repressed during differentiation. The induction of miR-16 blocks myoblast differentiation and myotube formation, whereas knockdown enhances these processes. Despite a central role for miR-16 in myogenic cell biology, how it mediates its potent effects is incompletely defined. In this investigation, global transcriptomic and proteomic analyses after miR-16 knockdown in proliferating C2C12 myoblasts revealed how miR-16 influences myogenic cell fate. Eighteen hours after miR-16 inhibition, ribosomal protein gene expression levels were higher relative to control myoblasts and p53 pathway-related gene abundance was lower. At the protein level at this same time point, miR-16 knockdown globally upregulated tricarboxylic acid (TCA) cycle proteins while downregulating RNA metabolism-related proteins. miR-16 inhibition induced specific proteins associated with myogenic differentiation such as ACTA2, EEF1A2, and OPA1. We extend prior work in hypertrophic muscle tissue and show that miR-16 is lower in mechanically overloaded muscle in vivo. Our data collectively point to how miR-16 is implicated in aspects of myogenic cell differentiation. A deeper understanding of the role of miR-16 in myogenic cells has consequences for muscle developmental growth, exercise-induced hypertrophy, and regenerative repair after injury, all of which involve myogenic progenitors. [ABSTRACT FROM AUTHOR]
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- 2023
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25. A novel tetracycline-responsive transgenic mouse strain for skeletal muscle-specific gene expression
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Iwata, Masahiro, Englund, Davis A., Wen, Yuan, Dungan, Cory M., Murach, Kevin A., Vechetti, Jr, Ivan J., Mobley, Christopher B., Peterson, Charlotte A., and McCarthy, John J.
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- 2018
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26. Skeletal Muscle Hypertrophy with Concurrent Exercise Training: Contrary Evidence for an Interference Effect
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Murach, Kevin A. and Bagley, James R.
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- 2016
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27. Improving human skeletal muscle myosin heavy chain fiber typing efficiency
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Murach, Kevin A., Bagley, James R., McLeland, Kathryn A., Arevalo, Jose A., Ciccone, Anthony B., Malyszek, Kylie K., Wen, Yuan, and Galpin, Andrew J.
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- 2016
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28. Depletion of Pax7+ satellite cells does not affect diaphragm adaptations to running in young or aged mice
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Murach, Kevin A., Confides, Amy L., Ho, Angel, Jackson, Janna R., Ghazala, Lina S., Peterson, Charlotte A., and Dupont‐Versteegden, Esther E.
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- 2017
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29. Going nuclear: Molecular adaptations to exercise mediated by myonuclei.
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Koopmans, Pieter J., Zwetsloot, Kevin A., and Murach, Kevin A.
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SKELETAL muscle physiology ,EXERCISE physiology ,MUSCLE cells ,EPIGENETICS ,HOMEOSTASIS ,GENETIC transcription ,MICRORNA - Abstract
Muscle fibers are multinucleated, and muscle fiber nuclei (myonuclei) are believed to be post-mitotic and are typically situated near the periphery of the myofiber. Due to the unique organization of muscle fibers and their nuclei, the cellular and molecular mechanisms regulating myofiber homeostasis in unstressed and stressed conditions (e.g., exercise) are unique. A key role myonuclei play in regulating muscle during exercise is gene transcription. Only recently have investigators had the capability to identify molecular changes at high resolution exclusively in myonuclei in response to perturbations in vivo. The purpose of this review is to describe how myonuclei modulate their transcriptome, epigenetic status, mobility and shape, and microRNA expression in response to exercise in vivo. Given the relative paucity of high-fidelity information on myonucleus-specific contributions to exercise adaptation, we identify specific gaps in knowledge and provide perspectives on future directions of research. [ABSTRACT FROM AUTHOR]
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- 2023
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30. The myonuclear domain in adult skeletal muscle fibres: past, present and future.
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Bagley, James R., Denes, Lance T., McCarthy, John J., Wang, Eric T., and Murach, Kevin A.
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SKELETAL muscle ,FIBERS ,TECHNOLOGICAL innovations ,MUSCLE growth ,CARRIER proteins - Abstract
Most cells in the body are mononuclear whereas skeletal muscle fibres are uniquely multinuclear. The nuclei of muscle fibres (myonuclei) are usually situated peripherally which complicates the equitable distribution of gene products. Myonuclear abundance can also change under conditions such as hypertrophy and atrophy. Specialised zones in muscle fibres have different functions and thus distinct synthetic demands from myonuclei. The complex structure and regulatory requirements of multinuclear muscle cells understandably led to the hypothesis that myonuclei govern defined 'domains' to maintain homeostasis and facilitate adaptation. The purpose of this review is to provide historical context for the myonuclear domain and evaluate its veracity with respect to mRNA and protein distribution resulting from myonuclear transcription. We synthesise insights from past and current in vitro and in vivo genetically modified models for studying the myonuclear domain under dynamic conditions. We also cover the most contemporary knowledge on mRNA and protein transport in muscle cells. Insights from emerging technologies such as single myonuclear RNA‐sequencing further inform our discussion of the myonuclear domain. We broadly conclude: (1) the myonuclear domain can be flexible during muscle fibre growth and atrophy, (2) the mechanisms and role of myonuclear loss and motility deserve further consideration, (3) mRNA in muscle is actively transported via microtubules and locally restricted, but proteins may travel far from a myonucleus of origin and (4) myonuclear transcriptional specialisation extends beyond the classic neuromuscular and myotendinous populations. A deeper understanding of the myonuclear domain in muscle may promote effective therapies for ageing and disease. [ABSTRACT FROM AUTHOR]
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- 2023
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31. A molecular signature defining exercise adaptation with ageing and in vivo partial reprogramming in skeletal muscle.
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Jones, Ronald G., Dimet‐Wiley, Andrea, Haghani, Amin, da Silva, Francielly Morena, Brightwell, Camille R., Lim, Seongkyun, Khadgi, Sabin, Wen, Yuan, Dungan, Cory M., Brooke, Robert T., Greene, Nicholas P., Peterson, Charlotte A., McCarthy, John J., Horvath, Steve, Watowich, Stanley J., Fry, Christopher S., and Murach, Kevin A.
