23 results on '"Peck, Bailey D."'
Search Results
2. Myonuclear transcriptional dynamics in response to exercise following satellite cell depletion
- Author
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Wen, Yuan, Englund, Davis A., Peck, Bailey D., Murach, Kevin A., McCarthy, John J., and Peterson, Charlotte A.
- Published
- 2021
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3. 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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4. Associations of muscle lipid content with physical function and resistance training outcomes in older adults: altered responses with metformin
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Long, Douglas E., Peck, Bailey D., Tuggle, Steven C., Villasante Tezanos, Alejandro G., Windham, Samuel T., Bamman, Marcas M., Kern, Philip A., Peterson, Charlotte A., and Walton, Rosicka G.
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- 2021
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5. Human skeletal muscle macrophages increase following cycle training and are associated with adaptations that may facilitate growth
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Walton, R. Grace, Kosmac, Kate, Mula, Jyothi, Fry, Christopher S., Peck, Bailey D., Groshong, Jason S., Finlin, Brian S., Zhu, Beibei, Kern, Philip A., and Peterson, Charlotte A.
- Published
- 2019
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6. Elevated Myostatin Expression Promotes Skeletal Muscle Fibrogenic Cell Expansion Following ACL Injury: 3269 Board #138 June 2 9: 30 AM - 11: 00 AM
- Author
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Fry, Christopher S., Peck, Bailey D., Johnson, Darren L., Ireland, Mary L., and Noehren, Brian
- Published
- 2018
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7. Altered left ventricular performance in aging physically active mice with an ankle sprain injury
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Turner, Michael J., Guderian, Sophie, Wikstrom, Erik A., Huot, Joshua R., Peck, Bailey D., Arthur, Susan T., Marino, Joseph S., and Hubbard-Turner, Tricia
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- 2016
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8. Skeletal muscle properties show collagen organization and immune cell content are associated with resistance exercise response heterogeneity in older persons.
- Author
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Long, Douglas E., Peck, Bailey D., Lavin, Kaleen M., Dungan, Cory M., Kosmac, Kate, Tuggle, Steven C., Bamman, Marcas M., Kern, Philip A., and Peterson, Charlotte A.
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OLDER people ,RESISTANCE training ,SKELETAL muscle ,DUAL-energy X-ray absorptiometry ,COLLAGEN - Abstract
In older Individuals, hypertrophy from progressive resistance training (PRT) is compromised In approximately one-third of participants In exercise trials. The objective of this study was to establish novel relationships between baseline muscle features and/or their PRT-induced change in vastus lateralis muscle biopsies with hypertrophy outcomes. Multiple linear regression analyses adjusted for sex were performed on phenotypic data from older adults (n = 48 participants, 70.8±4.5 yr) completing 14 wk of PRT. Results show that baseline muscle size associates with growth regardless of hypertrophy outcome measure [fiber cross-sectional area (fCSA), β = -0.76, Adj. P < 0.01; thigh muscle area by computed tomography (CT), β = -0.75, Adj. P < 0.01; dual-energy X-ray absorptiometry (DXA) thigh lean mass, β = -0.47, Adj. P < 0.05]. Furthermore, loosely packed collagen organization (CO, β = -0.44, Adj. P < 0.05) and abundance of CD11b+/CD206- immune cells (β = -0.36, Adj. P = 0.10) were negatively associated with whole muscle hypertrophy, with a significant sex interaction on the latter. In addition, a composite hypertrophy score generated using all three measures reinforces significant fiber level findings that changes in myonuclei (MN) (β = 0.67, Adj. P < 0.01), changes in immune cells (β = 0.48, Adj. P < 0.05; both CD11b+/CD206 + and CD11b+/CD206- cells), and capillary density (β = 0.56, Adj. P < 0.01) are significantly associated with growth. Exploratory single-cell RNA-sequencing of CD11b+ cells in muscle in response to resistance exercise showed that macrophages have a mixed phenotype. Collagen associations with macrophages may be an important aspect in muscle response heterogeneity. Detailed histological phenotyping of muscle combined with multiple measures of growth response to resistance training in older persons identify potential new mechanisms underlying response heterogeneity and possible sex differences. NEW & NOTEWORTHY Extensive analyses of muscle features associated with muscle size and resistance training response in older persons, including sex differences, and evaluation of multiple measures of hypertrophy are discussed. Collagen organization and CD11b-expressing immune cells offer potential new targets to augment growth response in older individuals. A hypertrophy composite score reveals that changes in immune cells, myonuclei, and capillary density are critically important for overall muscle growth while sc-RNAseq reveals evidence for macrophage heterogeneity. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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9. Mechanotherapy Reprograms Aged Muscle Stromal Cells to Remodel the Extracellular Matrix during Recovery from Disuse.
