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Your search keyword '"Bello, Fiona M"' showing total 6 results
Start Over Author "Bello, Fiona M" Publication Type Academic Journals
6 results on '"Bello, Fiona M"'

3. Role of Cardiorespiratory Fitness and Mitochondrial Oxidative Capacity in Reduced Walk Speed of Older Adults With Diabetes.

Author

Ramos, Sofhia V., Distefano, Giovanna, Lui, Li-Yung, Cawthon, Peggy M., Kramer, Philip, Sipula, Ian J., Bello, Fiona M., Mau, Theresa, Jurczak, Michael J., Molina, Anthony J., Kershaw, Erin E., Marcinek, David J., Shankland, Eric, Toledo, Frederico G.S., Newman, Anne B., Hepple, Russell T., Kritchevsky, Stephen B., Goodpaster, Bret H., Cummings, Steven R., and Coen, Paul M.

Subjects
WALKING speed, CARDIOPULMONARY fitness, OLDER people, FITNESS walking, DIABETES
Abstract

Cardiorespiratory fitness and mitochondrial oxidative capacity are associated with reduced walking speed in older adults, but their impact on walking speed in older adults with diabetes has not been clearly defined. We examined differences in cardiorespiratory fitness and skeletal muscle mitochondrial oxidative capacity between older adults with and without diabetes, as well as determined their relative contribution to slower walking speed in older adults with diabetes. Participants with diabetes (n = 159) had lower cardiorespiratory fitness and mitochondrial respiration in permeabilized fiber bundles compared with those without diabetes (n = 717), following adjustments for covariates including BMI, chronic comorbid health conditions, and physical activity. Four-meter and 400-m walking speeds were slower in those with diabetes. Mitochondrial oxidative capacity alone or combined with cardiorespiratory fitness mediated ∼20–70% of the difference in walking speed between older adults with and without diabetes. Additional adjustments for BMI and comorbidities further explained the group differences in walking speed. Cardiorespiratory fitness and skeletal muscle mitochondrial oxidative capacity contribute to slower walking speeds in older adults with diabetes. Article Highlights: The contributors to slower walking speed in older adults with diabetes remain unclear. This study was conducted to answer the question of how mitochondrial oxidative capacity and cardiorespiratory fitness impact walking speed in older adults with diabetes. We found that mitochondrial oxidative capacity, cardiorespiratory fitness, and walking speed were lower in older adults with diabetes compared with those without diabetes. In addition, mitochondrial oxidative capacity and cardiorespiratory fitness contributed to slower walking speed in those with diabetes. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Intact mitochondrial function in the setting of telomere‐induced senescence.

Author

Sullivan, Daniel I., Bello, Fiona M., Silva, Agustin Gil, Redding, Kevin M., Giordano, Luca, Hinchie, Angela M., Loughridge, Kelly E., Mora, Ana L., Königshoff, Melanie, Kaufman, Brett A., Jurczak, Michael J., and Alder, Jonathan K.

Subjects
*CELLULAR aging, *DNA repair, *CELL physiology, *MITOCHONDRIA, *SET functions, *HUMAN abnormalities
Abstract

Mitochondria play essential roles in metabolic support and signaling within all cells. Congenital and acquired defects in mitochondria are responsible for several pathologies, including premature entrance to cellar senescence. Conversely, we examined the consequences of dysfunctional telomere‐driven cellular senescence on mitochondrial biogenesis and function. We drove senescence in vitro and in vivo by deleting the telomere‐binding protein TRF2 in fibroblasts and hepatocytes, respectively. Deletion of TRF2 led to a robust DNA damage response, global changes in transcription, and induction of cellular senescence. In vitro, senescent cells had significant increases in mitochondrial respiratory capacity driven by increased cellular and mitochondrial volume. Hepatocytes with dysfunctional telomeres maintained their mitochondrial respiratory capacity in vivo, whether measured in intact cells or purified mitochondria. Induction of senescence led to the upregulation of overlapping and distinct genes in fibroblasts and hepatocytes, but transcripts related to mitochondria were preserved. Our results support that mitochondrial function and activity are preserved in telomere dysfunction‐induced senescence, which may facilitate continued cellular functions. [ABSTRACT FROM AUTHOR]

Published
2023
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5. Mitochondrial energetics in skeletal muscle are associated with leg power and cardiorespiratory fitness in the Study of Muscle, Mobility, and Aging (SOMMA).

