Dietary protein, exercise, ageing and physical inactivity: interactive influences on skeletal muscle proteostasis
Dietary protein, exercise, ageing and physical inactivity: interactive influences on skeletal muscle proteostasis
Dietary protein is a pre-requisite for the maintenance of skeletal muscle mass; stimulating increases in muscle protein synthesis (MPS), via essential amino acids (EAA), and attenuating muscle protein breakdown, via insulin. Muscles are receptive to the anabolic effects of dietary protein, and in particular the EAA leucine, for only a short period (i.e. about 2-3 h) in the rested state. Thereafter, MPS exhibits tachyphylaxis despite continued EAA availability and sustained mechanistic target of rapamycin complex 1 signalling. Other notable characteristics of this 'muscle full' phenomenon include: (i) it cannot be overcome by proximal intake of additional nutrient signals/substrates regulating MPS; meaning a refractory period exists before a next stimulation is possible, (ii) it is refractory to pharmacological/nutraceutical enhancement of muscle blood flow and thus is not induced by muscle hypo-perfusion, (iii) it manifests independently of whether protein intake occurs in a bolus or intermittent feeding pattern, and (iv) it does not appear to be dependent on protein dose per se. Instead, the main factor associated with altering muscle full is physical activity. For instance, when coupled to protein intake, resistance exercise delays the muscle full set-point to permit additional use of available EAA for MPS to promote muscle remodelling/growth. In contrast, ageing is associated with blunted MPS responses to protein/exercise (anabolic resistance), while physical inactivity (e.g. immobilisation) induces a premature muscle full, promoting muscle atrophy. It is crucial that in catabolic scenarios, anabolic strategies are sought to mitigate muscle decline. This review highlights regulatory protein turnover interactions by dietary protein, exercise, ageing and physical inactivity.
106-117
Deane, Colleen S.
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Ely, Isabel A.
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Wilkinson, Daniel J.
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Smith, Kenneth
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Phillips, Bethan E.
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Atherton, Philip J.
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Deane, Colleen S.
3320532e-f411-4ea8-9a14-4a9f248da898
Ely, Isabel A.
6d1fec1b-3434-4615-a87a-e882950b81f8
Wilkinson, Daniel J.
cb26017f-51b6-4ba0-a309-079aa4721de8
Smith, Kenneth
03b7a22d-0932-40e3-ae2f-88e083d8335d
Phillips, Bethan E.
dbd3c967-7c0a-46c0-9b1d-2cbcda9c8c97
Atherton, Philip J.
7862070e-c551-46c4-be02-cd9fb4344a5e
Deane, Colleen S., Ely, Isabel A., Wilkinson, Daniel J., Smith, Kenneth, Phillips, Bethan E. and Atherton, Philip J.
(2020)
Dietary protein, exercise, ageing and physical inactivity: interactive influences on skeletal muscle proteostasis.
The Proceedings of the Nutrition Society, 80, .
(doi:10.1017/s0029665120007879).
Abstract
Dietary protein is a pre-requisite for the maintenance of skeletal muscle mass; stimulating increases in muscle protein synthesis (MPS), via essential amino acids (EAA), and attenuating muscle protein breakdown, via insulin. Muscles are receptive to the anabolic effects of dietary protein, and in particular the EAA leucine, for only a short period (i.e. about 2-3 h) in the rested state. Thereafter, MPS exhibits tachyphylaxis despite continued EAA availability and sustained mechanistic target of rapamycin complex 1 signalling. Other notable characteristics of this 'muscle full' phenomenon include: (i) it cannot be overcome by proximal intake of additional nutrient signals/substrates regulating MPS; meaning a refractory period exists before a next stimulation is possible, (ii) it is refractory to pharmacological/nutraceutical enhancement of muscle blood flow and thus is not induced by muscle hypo-perfusion, (iii) it manifests independently of whether protein intake occurs in a bolus or intermittent feeding pattern, and (iv) it does not appear to be dependent on protein dose per se. Instead, the main factor associated with altering muscle full is physical activity. For instance, when coupled to protein intake, resistance exercise delays the muscle full set-point to permit additional use of available EAA for MPS to promote muscle remodelling/growth. In contrast, ageing is associated with blunted MPS responses to protein/exercise (anabolic resistance), while physical inactivity (e.g. immobilisation) induces a premature muscle full, promoting muscle atrophy. It is crucial that in catabolic scenarios, anabolic strategies are sought to mitigate muscle decline. This review highlights regulatory protein turnover interactions by dietary protein, exercise, ageing and physical inactivity.
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dietary-protein-exercise-ageing-and-physical-inactivity-interactive-influences-on-skeletal-muscle-proteostasis
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e-pub ahead of print date: 7 October 2020
Venue - Dates:
Nutrition Society Live 2020, Virtual, 2020-07-14 - 2020-07-15
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Local EPrints ID: 483351
URI: http://eprints.soton.ac.uk/id/eprint/483351
PURE UUID: 1ee6ee4a-7854-49e6-9dc2-da6d43b6ad65
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Date deposited: 30 Oct 2023 07:58
Last modified: 17 Mar 2024 04:15
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Author:
Colleen S. Deane
Author:
Isabel A. Ely
Author:
Daniel J. Wilkinson
Author:
Kenneth Smith
Author:
Bethan E. Phillips
Author:
Philip J. Atherton
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