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SKELETAL muscle ,EXERCISE therapy ,SOLEUS muscle ,HYPOXIA-inducible factor 1 ,REACTIVE oxygen species ,GENE expression ,OXYGEN consumption - Abstract
Exercise promotes functional improvements in aged tissues, but the extent to which it simulates partial molecular reprogramming is unknown. Using transcriptome profiling from (1) a skeletal muscle‐specific in vivo Oct3/4, Klf4, Sox2 and Myc (OKSM) reprogramming‐factor expression murine model; (2) an in vivo inducible muscle‐specific Myc induction murine model; (3) a translatable high‐volume hypertrophic exercise training approach in aged mice; and (4) human exercise muscle biopsies, we collectively defined exercise‐induced genes that are common to partial reprogramming. Late‐life exercise training lowered murine DNA methylation age according to several contemporary muscle‐specific clocks. A comparison of the murine soleus transcriptome after late‐life exercise training to the soleus transcriptome after OKSM induction revealed an overlapping signature that included higher JunB and Sun1. Also, within this signature, downregulation of specific mitochondrial and muscle‐enriched genes was conserved in skeletal muscle of long‐term exercise‐trained humans; among these was muscle‐specific Abra/Stars. Myc is the OKSM factor most induced by exercise in muscle and was elevated following exercise training in aged mice. A pulse of MYC rewired the global soleus muscle methylome, and the transcriptome after a MYC pulse partially recapitulated OKSM induction. A common signature also emerged in the murine MYC‐controlled and exercise adaptation transcriptomes, including lower muscle‐specific Melusin and reactive oxygen species‐associated Romo1. With Myc, OKSM and exercise training in mice, as well habitual exercise in humans, the complex I accessory subunit Ndufb11 was lower; low Ndufb11 is linked to longevity in rodents. Collectively, exercise shares similarities with genetic in vivo partial reprogramming. Key points: Advances in the last decade related to cellular epigenetic reprogramming (e.g. DNA methylome remodelling) toward a pluripotent state via the Yamanaka transcription factors Oct3/4, Klf4, Sox2 and Myc (OKSM) provide a window into potential mechanisms for combatting the deleterious effects of cellular ageing.Using global gene expression analysis, we compared the effects of in vivo OKSM‐mediated partial reprogramming in skeletal muscle fibres of mice to the effects of late‐life murine exercise training in muscle.Myc is the Yamanaka factor most induced by exercise in skeletal muscle, and so we compared the MYC‐controlled transcriptome in muscle to Yamanaka factor‐mediated and exercise adaptation mRNA landscapes in mice and humans.A single pulse of MYC is sufficient to remodel the muscle methylome.We identify partial reprogramming‐associated genes that are innately altered by exercise training and conserved in humans, and propose that MYC contributes to some of these responses. [ABSTRACT FROM AUTHOR]
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- 2023
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32. Depressed Protein Synthesis and Anabolic Signaling Potentiate ACL Tear–Resultant Quadriceps Atrophy.
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Keeble, Alexander R., Brightwell, Camille R., Latham, Christine M., Thomas, Nicholas T., Mobley, C. Brooks, Murach, Kevin A., Johnson, Darren L., Noehren, Brian, and Fry, Christopher S.
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PROTEIN metabolism ,MUSCULAR atrophy ,LABORATORY animals ,SEQUENCE analysis ,BIOPSY ,ANIMAL experimentation ,IMMUNOHISTOCHEMISTRY ,RESEARCH methodology ,METABOLISM ,RNA ,CELLULAR signal transduction ,T-test (Statistics) ,OXIDATIVE stress ,ANTERIOR cruciate ligament injuries ,QUADRICEPS muscle ,DESCRIPTIVE statistics ,GENE expression profiling ,DATA analysis software ,TRANSCRIPTION factors ,MICE ,DISEASE risk factors ,DISEASE complications - Abstract
Background: Anterior cruciate ligament (ACL) tear (ACLT) leads to protracted quadriceps muscle atrophy. Protein turnover largely dictates muscle size and is highly responsive to injury and loading. Regulation of quadriceps molecular protein synthetic machinery after ACLT has largely been unexplored, limiting development of targeted therapies. Purpose: To define the effect of ACLT on (1) the activation of protein synthetic and catabolic signaling within quadriceps biopsy specimens from human participants and (2) the time course of alterations to protein synthesis and its molecular regulation in a mouse ACL injury model. Study Design: Descriptive laboratory study. Methods: Muscle biopsy specimens were obtained from the ACL-injured and noninjured vastus lateralis of young adult humans after an overnight fast (N = 21; mean ± SD, 19 ± 5 years). Mice had their limbs assigned to ACLT or control, and whole quadriceps were collected 6 hours or 1, 3, or 7 days after injury with puromycin injected before tissue collection for assessment of relative protein synthesis. Muscle fiber size and expression and phosphorylation of protein anabolic and catabolic signaling proteins were assessed at the protein and transcript levels (RNA sequencing). Results: Human quadriceps showed reduced phosphorylation of ribosomal protein S6 (–41%) in the ACL-injured limb (P =.008), in addition to elevated phosphorylation of eukaryotic initiation factor 2α (+98%; P =.006), indicative of depressed protein anabolic signaling in the injured limb. No differences in E3 ubiquitin ligase expression were noted. Protein synthesis was lower at 1 day (P =.01 vs control limb) and 3 days (P =.002 vs control limb) after ACLT in mice. Pathway analyses revealed shared molecular alterations between human and mouse quadriceps after ACLT. Conclusion: (1) Global protein synthesis and anabolic signaling deficits occur in the quadriceps in response to ACL injury, without notable changes in measured markers of muscle protein catabolism. (2) Importantly, these deficits occur before the onset of significant atrophy, underscoring the need for early intervention. Clinical Relevance: These findings suggest that blunted protein anabolism as opposed to increased catabolism likely mediates quadriceps atrophy after ACL injury. Thus, future interventions should aim to restore muscle protein anabolism rapidly after ACLT. [ABSTRACT FROM AUTHOR]
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- 2023
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33. A glitch in the matrix: the pivotal role for extracellular matrix remodeling during muscle hypertrophy.