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Hettinger, Zachary R, Wen, Yuan, Peck, Bailey D, Hamagata, Kyoko, Confides, Amy L, Van Pelt, Douglas W, Harrison, Douglas A, Miller, Benjamin F, Butterfield, Timothy A, and Dupont-Versteegden, Esther E
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EXTRACELLULAR matrix ,MUSCLE cells ,STROMAL cells ,PERICYTES ,MECHANOTHERAPY ,GENE regulatory networks ,ANTIGEN presenting cells ,CHEMOTAXIS - Abstract
Aging is accompanied by reduced remodeling of skeletal muscle extracellular matrix (ECM), which is exacerbated during recovery following periods of disuse atrophy. Mechanotherapy has been shown to promote ECM remodeling through immunomodulation in adult muscle recovery, but not during the aged recovery from disuse. In order to determine if mechanotherapy promotes ECM remodeling in aged muscle, we performed single cell RNA sequencing (scRNA-seq) of all mononucleated cells in adult and aged rat gastrocnemius muscle recovering from disuse, with (REM) and without mechanotherapy (RE). We show that fibroadipogenic progenitor cells (FAPs) in aged RE muscle are highly enriched in chemotaxis genes (Csf1), but absent in ECM remodeling genes compared to adult RE muscle (Col1a1). Receptor-ligand (RL) network analysis of all mononucleated cell populations in aged RE muscle identified chemotaxis-enriched gene expression in numerous stromal cell populations (FAPs, endothelial cells, pericytes), despite reduced enrichment of genes related to phagocytic activity in myeloid cell populations (macrophages, monocytes, antigen presenting cells). Following mechanotherapy, aged REM mononuclear cell gene expression resembled adult RE muscle as evidenced by RL network analyses and KEGG pathway activity scoring. To validate our transcriptional findings, ECM turnover was measured in an independent cohort of animals using in vivo isotope tracing of intramuscular collagen and histological scoring of the ECM, which confirmed mechanotherapy-mediated ECM remodeling in aged RE muscle. Our results highlight age-related cellular mechanisms underpinning the impairment to complete recovery from disuse, and also promote mechanotherapy as an intervention to enhance ECM turnover in aged muscle recovering from disuse. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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10. A muscle cell‐macrophage axis involving matrix metalloproteinase 14 facilitates extracellular matrix remodeling with mechanical loading.
- Author
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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
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11. Mechanical overload-induced muscle-derived extracellular vesicles promote adipose tissue lipolysis.
- Author
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Vechetti Jr., Ivan J., Peck, Bailey D., Yuan Wen, Walton, R. Grace, Valentino, Taylor R., Alimov, Alexander P., Dungan, Cory M., Van Pelt, Douglas W., von Walden, Ferdinand, Alkner, Björn, Peterson, Charlotte A., and McCarthy, John J.
- Abstract
How regular physical activity is able to improve health remains poorly understood. The release of factors from skeletal muscle following exercise has been proposed as a possible mechanism mediating such systemic benefits. We describe a mechanism wherein skeletal muscle, in response to a hypertrophic stimulus induced by mechanical overload (MOV), released extracellular vesicles (EVs) containing musclespecific miR-1 that were preferentially taken up by epidydimal white adipose tissue (eWAT). In eWAT, miR-1 promoted adrenergic signaling and lipolysis by targeting Tfap2α, a known repressor of Adrβ3 expression. Inhibiting EV release prevented the MOV-induced increase in eWAT miR-1 abundance and expression of lipolytic genes. Resistance exercise decreased skeletal muscle miR-1 expression with a concomitant increase in plasma EV miR-1 abundance, suggesting a similar mechanism may be operative in humans. Altogether, these findings demonstrate that skeletal muscle promotes metabolic adaptations in adipose tissue in response to MOV via EV-mediated delivery of miR-1. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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12. Muscle transcriptional networks linked to resistance exercise training hypertrophic response heterogeneity.
