5 results on '"Englund, Davis A."'
Search Results
2. The Second Annual Symposium of the Midwest Aging Consortium: The Future of Aging Research in the Midwestern United States.
- Author
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Green, Cara L, Englund, Davis A, Das, Srijit, Herrerias, Mariana M, Yousefzadeh, Matthew J, Grant, Rogan A, Clark, Josef, Pak, Heidi H, Liu, Peiduo, Bai, Hua, Prahlad, Veena, Lamming, Dudley W, and Chusyd, Daniella E
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LOW-calorie diet , *RHESUS monkeys , *AGING , *CAENORHABDITIS elegans , *LABORATORY animals - Abstract
While the average human life span continues to increase, there is little evidence that this is leading to a contemporaneous increase in "healthy years" experienced by our aging population. Consequently, many scientists focus their research on understanding the process of aging and trialing interventions that can promote healthspan. The 2021 Midwest Aging Consortium consensus statement is to develop and further the understanding of aging and age-related disease using the wealth of expertise across universities in the Midwestern United States. This report summarizes the cutting-edge research covered in a virtual symposium held by a consortium of researchers in the Midwestern United States, spanning topics such as senescence biomarkers, serotonin-induced DNA protection, immune system development, multisystem impacts of aging, neural decline following severe infection, the unique transcriptional impact of calorie restriction of different fat depots, the pivotal role of fasting in calorie restriction, the impact of peroxisome dysfunction, and the influence of early life trauma on health. The symposium speakers presented data from studies conducted in a variety of common laboratory animals as well as less-common species, including Caenorhabditis elegans, Drosophila, mice, rhesus macaques, elephants, and humans. The consensus of the symposium speakers is that this consortium highlights the strength of aging research in the Midwestern United States as well as the benefits of a collaborative and diverse approach to geroscience. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
3. Exercise reduces circulating biomarkers of cellular senescence in humans.
- Author
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Englund, Davis A., Sakamoto, Ayumi E., Fritsche, Chad M., Heeren, Amanda A., Zhang, Xu, Kotajarvi, Brian R., Lecy, Denise R., Yousefzadeh, Matthew J., Schafer, Marissa J., White, Thomas A., Atkinson, Elizabeth J., and LeBrasseur, Nathan K.
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OLDER people , *REDUCING exercises , *AGE , *BIOMARKERS , *PHYSICAL mobility , *CELLULAR aging , *PROTEIN expression - Abstract
Cellular senescence has emerged as a significant and potentially tractable mechanism of aging and multiple aging‐related conditions. Biomarkers of senescent cell burden, including molecular signals in circulating immune cells and the abundance of circulating senescence‐related proteins, have been associated with chronological age and clinical parameters of biological age in humans. The extent to which senescence biomarkers are affected by interventions that enhance health and function has not yet been examined. Here, we report that a 12‐week structured exercise program drives significant improvements in several performance‐based and self‐reported measures of physical function in older adults. Impressively, the expression of key markers of the senescence program, including p16,p21, cGAS, and TNFα, were significantly lowered in CD3+ T cells in response to the intervention, as were the circulating concentrations of multiple senescence‐related proteins. Moreover, partial least squares discriminant analysis showed levels of senescence‐related proteins at baseline were predictive of changes in physical function in response to the exercise intervention. Our study provides first‐in‐human evidence that biomarkers of senescent cell burden are significantly lowered by a structured exercise program and predictive of the adaptive response to exercise. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
4. 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
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5. p21 induces a senescence program and skeletal muscle dysfunction.
- Author
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Englund, Davis A., Jolliffe, Alyssa, Aversa, Zaira, Zhang, Xu, Sturmlechner, Ines, Sakamoto, Ayumi E., Zeidler, Julianna D., Warner, Gina M., McNinch, Colton, White, Thomas A., Chini, Eduardo N., Baker, Darren J., van Deursen, Jan M., and LeBrasseur, Nathan K.
- Abstract
Recent work has established associations between elevated p21, the accumulation of senescent cells, and skeletal muscle dysfunction in mice and humans. Using a mouse model of p21 overexpression (p21OE), we examined if p21 mechanistically contributes to cellular senescence and pathological features in skeletal muscle. We show that p21 induces several core properties of cellular senescence in skeletal muscle, including an altered transcriptome, DNA damage, mitochondrial dysfunction, and the senescence-associated secretory phenotype (SASP). Furthermore, p21OE mice exhibit manifestations of skeletal muscle pathology, such as atrophy, fibrosis, and impaired physical function when compared to age-matched controls. These findings suggest p21 alone is sufficient to drive a cellular senescence program and reveal a novel source of skeletal muscle loss and dysfunction. • p21 induces a transcriptional program in skeletal muscle consistent with a senescence program. • p21 induces core properties of senescence in skeletal muscle, including DNA damage, mitochondrial dysfunction, and the SASP. • Mice that overexpress p21 exhibit signs of muscle pathology, such as atrophy, fibrosis, and impaired physical function. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
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