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Brightwell, Camille R., Latham, Christine M., Thomas, Nicholas T., Keeble, Alexander R., Murach, Kevin A., and Fry, Christopher S.
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MUSCULAR hypertrophy ,EXTRACELLULAR matrix ,CELL anatomy ,SATELLITE cells ,RESISTANCE training - Abstract
Multinuclear muscle fibers are the most voluminous cells in skeletal muscle and the primary drivers of growth in response to loading. Outside the muscle fiber, however, is a diversity of mononuclear cell types that reside in the extracellular matrix (ECM). These muscle-resident cells are exercise-responsive and produce the scaffolding for successful myofibrillar growth. Without proper remodeling and maintenance of this ECM scaffolding, the ability to mount an appropriate response to resistance training in adult muscles is severely hindered. Complex cellular choreography takes place in muscles following a loading stimulus. These interactions have been recently revealed by single-cell explorations into muscle adaptation with loading. The intricate ballet of ECM remodeling involves collagen production from fibrogenic cells and ECM modifying signals initiated by satellite cells, immune cells, and the muscle fibers themselves. The acellular collagen-rich ECM is also a mechanical signal-transducer and rich repository of growth factors that may directly influence muscle fiber hypertrophy once liberated. Collectively, high levels of collagen expression, deposition, and turnover characterize a well-trained muscle phenotype. The purpose of this review is to highlight the most recent evidence for how the ECM and its cellular components affect loading-induced muscle hypertrophy. We also address how the muscle fiber may directly take part in ECM remodeling, and whether ECM dynamics are rate limiting for muscle fiber growth. [ABSTRACT FROM AUTHOR]
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- 2022
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34. Muscle-Specific Cellular and Molecular Adaptations to Late-Life Voluntary Concurrent Exercise.
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Dungan, Cory M, Brightwell, Camille R, Wen, Yuan, Zdunek, Christopher J, Latham, Christine M, Thomas, Nicholas T, Zagzoog, Alyaa M, Brightwell, Benjamin D, VonLehmden, Georgia L, Keeble, Alexander R, Watowich, Stanley J, Murach, Kevin A, and Fry, Christopher S
- Subjects
MUSCLE aging ,MUSCLE strength ,MUSCLE mass ,DNA methylation ,SATELLITE cells ,MUSCLE growth ,RESISTANCE training - Abstract
Murine exercise models can provide information on factors that influence muscle adaptability with aging, but few translatable solutions exist. Progressive weighted wheel running (PoWeR) is a simple, voluntary, low-cost, high-volume endurance/resistance exercise approach for training young mice. In the current investigation, aged mice (22-mo-old) underwent a modified version of PoWeR for 8 wk. Muscle functional, cellular, biochemical, transcriptional, and myonuclear DNA methylation analyses provide an encompassing picture of how muscle from aged mice responds to high-volume combined training. Mice run 6–8 km/d, and relative to sedentary mice, PoWeR increases plantarflexor muscle strength. The oxidative soleus of aged mice responds to PoWeR similarly to young mice in every parameter measured in previous work; this includes muscle mass, glycolytic-to-oxidative fiber type transitioning, fiber size, satellite cell frequency, and myonuclear number. The oxidative/glycolytic plantaris adapts according to fiber type, but with modest overall changes in muscle mass. Capillarity increases markedly with PoWeR in both muscles, which may be permissive for adaptability in advanced age. Comparison to published PoWeR RNA-sequencing data in young mice identified conserved regulators of adaptability across age and muscles; this includes Aldh1l1 which associates with muscle vasculature. Agrn and Samd1 gene expression is upregulated after PoWeR simultaneous with a hypomethylated promoter CpG in myonuclear DNA, which could have implications for innervation and capillarization. A promoter CpG in Rbm10 is hypomethylated by late-life exercise in myonuclei, consistent with findings in muscle tissue. PoWeR and the data herein are a resource for uncovering cellular and molecular regulators of muscle adaptation with aging. [ABSTRACT FROM AUTHOR]
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- 2022
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35. Exercise Counteracts the Deleterious Effects of Cancer Cachexia.
- Author
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Tsitkanou, Stavroula, Murach, Kevin A., Washington, Tyrone A., and Greene, Nicholas P.
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CANCER patients , *CACHEXIA , *EXERCISE therapy , *CANCER patient rehabilitation , *COMORBIDITY - Abstract
Simple Summary: This review provides an overview of the effects of exercise training on the major mechanisms related to cancer cachexia (CC). The review also discusses how cancer comorbidities can influence the ability of patients/animals with cancer to perform exercise training and what precautions should be taken when they exercise. The contribution of other factors, such as exercise modality and biological sex, to exercise effectiveness in ameliorating CC are also elaborated in the final sections. We provide meticulous evidence for how advantageous exercise training can be in patients/animals with CC at molecular and cellular levels. Finally, we emphasise what factors should be considered to optimise and personalise an exercise training program in CC. Cancer cachexia (CC) is a multifactorial syndrome characterised by unintentional loss of body weight and muscle mass in patients with cancer. The major hallmarks associated with CC development and progression include imbalanced protein turnover, inflammatory signalling, mitochondrial dysfunction and satellite cell dysregulation. So far, there is no effective treatment to counteract muscle wasting in patients with CC. Exercise training has been proposed as a potential therapeutic approach for CC. This review provides an overview of the effects of exercise training in CC-related mechanisms as well as how factors such as cancer comorbidities, exercise modality and biological sex can influence exercise effectiveness in CC. Evidence in mice and humans suggests exercise training combats all of the hallmarks of CC. Several exercise modalities induce beneficial adaptations in patients/animals with CC, but concurrent resistance and endurance training is considered the optimal type of exercise. In the case of cancer patients presenting comorbidities, exercise training should be performed only under specific guidelines and precautions to avoid adverse effects. Observational comparison of studies in CC using different biological sex shows exercise-induced adaptations are similar between male and female patients/animals with cancer, but further studies are needed to confirm this. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
36. A muscle cell‐macrophage axis involving matrix metalloproteinase 14 facilitates extracellular matrix remodeling with mechanical loading.
