Anabolic signaling and response in sarcopenia as a model for microgravity induced muscle deconditioning: A systematic review

Q1 Physics and Astronomy

REACH Pub Date : 2019-03-01 DOI:10.1016/j.reach.2019.100025

L.C. Rundfeldt, H.C. Gunga, M. Steinach

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引用次数: 3

Abstract

Purpose

Muscle mass, sustained through buildup exceeding constant parallel breakdown, is mainly regulated through amino acid availability and mechanic stimulation and conveyed through the key mediator mTORC1. Sarcopenia, as age- and immobilization related loss of muscle mass, strength and function, may serve as an analog to muscle deconditioning in space travel. Optimal countermeasures to muscle deconditioning syndromes may be impacted by impaired anabolic response. This review assesses the pathophysiological contribution of anabolic resistance to muscle deconditioning, and its influence on adequate interventions applied in aging and immobilization as an analog for detrimental effects of space travel.

Methods

A systematic search of the MEDLINE database identified relevant publications. Selection criteria included clinical trials assessing markers of anabolic resistance in aged or disused muscle, as well as modulation of synthetic activity through adequate interventions.

Results

Increased protein intake and resistance training, especially combined, show the greatest potential for counteracting sarcopenia as an analog for microgravity-induced muscle deconditioning. However, elderly display partly attenuated responses to anabolic stimulation, which is reflected in decreased synthetic activity and muscle mass gain or absence of beneficial effects at all. Amongst other targets and dysregulations in anabolic signaling, there is an emerging role of REDD1 as a downstream inhibitor of mTORC1.

Conclusion

Findings on anabolic resistance and underlying effectors, such as REDD1, are partly controversial regarding its exclusively inhibitory role. Further detailed investigation on the exact mechanisms, the extent of occurrence, and subsequent impact of anabolic resistance on therapeutic approaches in analogs for microgravity-induced muscle deconditioning is needed.

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合成代谢信号和反应在肌肉减少症中作为微重力诱导肌肉调节的模型:系统综述

肌肉质量主要通过氨基酸可用性和机械刺激来调节，并通过关键介质mTORC1传递。肌肉减少症，作为与年龄和固定相关的肌肉质量、力量和功能的损失，可以作为太空旅行中肌肉失调的类比。肌肉调节综合征的最佳对策可能受到合成代谢反应受损的影响。这篇综述评估了合成代谢抵抗对肌肉调节的病理生理贡献，以及它对在衰老和固定中应用的适当干预的影响，作为太空旅行有害影响的模拟物。方法系统检索MEDLINE数据库，确定相关文献。选择标准包括评估老年或废肌合成代谢抵抗标志物的临床试验，以及通过适当干预调节合成活性。结果:增加蛋白质摄入和阻力训练，特别是结合起来，显示出最大的潜力来抵消肌肉减少症，作为微重力诱导的肌肉去调节的模拟物。然而，老年人对合成代谢刺激的反应部分减弱，这反映在合成活动和肌肉质量增加的减少或根本没有有益的影响。在合成代谢信号的其他靶点和失调中，REDD1作为mTORC1的下游抑制剂的作用正在出现。结论关于合成代谢抵抗及其潜在效应物(如REDD1)的发现在一定程度上存在争议，因为其仅具有抑制作用。需要进一步详细研究合成代谢抵抗的确切机制、发生程度以及随后对微重力诱导肌肉去调节类似物治疗方法的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

REACH Engineering-Aerospace Engineering

CiteScore

2.00

自引率

0.00%

发文量

期刊介绍： The Official Human Space Exploration Review Journal of the International Academy of Astronautics (IAA) and the International Astronautical Federation (IAF) REACH – Reviews in Human Space Exploration is an international review journal that covers the entire field of human space exploration, including: -Human Space Exploration Mission Scenarios -Robotic Space Exploration Missions (Preparing or Supporting Human Missions) -Commercial Human Spaceflight -Space Habitation and Environmental Health -Space Physiology, Psychology, Medicine and Environmental Health -Space Radiation and Radiation Biology -Exo- and Astrobiology -Search for Extraterrestrial Intelligence (SETI) -Spin-off Applications from Human Spaceflight -Benefits from Space-Based Research for Health on Earth -Earth Observation for Agriculture, Climate Monitoring, Disaster Mitigation -Terrestrial Applications of Space Life Sciences Developments -Extreme Environments REACH aims to meet the needs of readers from academia, industry, and government by publishing comprehensive overviews of the science of human and robotic space exploration, life sciences research in space, and beneficial terrestrial applications that are derived from spaceflight. Special emphasis will be put on summarizing the most important recent developments and challenges in each of the covered fields, and on making published articles legible for a non-specialist audience. Authors can also submit non-solicited review articles. Please note that original research articles are not published in REACH. The Journal plans to publish four issues per year containing six to eight review articles each.