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Lavin, Kaleen M., Bell, Margaret B., McAdam, Jeremy S., Peck, Bailey D., Walton, R. Grace, Windham, Samuel T., Tuggle, S. Craig, Long, Douglas E., Kern, Philip A., Peterson, Charlotte A., and Bamman, Marcas M.
- Abstract
The skeletal muscle hypertrophic response to resistance exercise training (RT) is highly variable across individuals. The molecular underpinnings of this heterogeneity are unclear. This study investigated transcriptional networks linked to RT-induced muscle hypertrophy, classified as 1) predictive of hypertrophy, 2) responsive to RT independent of muscle hypertrophy, or 3) plastic with hypertrophy. Older adults (n = 31, 18 F/13 M, 70 ± 4 yr) underwent 14-wk RT (3 days/wk, alternating high-low-high intensity). Muscle hypertrophy was assessed by pre- to post-RT change in mid-thigh muscle cross-sectional area (CSA) [computed tomography (CT), primary outcome] and thigh lean mass [dual-energy X-ray absorptiometry (DXA), secondary outcome]. Transcriptome-wide poly-A RNA-seq was performed on vastus lateralis tissue collected pre- (n = 31) and post-RT (n = 22). Prediction networks (using only baseline RNA-seq) were identified by weighted gene correlation network analysis (WGCNA). To identify Plasticity networks, WGCNA change indices for paired samples were calculated and correlated to changes in muscle size outcomes. Pathway-level information extractor (PLIER) was applied to identify Response networks and link genes to biological annotation. Prediction networks (n = 6) confirmed transcripts previously connected to resistance/aerobic training adaptations in the MetaMEx database while revealing novel member genes that should fuel future research to understand the influence of baseline muscle gene expression on hypertrophy. Response networks (n = 6) indicated RT-induced increase in aerobic metabolism and reduced expression of genes associated with spliceosome biology and type-I myofibers. A single exploratory Plasticity network was identified. Findings support that interindividual differences in baseline gene expression may contribute more than RT-induced changes in gene networks to muscle hypertrophic response heterogeneity. Code/Data: https://github.com/kallavin/MASTERS_manuscript/tree/master. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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13. In vivo analysis of γH2AX+ cells in skeletal muscle from aged and obese humans.
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Dungan, Cory M., Peck, Bailey D., Walton, R. Grace, Huang, Zhengyan, Bamman, Marcas M., Kern, Philip A., and Peterson, Charlotte A.
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Over the past 20 years, various identifiers of cellular senescence have been used to quantify the abundance of these cells in different tissues. These include classic markers such as p16, senescence‐associated β‐gal, and γH2AX, in addition to more recent markers (Sudan Black B and HMGB1). In vivo data on the usefulness of these markers in skeletal muscle are very limited and inconsistent. In the present study, we attempted to identify senescent cells in frozen human skeletal muscle biopsies using these markers to determine the effects of age and obesity on senescent cell burden; however, we were only able to assess the abundance of DNA‐damaged nuclei using γH2AX immunohistochemistry. The abundance of γH2AX+ cells, including satellite cells, was not higher in muscle from old compared to young individuals; however, γH2AX+ cells were higher with obesity. Additionally, terminally differentiated, postmitotic myofiber nuclei from obese individuals had elevated γH2AX abundance compared to muscle from lean individuals. Analyses of gene expression support the conclusion that the elevated DNA damage and the senescence‐associated secretory phenotype are preferentially associated with obesity in skeletal muscle. These data implicate obesity as a larger contributor to DNA damage in skeletal muscle than aging; however, more sensitive senescence markers for human skeletal muscle are needed to determine if these cells are in fact senescent. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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14. Resident muscle stem cells are not required for testosterone-induced skeletal muscle hypertrophy.
- Author
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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.
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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
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15. Anterior Cruciate Ligament Tear Promotes Skeletal Muscle Myostatin Expression, Fibrogenic Cell Expansion, and a Decline in Muscle Quality.
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Peck, Bailey D., Brightwell, Camille R., Johnson, Darren L., Ireland, Mary Lloyd, Noehren, Brian, and Fry, Christopher S.