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Peck, Bailey D., Murach, Kevin A., Walton, R. Grace, Simmons, Alexander J., Long, Douglas E., Kosmac, Kate, Dungan, Cory M., Kern, Philip A., Bamman, Marcas M., and Peterson, Charlotte A.
- Abstract
The extracellular matrix (ECM) in skeletal muscle plays an integral role in tissue development, structural support, and force transmission. For successful adaptation to mechanical loading, remodeling processes must occur. In a large cohort of older adults, transcriptomics revealed that genes involved in ECM remodeling, including matrix metalloproteinase 14 (MMP14), were the most upregulated following 14 weeks of progressive resistance exercise training (PRT). Using single‐cell RNA‐seq, we identified macrophages as a source of Mmp14 in muscle following a hypertrophic exercise stimulus in mice. In vitro contractile activity in myotubes revealed that the gene encoding cytokine leukemia inhibitory factor (LIF) is robustly upregulated and can stimulate Mmp14 expression in macrophages. Functional experiments confirmed that modulation of this muscle cell‐macrophage axis facilitated Type I collagen turnover. Finally, changes in LIF expression were significantly correlated with MMP14 expression in humans following 14 weeks of PRT. Our experiments reveal a mechanism whereby muscle fibers influence macrophage behavior to promote ECM remodeling in response to mechanical loading. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
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37. Deletion of SA β‐Gal+ cells using senolytics improves muscle regeneration in old mice.
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Dungan, Cory M., Murach, Kevin A., Zdunek, Christopher J., Tang, Zuo Jian, VonLehmden, Georgia L., Brightwell, Camille R., Hettinger, Zachary, Englund, Davis A., Liu, Zheng, Fry, Christopher S., Filareto, Antonio, Franti, Michael, and Peterson, Charlotte A.
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- *
MUSCLE regeneration , *MICE , *MYOBLASTS , *LABORATORY mice , *SKELETAL muscle - Abstract
Systemic deletion of senescent cells leads to robust improvements in cognitive, cardiovascular, and whole‐body metabolism, but their role in tissue reparative processes is incompletely understood. We hypothesized that senolytic drugs would enhance regeneration in aged skeletal muscle. Young (3 months) and old (20 months) male C57Bl/6J mice were administered the senolytics dasatinib (5 mg/kg) and quercetin (50 mg/kg) or vehicle bi‐weekly for 4 months. Tibialis anterior (TA) was then injected with 1.2% BaCl2 or PBS 7‐ or 28 days prior to euthanization. Senescence‐associated β‐Galactosidase positive (SA β‐Gal+) cell abundance was low in muscle from both young and old mice and increased similarly 7 days following injury in both age groups, with no effect of D+Q. Most SA β‐Gal+ cells were also CD11b+ in young and old mice 7‐ and 14 days following injury, suggesting they are infiltrating immune cells. By 14 days, SA β‐Gal+/CD11b+ cells from old mice expressed senescence genes, whereas those from young mice expressed higher levels of genes characteristic of anti‐inflammatory macrophages. SA β‐Gal+ cells remained elevated in old compared to young mice 28 days following injury, which were reduced by D+Q only in the old mice. In D+Q‐treated old mice, muscle regenerated following injury to a greater extent compared to vehicle‐treated old mice, having larger fiber cross‐sectional area after 28 days. Conversely, D+Q blunted regeneration in young mice. In vitro experiments suggested D+Q directly improve myogenic progenitor cell proliferation. Enhanced physical function and improved muscle regeneration demonstrate that senolytics have beneficial effects only in old mice. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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38. Late‐life exercise mitigates skeletal muscle epigenetic aging.
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Murach, Kevin A., Dimet‐Wiley, Andrea L., Wen, Yuan, Brightwell, Camille R., Latham, Christine M., Dungan, Cory M., Fry, Christopher S., and Watowich, Stanley J.
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- *
MUSCLE aging , *RIBOSOMAL DNA , *EXERCISE therapy , *RECOMBINANT DNA , *EPIGENETICS , *RESISTANCE training - Abstract
There are functional benefits to exercise in muscle, even when performed late in life, but the contributions of epigenetic factors to late‐life exercise adaptation are poorly defined. Using reduced representation bisulfite sequencing (RRBS), ribosomal DNA (rDNA) and mitochondrial‐specific examination of methylation, targeted high‐resolution methylation analysis, and DNAge™ epigenetic aging clock analysis with a translatable model of voluntary murine endurance/resistance exercise training (progressive weighted wheel running, PoWeR), we provide evidence that exercise may mitigate epigenetic aging in skeletal muscle. Late‐life PoWeR from 22–24 months of age modestly but significantly attenuates an age‐associated shift toward promoter hypermethylation. The epigenetic age of muscle from old mice that PoWeR‐trained for eight weeks was approximately eight weeks younger than 24‐month‐old sedentary counterparts, which represents ~8% of the expected murine lifespan. These data provide a molecular basis for exercise as a therapy to attenuate skeletal muscle aging. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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39. Epigenetic evidence for distinct contributions of resident and acquired myonuclei during long-term exercise adaptation using timed in vivo myonuclear labeling.