Author

Mau, Theresa, Lui, Li-Yung, Distefano, Giovanna, Kramer, Philip A, Ramos, Sofhia V, Toledo, Frederico G S, Santanasto, Adam J, Shankland, Eric G, Marcinek, David J, Jurczak, Michael J, Sipula, Ian, Bello, Fiona M, Duchowny, Kate A, Molina, Anthony J A, Sparks, Lauren M, Goodpaster, Bret H, Hepple, Russell T, Kritchevsky, Stephen B, Newman, Anne B, and Cawthon, Peggy M

Subjects
CARDIOPULMONARY fitness, SKELETAL muscle, NUCLEAR magnetic resonance spectroscopy, EXERCISE tests, MITOCHONDRIA
Abstract

Background: Mitochondrial energetics are an important property of aging muscle, as generation of energy is pivotal to the execution of muscle contraction. However, its association with functional outcomes, including leg power and cardiorespiratory fitness is largely understudied.Methods: In the Study of Muscle, Mobility, and Aging (SOMMA), we collected vastus lateralis biopsies from older adults (n=879,70-94 years,59.2% women). Maximal state 3 respiration (Max OXPHOS) was assessed in permeabilized fiber bundles by high-resolution respirometry. Capacity for maximal adenosine triphosphate production (ATPmax) was measured in vivo by 31P magnetic resonance spectroscopy. Leg extension power was measured with a Keiser press system, and VO2 peak was determined using a standardized cardiopulmonary exercise test. Gender-stratified multivariate linear regression models were adjusted for age, race, technician/site, adiposity, and physical activity with beta-coefficients expressed per 1 SD increment in the independent variable.Results: Max OXPHOS was associated with leg power for both women (β=0.12Watts/kg,p<0.001) and men (β=0.11Watts/kg,p<0.050). ATPmax was associated with leg power for men (β=0.09Watts/kg p<0.05) but was not significant for women (β=0.03Watts/kg,p=0.11). Max OXPHOS and ATPmax were associated with VO2 peak in women and men (Max OXPHOS, βwomen=1.03mL/kg/min, βmen=1.32 mL/kg/min; ATPmax βwomen=0.87mL/kg/min, βmen=1.50mL/kg/min;all p<0.001).Conclusions: Higher muscle mitochondrial energetics measures were associated with both better cardiorespiratory fitness and greater leg power in older adults. Muscle mitochondrial energetics explained a greater degree of variance in VO2 peak compared to leg power. [ABSTRACT FROM AUTHOR]

Published
2023
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6. Role of Cardiorespiratory Fitness and Mitochondrial Energetics in Reduced Walk Speed of Older Adults with Diabetes in the Study of Muscle, Mobility and Aging (SOMMA).

Author

Ramos SV, Distefano G, Lui LY, Cawthon PM, Kramer P, Sipula IJ, Bello FM, Mau T, Jurczak MJ, Molina AJ, Kershaw EE, Marcinek DJ, Toledo FGS, Newman AB, Hepple RT, Kritchevsky SB, Goodpaster BH, Cummings SR, and Coen PM

Abstract

Rationale: Cardiorespiratory fitness and mitochondrial energetics are associated with reduced walking speed in older adults. The impact of cardiorespiratory fitness and mitochondrial energetics on walking speed in older adults with diabetes has not been clearly defined., Objective: To examine differences in cardiorespiratory fitness and skeletal muscle mitochondrial energetics between older adults with and without diabetes. We also assessed the contribution of cardiorespiratory fitness and skeletal muscle mitochondrial energetics to slower walking speed in older adults with diabetes., Findings: Participants with diabetes had lower cardiorespiratory fitness and mitochondrial energetics when compared to those without diabetes, following adjustments for covariates including BMI, chronic comorbid health conditions, and physical activity. 4-m and 400-m walking speeds were slower in those with diabetes. Mitochondrial oxidative capacity alone or combined with cardiorespiratory fitness mediated ∼20-70% of the difference in walk speed between older adults with and without diabetes. Further adjustments of BMI and co-morbidities further explained the group differences in walk speed., Conclusions: Skeletal muscle mitochondrial energetics and cardiorespiratory fitness contribute to slower walking speeds in older adults with diabetes. Cardiorespiratory fitness and mitochondrial energetics may be therapeutic targets to maintain or improve mobility in older adults with diabetes., Article Highlights: Why did we undertake this study? To determine if mitochondrial energetics and cardiorespiratory fitness contribute to slower walking speed in older adults with diabetes. What is the specific question(s) we wanted to answer? Are mitochondrial energetics and cardiorespiratory fitness in older adults with diabetes lower than those without diabetes? How does mitochondrial energetics and cardiorespiratory fitness impact walking speed in older adults with diabetes? What did we find? Mitochondrial energetics and cardiorespiratory fitness were lower in older adults with diabetes compared to those without diabetes, and energetics, and cardiorespiratory fitness, contributed to slower walking speed in those with diabetes. What are the implications of our findings? Cardiorespiratory fitness and mitochondrial energetics may be key therapeutic targets to maintain or improve mobility in older adults with diabetes.

Published
2023
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