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MUSCULAR atrophy , *FIBROSIS , *CELL proliferation , *ANTERIOR cruciate ligament injuries , *BIOPSY , *STATISTICAL correlation , *EXTRACELLULAR space , *FIBROBLASTS , *GENE expression , *IMMUNOHISTOCHEMISTRY , *RESEARCH methodology , *POLYMERASE chain reaction , *RESEARCH funding , *STAINS & staining (Microscopy) , *STATISTICS , *TRANSFORMING growth factors-beta , *WESTERN immunoblotting , *DATA analysis , *QUADRICEPS muscle , *REVERSE transcriptase polymerase chain reaction , *DATA analysis software , *DESCRIPTIVE statistics , *MYOSTATIN , *NUCLEIC acid amplification techniques , *IN vitro studies , *BLOOD , *DISEASE complications , *DISEASE risk factors - Abstract
Background: Anterior cruciate ligament (ACL) tears result in significant quadriceps muscle atrophy that is resistant to recovery despite extensive rehabilitation. Recent work suggests an elevated fibrotic burden in the quadriceps muscle after the injury, which may limit recovery. Elucidating the mechanisms and cell types involved in the progression of fibrosis is critical for developing new treatment strategies. Purpose: To identify factors contributing to the elevated fibrotic burden found after the injury. Study Design: Descriptive laboratory study. Methods: After an ACL injury, muscle biopsy specimens were obtained from the injured and noninjured vastus lateralis of young adults (n = 14, mean ± SD: 23 ± 4 years). The expression of myostatin, transforming growth factor β, and other regulatory factors was measured, and immunohistochemical analyses were performed to assess turnover of extracellular matrix components. Results: Injured limb skeletal muscle demonstrated elevated myostatin gene (P <.005) and protein (P <.0005) expression, which correlated (R 2 = 0.38, P <.05) with fibroblast cell abundance. Immunohistochemical analysis showed that human fibroblasts express the activin type IIB receptor and that isolated primary human muscle-derived fibroblasts increased proliferation after myostatin treatment in vitro (P <.05). Collagen 1 and fibronectin, primary components of the muscle extracellular matrix, were significantly higher in the injured limb (P <.05). The abundance of procollagen 1–expressing cells as well as a novel index of collagen remodeling was also elevated in the injured limb (P <.05). Conclusion: These findings support a role for myostatin in promoting fibrogenic alterations within skeletal muscle after an ACL injury. Clinical Relevance: The current work shows that the cause of muscle quality decline after ACL injury likely involves elevated myostatin expression, and future studies should explore therapeutic inhibition of myostatin to facilitate improvements in muscle recovery and return to sport. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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16. Metformin to Augment Strength Training Effective Response in Seniors (MASTERS): study protocol for a randomized controlled trial.
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Long, Doug E., Peck, Bailey D., Martz, Jenny L., Tuggle, S. Craig, Bush, Heather M., McGwin, Gerald, Kern, Philip A., Bamman, Marcas M., and Peterson, Charlotte A.