- Author
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Murach, Kevin A., Dungan, Cory M., von Walden, Ferdinand, and Yuan Wen
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- *
SATELLITE cells , *EPIGENETICS , *CELL nuclei , *RIBOSOMAL proteins , *DNA methylation , *GENETIC models , *MUSCLE growth - Abstract
Muscle fibers are syncytial postmitotic cells that can acquire exogenous nuclei from resident muscle stem cells, called satellite cells. Myonuclei are added to muscle fibers by satellite cells during conditions such as load-induced hypertrophy. It is difficult to dissect the molecular contributions of resident versus satellite cell-derived myonuclei during adaptation due to the complexity of labeling distinct nuclear populations in multinuclear cells without label transference between nuclei. To sidestep this barrier, we used a genetic mouse model where myonuclear DNA can be specifically and stably labeled via nonconstitutive H2B-GFP at any point in the lifespan. Resident myonuclei (Mn) were GFP-tagged in vivo before 8 wk of progressive weighted wheel running (PoWeR) in adult mice (>4-mo-old). Resident þ satellite cell-derived myonuclei (MnþSC Mn) were labeled at the end of PoWeR in a separate cohort. Following myonuclear isolation, promoter DNA methylation profiles acquired with low-input reduced representation bisulfite sequencing (RRBS) were compared to deduce epigenetic contributions of satellite cell-derived myonuclei during adaptation. Resident myonuclear DNA has hypomethylated promoters in genes related to protein turnover, whereas the addition of satellite cell-derived myonuclei shifts myonuclear methylation profiles to favor transcription factor regulation and cellcell signaling. By comparing myonucleus-specific methylation profiling to previously published single-nucleus transcriptional analysis in the absence (Mn) versus the presence of satellite cells (MnþSC Mn) with PoWeR, we provide evidence that satellite cellderived myonuclei may preferentially supply specific ribosomal proteins to growing myofibers and retain an epigenetic "memory" of prior stem cell identity. These data offer insights on distinct epigenetic myonuclear characteristics and contributions during adult muscle growth. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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40. Nucleus Type-Specific DNA Methylomics Reveals Epigenetic "Memory" of Prior Adaptation in Skeletal Muscle.
- Author
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Wen, Yuan, Dungan, Cory M, Mobley, C Brooks, Valentino, Taylor, von Walden, Ferdinand, and Murach, Kevin A
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WNT genes ,EPIGENETICS ,PROMOTERS (Genetics) ,DNA ,MUSCLE growth ,GENE expression - Abstract
Using a mouse model of conditional and inducible in vivo fluorescent myonuclear labeling (HSA-GFP), sorting purification of nuclei, low-input reduced representation bisulfite sequencing (RRBS), and a translatable and reversible model of exercise (progressive weighted wheel running, PoWeR), we provide the first nucleus type-specific epigenetic information on skeletal muscle adaptation and detraining. Adult (>4 mo) HSA-GFP mice performed PoWeR for 8 wk then detrained for 12 wk; age-matched untrained mice were used to control for the long duration of the study. Myonuclei and interstitial nuclei from plantaris muscles were isolated for RRBS. Relative to untrained, PoWeR caused similar myonuclear CpG hypo- and hyper-methylation of promoter regions and substantial hypomethylation in interstitial nuclear promoters. Over-representation analysis of promoters revealed a larger number of hyper- versus hypo-methylated pathways in both nuclear populations after training and evidence for reciprocal regulation of methylation between nucleus types, with hypomethylation of promoter regions in Wnt signaling-related genes in myonuclei and hypermethylation in interstitial nuclei. After 12 wk of detraining, promoter CpGs in documented muscle remodeling-associated genes and pathways that were differentially methylated immediately after PoWeR were persistently differentially methylated in myonuclei, along with long-term promoter hypomethylation in interstitial nuclei. No enduring gene expression changes in muscle tissue were observed using RNA-sequencing. Upon 4 wk of retraining, mice that trained previously grew more at the whole muscle and fiber type-specific cellular level than training naïve mice, with no difference in myonuclear number. Muscle nuclei have a methylation epi-memory of prior training that may augment muscle adaptability to retraining. Graphical Abstract [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
41. Reduced mitochondrial DNA and OXPHOS protein content in skeletal muscle of children with cerebral palsy.
- Author
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von Walden, Ferdinand, Vechetti, Ivan J, Englund, Davis, Figueiredo, Vandré C, Fernandez‐Gonzalo, Rodrigo, Murach, Kevin, Pingel, Jessica, Mccarthy, John J, Stål, Per, and Pontén, Eva
- Subjects
CHILDREN with cerebral palsy ,TYPE 2 diabetes ,MITOCHONDRIAL DNA ,SKELETAL muscle ,SPECIFIC language impairment in children ,PGC-1 protein ,AEROBIC capacity - Abstract
Skeletal muscle in individuals with CP also contains lower amounts of mtDNA, potentially indicating fewer mitochondria in CP skeletal muscle compared with typically developing muscle. We compared skeletal muscle samples from children with cerebral palsy (CP) and typically developing children and observed evidence of reduced mtDNA and OXPHOS protein content in CP skeletal muscle, indicating reduced mitochondrial abundance. Cerebral palsy (CP) muscle contains fewer energy-generating organelles than typically developing muscle. [Extracted from the article]
- Published
- 2021
- Full Text
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42. Genetic and epigenetic regulation of skeletal muscle ribosome biogenesis with exercise.
