The influence of physical exercise and sports on telomere length A model for telomere length and telomerase activity regulation based on a comparative assessment of literature

International Educational Scientific Research Journal Pub Date : 2016-04-19 DOI:10.7287/PEERJ.PREPRINTS.1965V1

Paul F. Lang, K. Fröhlich

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引用次数: 3

Abstract

Based upon a comprehensive analysis of current literature and by combining a molecular biology and a sports science perspective, this review examines (1) if a correlation between physical activity load and telomere length (TL) exists, and (2) comprehensively analyses and integrates molecular pathways regulating exercise dependent TL dynamics. The focus is on TL in leukocytes and muscle tissue in middle to advanced aged subjects. Regarding item (1), a strong tendency for an increase in mean leukocyte TL was found for exercise energy expenditures up to about 2∙103 kcal/week, while for higher activity levels no conclusive statement can be made. Conversely, research on skeletal muscle TL so far is quite limited but suggests that physical exercise with prolonged eccentric muscle contractions rather acts to shorten telomeres, while sports with little eccentric contractions might rather act to lengthen telomeres. As to item (2), a model for hypothetical pathways for exercise dependent telomerase activity regulation is proposed by consolidating findings of different studies in different cells. Consistent with this pathway model, various studies report increased telomerase transcription or activation by exercise. Moreover, a qualitative overall model for endurance exercise related TL dynamics is presented. It considers telomeres as dynamic structures in equilibrium between telomere shortening (e.g., cellular turnover, oxidative stress, inflammation) and telomere lengthening (e.g., telomerase activity, telomerase recruitment) effects. A negative feedback-loop mediated by enhanced telomerase recruitment to short telomeres is assumed to counteract too excessive TL alterations. Finally, a proposal is put forth for future research on exercise dependent telomere dynamics by adopting a systems biology approach to develop mathematical models that properly integrate the complexity of the interacting variables.

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体育锻炼和运动对端粒长度的影响基于文献比较评估的端粒长度和端粒酶活性调节模型

在综合分析现有文献的基础上，结合分子生物学和运动科学的观点，本文将探讨(1)体力活动负荷与端粒长度(TL)之间是否存在相关性;(2)全面分析和整合调节运动依赖的端粒长度动态的分子途径。重点是在白细胞和肌肉组织在中老年受试者的TL。关于第(1)项，当运动能量消耗达到约2∙103 kcal/week时，发现平均白细胞TL有强烈的增加趋势，而对于更高的活动水平，则没有结论性的说法。相反，迄今为止对骨骼肌TL的研究相当有限，但表明长期偏心肌收缩的体育锻炼反而会缩短端粒，而偏心肌收缩较小的体育运动可能反而会延长端粒。对于(2)项，通过整合不同细胞的不同研究结果，提出了运动依赖端粒酶活性调节的假设途径模型。与这一途径模型一致，各种研究报告了端粒酶的转录或激活通过运动增加。此外，本文还提出了耐力运动相关的定性整体模型。它认为端粒是端粒缩短(如细胞更新、氧化应激、炎症)和端粒延长(如端粒酶活性、端粒酶募集)效应之间平衡的动态结构。一个由端粒酶向短端粒募集增强介导的负反馈环被认为可以抵消过多的TL改变。最后，对运动依赖端粒动力学的未来研究提出了建议，即采用系统生物学方法建立适当整合相互作用变量复杂性的数学模型。

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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International Educational Scientific Research Journal

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