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METFORMIN , *SARCOPENIA , *AGING , *MUSCLE mass , *MUSCLE strength , *RESISTANCE training , *AGE distribution , *GERIATRIC assessment , *COMPARATIVE studies , *CONVALESCENCE , *EXPERIMENTAL design , *RESEARCH methodology , *MEDICAL cooperation , *RESEARCH protocols , *RESEARCH , *RESEARCH funding , *STATISTICAL sampling , *TIME , *EVALUATION research , *RANDOMIZED controlled trials , *TREATMENT effectiveness , *BLIND experiment , *SKELETAL muscle , *DIAGNOSIS , *THERAPEUTICS - Abstract
Background: Muscle mass and strength are strong determinants of a person's quality of life and functional independence with advancing age. While resistance training is the most effective intervention to combat age-associated muscle atrophy (sarcopenia), the ability of older adults to increase muscle mass and strength in response to training is blunted and highly variable. Thus, finding novel ways to complement resistance training to improve muscle response and ultimately quality of life among older individuals is critical. The purpose of this study is to determine whether a commonly prescribed medication called metformin can be repurposed to improve the response to resistance exercise training by altering the muscle tissue inflammatory environment.Methods/design: Individuals aged 65 and older are participating in a two-site, randomized, double-blind, placebo-controlled trial testing the effects of metformin or placebo on muscle size, strength, and physical function when combined with a progressive resistance training program. Participants consume 1700 mg of metformin per day or placebo for 2 weeks before engaging in a 14-week progressive resistance training regimen, with continued metformin or placebo. Participants are then monitored post-training to determine if the group taking metformin derived greater overall benefit from training in terms of muscle mass and strength gains than those on placebo. Muscle biopsies are taken from the vastus lateralis at three time points to assess individual cellular and molecular adaptations to resistance training and also changes in response to metformin.Discussion: The response of aged muscles to a resistance training program does not always result in a positive outcome; some individuals even experience a loss in muscle mass following resistance training. Thus, adjuvant therapies, including pharmacological ones, are required to optimize response to training in those who do not respond and may be at increased risk of frailty. This is the first known metformin repurposing trial in non-diseased individuals, aimed specifically at the resistance exercise "non-responder" phenotype present in the aging population. The overall goal of this trial is to determine if combined exercise-metformin intervention therapy will benefit older individuals by promoting muscle hypertrophy and strength gains, thereby maintaining functional independence.Trial Registration: ClinicalTrials.gov, NCT02308228 . Registered on 25 November 2014. [ABSTRACT FROM AUTHOR]- Published
- 2017
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17. Metformin blunts muscle hypertrophy in response to progressive resistance exercise training in older adults: A randomized, double‐blind, placebo‐controlled, multicenter trial: The MASTERS trial.
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Walton, R. Grace, Dungan, Cory M., Long, Douglas E., Tuggle, S. Craig, Kosmac, Kate, Peck, Bailey D., Bush, Heather M., Villasante Tezanos, Alejandro G., McGwin, Gerald, Windham, Samuel T., Ovalle, Fernando, Bamman, Marcas M., Kern, Philip A., and Peterson, Charlotte A.
- Subjects
MUSCLE growth ,ISOMETRIC exercise ,RESISTANCE training ,OLDER people ,SKELETAL muscle ,METFORMIN ,LEAN body mass - Abstract
Progressive resistance exercise training (PRT) is the most effective known intervention for combating aging skeletal muscle atrophy. However, the hypertrophic response to PRT is variable, and this may be due to muscle inflammation susceptibility. Metformin reduces inflammation, so we hypothesized that metformin would augment the muscle response to PRT in healthy women and men aged 65 and older. In a randomized, double‐blind trial, participants received 1,700 mg/day metformin (N = 46) or placebo (N = 48) throughout the study, and all subjects performed 14 weeks of supervised PRT. Although responses to PRT varied, placebo gained more lean body mass (p = .003) and thigh muscle mass (p < .001) than metformin. CT scan showed that increases in thigh muscle area (p = .005) and density (p = .020) were greater in placebo versus metformin. There was a trend for blunted strength gains in metformin that did not reach statistical significance. Analyses of vastus lateralis muscle biopsies showed that metformin did not affect fiber hypertrophy, or increases in satellite cell or macrophage abundance with PRT. However, placebo had decreased type I fiber percentage while metformin did not (p = .007). Metformin led to an increase in AMPK signaling, and a trend for blunted increases in mTORC1 signaling in response to PRT. These results underscore the benefits of PRT in older adults, but metformin negatively impacts the hypertrophic response to resistance training in healthy older individuals. ClinicalTrials.gov Identifier: NCT02308228. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
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18. Elevated Myostatin Expression Promotes Skeletal Muscle Fibrogenic Cell Expansion Following ACL Injury: 3269 Board #138 June 2 9:30 AM - 11:00 AM.