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Figueiredo, Vandré C., Wen, Yuan, Alkner, Björn, Fernandez‐Gonzalo, Rodrigo, Norrbom, Jessica, Vechetti, Ivan J., Valentino, Taylor, Mobley, C. Brooks, Zentner, Gabriel E., Peterson, Charlotte A., McCarthy, John J., Murach, Kevin A., and Walden, Ferdinand
- Subjects
ORGANELLE formation ,GENETIC regulation ,SKELETAL muscle ,RIBOSOMAL DNA ,CHLOROPLAST DNA ,RESISTANCE training - Abstract
Key points: Ribosome biogenesis and MYC transcription are associated with acute resistance exercise (RE) and are distinct from endurance exercise in human skeletal muscle throughout a 24 h time course of recovery.A PCR‐based method for relative ribosomal DNA (rDNA) copy number estimation was validated by whole genome sequencing and revealed that rDNA dosage is positively correlated with ribosome biogenesis in response to RE.Acute RE modifies rDNA methylation patterns in enhancer, intergenic spacer and non‐canonical MYC‐associated regions, but not the promoter.Myonuclear‐specific rDNA methylation patterns with acute mechanical overload in mice corroborate and expand on rDNA findings with RE in humans.A genetic predisposition for hypertrophic responsiveness may exist based on rDNA gene dosage. Ribosomes are the macromolecular engines of protein synthesis. Skeletal muscle ribosome biogenesis is stimulated by exercise, although the contribution of ribosomal DNA (rDNA) copy number and methylation to exercise‐induced rDNA transcription is unclear. To investigate the genetic and epigenetic regulation of ribosome biogenesis with exercise, a time course of skeletal muscle biopsies was obtained from 30 participants (18 men and 12 women; 31 ± 8 years, 25 ± 4 kg m–2) at rest and 30 min, 3 h, 8 h and 24 h after acute endurance (n = 10, 45 min cycling, 70% V̇O2max) or resistance exercise (n = 10, 4 × 7 × 2 exercises); 10 control participants underwent biopsies without exercise. rDNA transcription and dosage were assessed using quantitative PCR and whole genome sequencing. rDNA promoter methylation was investigated using massARRAY EpiTYPER and global rDNA CpG methylation was assessed using reduced‐representation bisulphite sequencing. Ribosome biogenesis and MYC transcription were associated primarily with resistance but not endurance exercise, indicating preferential up‐regulation during hypertrophic processes. With resistance exercise, ribosome biogenesis was associated with rDNA gene dosage, as well as epigenetic changes in enhancer and non‐canonical MYC‐associated areas in rDNA, but not the promoter. A mouse model of in vivo metabolic RNA labelling and genetic myonuclear fluorescence labelling validated the effects of an acute hypertrophic stimulus on ribosome biogenesis and Myc transcription, and also corroborated rDNA enhancer and Myc‐associated methylation alterations specifically in myonuclei. The present study provides the first information on skeletal muscle genetic and rDNA gene‐wide epigenetic regulation of ribosome biogenesis in response to exercise, revealing novel roles for rDNA dosage and CpG methylation. Key points: Ribosome biogenesis and MYC transcription are associated with acute resistance exercise (RE) and are distinct from endurance exercise in human skeletal muscle throughout a 24 h time course of recovery.A PCR‐based method for relative ribosomal DNA (rDNA) copy number estimation was validated by whole genome sequencing and revealed that rDNA dosage is positively correlated with ribosome biogenesis in response to RE.Acute RE modifies rDNA methylation patterns in enhancer, intergenic spacer and non‐canonical MYC‐associated regions, but not the promoter.Myonuclear‐specific rDNA methylation patterns with acute mechanical overload in mice corroborate and expand on rDNA findings with RE in humans.A genetic predisposition for hypertrophic responsiveness may exist based on rDNA gene dosage. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
43. Muscle memory: myonuclear accretion, maintenance, morphology, and miRNA levels with training and detraining in adult mice.
- Author
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Murach, Kevin A., Mobley, C. Brooks, Zdunek, Christopher J., Frick, Kaitlyn K., Jones, Savannah R., McCarthy, John J., Peterson, Charlotte A., and Dungan, Cory M.
- Subjects
MUSCLE growth ,SKELETAL muscle ,SOLEUS muscle ,MUSCLES ,MICRORNA ,MORPHOLOGY ,EXERCISE - Abstract
Background: In the context of mass regulation, 'muscle memory' can be defined as long‐lasting cellular adaptations to hypertrophic exercise training that persist during detraining‐induced atrophy and may facilitate future adaptation. The cellular basis of muscle memory is not clearly defined but may be related to myonuclear number and/or epigenetic changes within muscle fibres. Methods: Utilizing progressive weighted wheel running (PoWeR), a novel murine exercise training model, we explored myonuclear dynamics and skeletal muscle miRNA levels with training and detraining utilizing immunohistochemistry, single fibre myonuclear analysis, and quantitative analysis of miRNAs. We also used a genetically inducible mouse model of fluorescent myonuclear labelling to study myonuclear adaptations early during exercise. Results: In the soleus, oxidative type 2a fibres were larger after 2 months of PoWeR (P = 0.02), but muscle fibre size and myonuclear number did not return to untrained levels after 6 months of detraining. Soleus type 1 fibres were not larger after PoWeR but had significantly more myonuclei, as well as central nuclei (P < 0.0001), the latter from satellite cell‐derived or resident myonuclei, appearing early during training and remaining with detraining. In the gastrocnemius muscle, oxidative type 2a fibres of the deep region were larger and contained more myonuclei after PoWeR (P < 0.003), both of which returned to untrained levels after detraining. In the gastrocnemius and plantaris, two muscles where myonuclear number was comparable with untrained levels after 6 months of detraining, myonuclei were significantly elongated with detraining (P < 0.0001). In the gastrocnemius, miR‐1 was lower with training and remained lower after detraining (P < 0.002). Conclusions: This study found that (i) myonuclei gained during hypertrophy are lost with detraining across muscles, even in oxidative fibres; (ii) complete reversal of muscle adaptations, including myonuclear number, to untrained levels occurs within 6 months in the plantaris and gastrocnemius; (iii) the murine soleus is resistant to detraining; (iv) myonuclear accretion occurs early with wheel running and can be uncoupled from muscle fibre hypertrophy; (v) resident (non‐satellite cell‐derived) myonuclei can adopt a central location; (vi) myonuclei change shape with training and detraining; and (vii) miR‐1 levels may reflect a memory of previous adaptation that facilitates future growth. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
44. The myonuclear DNA methylome in response to an acute hypertrophic stimulus.
- Author
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Von Walden, Ferdinand, Rea, Matthew, Mobley, C. Brooks, Fondufe-Mittendorf, Yvonne, McCarthy, John J., Peterson, Charlotte A., and Murach, Kevin A.