- Author
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Fry, Christopher S., Peck, Bailey D., Johnson, Darren L., Ireland, Mary L., and Noehren, Brian
- Subjects
- *
CONFERENCES & conventions , *ANTERIOR cruciate ligament injuries , *MYOSTATIN , *BLOOD - Published
- 2018
- Full Text
- View/download PDF
19. Extracellular vesicle transfer of miR-1 to adipose tissue modifies lipolytic pathways following resistance exercise.
- Author
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Burke BI, Ismaeel A, Long DE, Depa LA, Coburn PT, Goh J, Saliu TP, Walton BJ, Vechetti IJ, Peck BD, Valentino TR, Mobley CB, Memetimin H, Wang D, Finlin BS, Kern PA, Peterson CA, McCarthy JJ, and Wen Y
- Abstract
Extracellular vesicles (EVs) have emerged as important mediators of inter-tissue signaling and exercise adaptations. In this human study (n = 32), we provide evidence that muscle-specific microRNA-1 (miR-1) was transferred to adipose tissue via EVs following an acute bout of resistance exercise. Using a multi-model machine learning automation tool, we discovered muscle primary miR-1 transcript and CD63+ EV count in circulation as top explanatory features for changes in adipose miR-1 levels in response to resistance exercise. RNA-sequencing (RNA-seq) and in-silico prediction of miR-1 target genes identified caveolin 2 (CAV2) and tripartite motif containing 6 (TRIM6) as miR-1 target genes downregulated in the adipose tissue of a subset of participants with the highest increases in miR-1 levels following resistance exercise (n = 6). Overexpression of miR-1 in differentiated human adipocyte-derived stem cells downregulated these miR-1 targets and enhanced catecholamine-induced lipolysis. These data identify a potential EV-mediated mechanism by which skeletal muscle communicates to adipose tissue and modulates lipolysis via miR-1.
- Published
- 2024
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20. microRNA-1 Regulates Metabolic Flexibility in Skeletal Muscle via Pyruvate Metabolism.
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Ismaeel A, Peck BD, Montgomery MM, Burke BI, Goh J, Kang G, Franco AB, Xia Q, Goljanek-Whysall K, McDonagh B, McLendon JM, Koopmans PJ, Jacko D, Schaaf K, Bloch W, Gehlert S, Wen Y, Murach KA, Peterson CA, Boudreau RL, Fisher-Wellman KH, and McCarthy JJ
- Abstract
MicroRNA-1 (miR-1) is the most abundant miRNA in adult skeletal muscle. To determine the function of miR-1 in adult skeletal muscle, we generated an inducible, skeletal muscle-specific miR-1 knockout (KO) mouse. Integration of RNA-sequencing (RNA-seq) data from miR-1 KO muscle with Argonaute 2 enhanced crosslinking and immunoprecipitation sequencing (AGO2 eCLIP-seq) from human skeletal muscle identified miR-1 target genes involved with glycolysis and pyruvate metabolism. The loss of miR-1 in skeletal muscle induced cancer-like metabolic reprogramming, as shown by higher pyruvate kinase muscle isozyme M2 (PKM2) protein levels, which promoted glycolysis. Comprehensive bioenergetic and metabolic phenotyping combined with skeletal muscle proteomics and metabolomics further demonstrated that miR-1 KO induced metabolic inflexibility as a result of pyruvate oxidation resistance. While the genetic loss of miR-1 reduced endurance exercise performance in mice and in C. elegans, the physiological down-regulation of miR-1 expression in response to a hypertrophic stimulus in both humans and mice causes a similar metabolic reprogramming that supports muscle cell growth. Taken together, these data identify a novel post-translational mechanism of adult skeletal muscle metabolism regulation mediated by miR-1.
- Published
- 2024
- Full Text
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21. Satellite Cell Depletion Disrupts Transcriptional Coordination and Muscle Adaptation to Exercise.
- Author
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Englund DA, Figueiredo VC, Dungan CM, Murach KA, Peck BD, Petrosino JM, Brightwell CR, Dupont AM, Neal AC, Fry CS, Accornero F, McCarthy JJ, and Peterson CA
- Subjects
- Mice, Animals, Motor Activity, Muscle, Skeletal, Hypertrophy, Tamoxifen, Physical Conditioning, Animal, Satellite Cells, Skeletal Muscle
- Abstract
Satellite cells are required for postnatal development, skeletal muscle regeneration across the lifespan, and skeletal muscle hypertrophy prior to maturity. Our group has aimed to address whether satellite cells are required for hypertrophic growth in mature skeletal muscle. Here, we generated a comprehensive characterization and transcriptome-wide profiling of skeletal muscle during adaptation to exercise in the presence or absence of satellite cells in order to identify distinct phenotypes and gene networks influenced by satellite cell content. We administered vehicle or tamoxifen to adult Pax7-DTA mice and subjected them to progressive weighted wheel running (PoWeR). We then performed immunohistochemical analysis and whole-muscle RNA-seq of vehicle (SC+) and tamoxifen-treated (SC-) mice. Further, we performed single myonuclear RNA-seq to provide detailed information on how satellite cell fusion affects myonuclear transcription. We show that while skeletal muscle can mount a robust hypertrophic response to PoWeR in the absence of satellite cells, growth, and adaptation are ultimately blunted. Transcriptional profiling reveals several gene networks key to muscle adaptation are altered in the absence of satellite cells., (© The Author(s) 2020. Published by Oxford University Press on behalf of American Physiological Society.)