- Subjects
DNA methylation ,AUTOPHAGY ,SKELETAL muscle ,EPIGENETICS ,MTOR inhibitors - Abstract
In addition to multi-nucleated muscle fibres, numerous resident and infiltrating mononuclear cells populate the muscle compartment. As most epigenetic assays in skeletal muscle are conducted on whole tissue homogenates, essentially nothing is known about regulatory processes exclusively within muscle fibres in vivo. Utilizing a novel genetically modified mouse model developed by our laboratory, we (1) outline a simple and rapid workflow for isolating pure myonuclei from small tissue samples via fluorescent activated cell sorting and extracting high-quality large-fragment DNA for downstream analyses, and (2) provide information on myonuclear and interstitial cell nuclear CpG DNA methylation via reduced representation bisulphite sequencing (RRBS) using mice that were subjected to an acute mechanical overload of the plantaris muscle. In 3-month-old mice, myonuclei are ~50% of total nuclei in sham and ~30% in 3-d overloaded muscle, the difference being attributable to mononuclear cell infiltration and proliferation with overload. In purified myonuclei, pathway analysis of hypomethylated promoter regions following overload was distinct from interstitial nuclei and revealed marked regulation of factors that converge on the master regulator of muscle growth mTOR, and on autophagy. Specifically, acute hypomethylation of Rheb, Rictor, Hdac1, and Hdac2, in addition to a major driver of ribosome biogenesis Myc, reveals the epigenetic regulation of hypertrophic signalling within muscle fibres that may underpin the long-term growth response to loading. This study provides foundational information on global myonuclear epigenetics in vivo using RRBS, and demonstrates the importance of isolating specific nuclear populations to study the epigenetic regulation of skeletal muscle fibre adaptation. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
45. Making Mice Mighty: recent advances in translational models of load-induced muscle hypertrophy.
- Author
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Murach, Kevin A., McCarthy, John J., Peterson, Charlotte A., and Dungan, Cory M.
- Subjects
MUSCLE growth ,MUSCLE mass ,SKELETAL muscle ,MICE ,MECHANICAL models - Abstract
The ability to genetically manipulate mice allows for gainand loss-of-function in vivo, making them an ideal model for elucidating mechanisms of skeletal muscle mass regulation. Combining genetic models with mechanical muscle loading enables identification of specific factors involved in the hypertrophic response as well as the ability to test the requirement of those factors for adaptation, thereby informing performance and therapeutic interventions. Until recently, approaches for inducing mechanically mediated muscle hypertrophy (i.e., resistance-training analogs) have been limited and considered "nontranslatable" to humans. This mini-review outlines recent translational advances in loading-mediated strategies for inducing muscle hypertrophy in mice, and highlights the advantages and disadvantages of each method. The skeletal muscle field is poised for new breakthroughs in understanding mechanisms regulating load-induced muscle growth given the numerous murine tools that have very recently been described. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
46. Depletion of resident muscle stem cells negatively impacts running volume, physical function, and muscle fiber hypertrophy in response to lifelong physical activity.
- Author
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Englund, Davis A., Murach, Kevin A., Dungan, Cory M., Figueiredo, Vandré C., Vechetti, Ivan J., Dupont-Versteegden, Esther E., McCarthy, John J., and Peterson, Charlotte A.
- Abstract
To date, studies that have aimed to investigate the role of satellite cells during adult skeletal muscle adaptation and hypertrophy have utilized a nontranslational stimulus and/or have been performed over a relatively short time frame. Although it has been shown that satellite cell depletion throughout adulthood does not drive skeletal muscle loss in sedentary mice, it remains unknown how satellite cells participate in skeletal muscle adaptation to long-term physical activity. The current study was designed to determine whether reduced satellite cell content throughout adulthood would influence the transcriptome-wide response to physical activity and diminish the adaptive response of skeletal muscle. We administered vehicle or tamoxifen to adult Pax7-diphtheria toxin A (DTA) mice to deplete satellite cells and assigned them to sedentary or wheel-running conditions for 13 mo. Satellite cell depletion throughout adulthood reduced balance and coordination, overall running volume, and the size of muscle proprioceptors (spindle fibers). Furthermore, satellite cell participation was necessary for optimal muscle fiber hypertrophy but not adaptations in fiber type distribution in response to lifelong physical activity. Transcriptome-wide analysis of the plantaris and soleus revealed that satellite cell function is muscle type specific; satellite cell-dependent myonuclear accretion was apparent in oxidative muscles, whereas initiation of G protein-coupled receptor (GPCR) signaling in the glycolytic plantaris may require satellite cells to induce optimal adaptations to long-term physical activity. These findings suggest that satellite cells play a role in preserving physical function during aging and influence muscle adaptation during sustained periods of physical activity. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
47. Fusion-Independent Satellite Cell Communication to Muscle Fibers During Load-Induced Hypertrophy.
- Author
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Murach, Kevin A., Vechetti Jr., Ivan J., Van Pelt, Douglas W., Crow, Samuel E., Dungan, Cory M., Figueiredo, Vandre C., Kosmac, Kate, Xu Fu, Richards, Christopher I., Fry, Christopher S., McCarthy, John J., and Peterson, Charlotte A.