- Published
- 2020
- Full Text
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22. Metformin alters skeletal muscle transcriptome adaptations to resistance training in older adults.
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Kulkarni AS, Peck BD, Walton RG, Kern PA, Mar JC, Windham ST, Bamman MM, Barzilai N, and Peterson CA
- Subjects
- Adaptation, Physiological, Aged, Alabama, Double-Blind Method, Female, Gene Expression Profiling, Gene Expression Regulation, Gene Regulatory Networks, Humans, Kentucky, Male, Quadriceps Muscle growth & development, Quadriceps Muscle metabolism, Time Factors, Treatment Outcome, Hypoglycemic Agents therapeutic use, Metformin therapeutic use, Quadriceps Muscle drug effects, Resistance Training, Skeletal Muscle Enlargement drug effects, Transcriptome drug effects
- Abstract
Evidence from clinical trials and observational studies suggests that both progressive resistance exercise training (PRT) and metformin delay a variety of age-related morbidities. Previously, we completed a clinical trial testing the effects of 14 weeks of PRT + metformin (metPRT) compared to PRT with placebo (plaPRT) on muscle hypertrophy in older adults. We found that metformin blunted PRT-induced muscle hypertrophic response. To understand potential mechanisms underlying the inhibitory effect of metformin on PRT, we analyzed the muscle transcriptome in 23 metPRT and 24 plaPRT participants. PRT significantly increased expression of genes involved in extracellular matrix remodeling pathways, and downregulated RNA processing pathways in both groups, however, metformin attenuated the number of differentially expressed genes within these pathways compared to plaPRT. Pathway analysis showed that genes unique to metPRT modulated aging-relevant pathways, such as cellular senescence and autophagy. Differentially expressed genes from baseline biopsies in older adults compared to resting muscle from young volunteers were reduced following PRT in plaPRT and were further reduced in metPRT. We suggest that although metformin may blunt pathways induced by PRT to promote muscle hypertrophy, adjunctive metformin during PRT may have beneficial effects on aging-associated pathways in muscle from older adults.
- Published
- 2020
- Full Text
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23. Immunohistochemical Identification of Human Skeletal Muscle Macrophages.
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Kosmac K, Peck BD, Walton RG, Mula J, Kern PA, Bamman MM, Dennis RA, Jacobs CA, Lattermann C, Johnson DL, and Peterson CA
- Abstract
Macrophages have well-characterized roles in skeletal muscle repair and regeneration. Relatively little is known regarding the role of resident macrophages in skeletal muscle homeostasis, extracellular matrix remodeling, growth, metabolism and adaptation to various stimuli including exercise and training. Despite speculation into macrophage contributions during these processes, studies characterizing macrophages in non-injured muscle are limited and methods used to identify macrophages vary. A standardized method for the identification of human resident skeletal muscle macrophages will aide in the characterization of these immune cells and allow for the comparison of results across studies. Here, we present an immunohistochemistry (IHC) protocol, validated by flow cytometry, to distinctly identify resident human skeletal muscle macrophage populations. We show that CD11b and CD206 double IHC effectively identifies macrophages in human skeletal muscle. Furthermore, the majority of macrophages in non-injured human skeletal muscle show a 'mixed' M1/M2 phenotype, expressing CD11b, CD14, CD68, CD86 and CD206. A relatively small population of CD11b+/CD206- macrophages are present in resting skeletal muscle. Changes in the relative abundance of this population may reflect important changes in the skeletal muscle environment. CD11b and CD206 IHC in muscle also reveals distinct morphological features of macrophages that may be related to the functional status of these cells.
- Published
- 2018
- Full Text
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