- Abstract
The "canonical" function of Pax7þ muscle stem cells (satellite cells) during hypertrophic growth of adult muscle fibers is myonuclear donation via fusion to support increased transcriptional output. In recent years, however, emerging evidence suggests that satellite cells play an important secretory role in promoting load-mediated growth. Utilizing genetically modified mouse models of delayed satellite cell fusion and in vivo extracellular vesicle (EV) tracking, we provide evidence for satellite cell communication to muscle fibers during hypertrophy. Myogenic progenitor cell-EV-mediated communication to myotubes in vitro influences extracellular matrix (ECM)-related gene expression, which is congruent with in vivo overload experiments involving satellite cell depletion, as well as in silico analyses. Satellite cell-derived EVs can transfer a Creinduced, cytoplasmic-localized fluorescent reporter to muscle cells as well as microRNAs that regulate ECM genes such as matrix metalloproteinase 9 (Mmp9), which may facilitate growth. Delayed satellite cell fusion did not limit long-term loadinduced muscle hypertrophy indicating that early fusion-independent communication from satellite cells to muscle fibers is an underappreciated aspect of satellite cell biology. We cannot exclude the possibility that satellite cell-mediated myonuclear accretion is necessary to maintain prolonged growth, specifically in the later phases of adaptation, but these data collectively highlight how EV delivery from satellite cells can directly contribute to mechanical load-induced muscle fiber hypertrophy, independent of cell fusion to the fiber. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
48. Fiber typing human skeletal muscle with fluorescent immunohistochemistry.
- Author
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Murach, Kevin A., Dungan, Cory M., Kosmac, Kate, Voigt, Thomas B., Tourville, Timothy W., Miller, Mark S., Bamman, Marcas M., Peterson, Charlotte A., and Toth, Michael J.
- Subjects
SKELETAL muscle ,HUMAN biology ,IMMUNOHISTOCHEMISTRY ,FIBERS ,GEL electrophoresis - Abstract
Skeletal muscle myosin heavy chain (MyHC) fiber type composition is a critical determinant of overall muscle function and health. Various approaches interrogate fiber type at the single cell, but the two most commonly utilized are single-muscle fiber sodium dodecyl sulfate-polyacrylamide gel electrophoresis (smfSDS-PAGE) and fluorescent immunohistochemistry (IHC). Although smfSDS-PAGE is generally considered the "gold standard," IHC is more commonly used because of its time-effectiveness and relative ease. Unfortunately, there is lingering inconsistency on how best to accurately and quickly determine fiber type via IHC and an overall misunderstanding regarding pure fiber type proportions, specifically the abundance of fibers exclusively expressing highly glycolytic MyHC IIX in humans. We therefore 1) present information and data showing the low abundance of pure MyHC IIX muscle fibers in healthy human skeletal muscle and 2) leverage this information to provide straightforward protocols that are informed by human biology and employ inexpensive, easily attainable antibodies for the accurate determination of fiber type. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
49. Resident muscle stem cells are not required for testosterone-induced skeletal muscle hypertrophy.
- Author
-
Englund, Davis A., Peck, Bailey D., Murach, Kevin A., Neal, Ally C., Caldwell, Hannah A., McCarthy, John J., Peterson, Charlotte A., and Dupont-Versteegden, Esther E.
- Subjects
MUSCLE growth ,MUSCLE cells ,STEM cells ,SKELETAL muscle ,SATELLITE cells ,SOLEUS muscle ,CELL fusion - Abstract
It is postulated that testosterone-induced skeletal muscle hypertrophy is driven by myonuclear accretion as the result of satellite cell fusion. To directly test this hypothesis, we utilized the Pax7-DTA mouse model to deplete satellite cells in skeletal muscle followed by testosterone administration. Pax7-DTA mice (6 mo of age) were treated for 5 days with either vehicle [satellite cell replete (SC+)] or tamoxifen [satellite cell depleted (SC-)]. Following a washout period, a testosterone propionate or sham pellet was implanted for 21 days. Testosterone administration caused a significant increase in muscle fiber crosssectional area in SC+ and SC- mice in both oxidative (soleus) and glycolytic (plantaris and extensor digitorum longus) muscles. In SC+ mice treated with testosterone, there was a significant increase in both satellite cell abundance and myonuclei that was completely absent in testosterone-treated SC- mice. These findings provide direct evidence that testosterone-induced muscle fiber hypertrophy does not require an increase in satellite cell abundance or myonuclear accretion. Listen to a podcast about this Rapid Report with senior author E. E. Dupont-Versteegden (https://ajpcell.podbean.com/e/podcast-on-paperthat- shows-testosterone-induced-skeletal-muscle-hypertrophydoes- not-need-muscle-stem-cells/). [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
50. Elevated myonuclear density during skeletal muscle hypertrophy in response to training is reversed during detraining.
- Author
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Dungan, Cory M., Murach, Kevin A., Frick, Kaitlyn K., Jones, Savannah R., Crow, Samuel E., Englund, Davis A., Vechetti Jr., Ivan J., Figueiredo, Vandre C., Levitan, Bryana M., Satin, Jonathan, McCarthy, John J., and Peterson, Charlotte A.
- Subjects
- *
MUSCLE growth , *SKELETAL muscle , *MUSCLE mass , *SKELETAL muscle physiology , *EXERCISE tests , *DENSITY , *MUSCLES - Abstract
Myonuclei gained during exercise-induced skeletal muscle hypertrophy may be long-lasting and could facilitate future muscle adaptability after deconditioning, a concept colloquially termed "muscle memory." The evidence for this is limited, mostly due to the lack of a murine exercise-training paradigm that is nonsurgical and reversible. To address this limitation, we developed a novel progressive weightedwheel- running (PoWeR) model of murine exercise training to test whether myonuclei gained during exercise persist after detraining. We hypothesized that myonuclei acquired during training-induced hypertrophy would remain following loss of muscle mass with detraining. Singly housed female C57BL/6J mice performed 8 wk of PoWeR, while another group performed 8 wk of PoWeR followed by 12 wk of detraining. Age-matched sedentary cage-dwelling mice served as untrained controls. Eight weeks of PoWeR yielded significant plantaris muscle fiber hypertrophy, a shift to a more oxidative phenotype, and greater myonuclear density than untrained mice. After 12 wk of detraining, the plantaris muscle returned to an untrained phenotype with fewer myonuclei. A finding of fewer myonuclei simultaneously with plantaris deconditioning argues against a muscle memory mechanism mediated by elevated myonuclear density in primarily fasttwitch muscle. PoWeR is a novel, practical, and easy-to-deploy approach for eliciting robust hypertrophy in mice, and our findings can inform future research on the mechanisms underlying skeletal muscle adaptive potential and muscle memory. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
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