Understanding seasonal telomere length dynamics in hibernating species

IF 2.9 2区生物学 Q2 BIOLOGY

Journal of thermal biology Pub Date : 2024-07-01 DOI:10.1016/j.jtherbio.2024.103913

Lilian Redon , Théo Constant , Steve Smith , Caroline Habold , Sylvain Giroud

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引用次数: 0

Abstract

Oxidative stress is thought to be one of the main causes of ageing as it progressively damages cell components throughout life, eventually causing cellular failure and apoptosis. In many organisms, telomeres shorten throughout life under the effect of, amongst other factors, oxidative stress, and are therefore commonly used as marker of biological ageing. However, hibernators, which are regularly exposed to acute oxidative stress when rewarming from torpor, are unexpectedly long-lived. In this review, we explore the causes of oxidative stress associated with hibernation and its impact on telomere dynamics in different taxa, focussing on hibernating rodents. We then speculate on the adaptive mechanisms of hibernators to compensate for the effects of oxidative stress, which may explain their increased longevity. Because winter hibernation appears to be associated with high oxidative stress, hibernators, particularly rodents, may periodically invest in repair mechanisms and antioxidant defences, resulting in seasonal variations in telomere lengths. This research shows how species with a slow life-history strategy deal with large changes in oxidative stress, unifying evolutionary and physiological theories of ageing. Because of the marked seasonal variation in telomere length, we also draw attention when using telomeres as markers for biological aging in seasonal heterotherms and possibly in other highly seasonal species.

查看原文本刊更多论文

了解冬眠物种的季节性端粒长度动态。

氧化应激被认为是老化的主要原因之一，因为它在整个生命过程中会逐渐破坏细胞成分，最终导致细胞衰竭和凋亡。在许多生物体中，端粒在氧化应激等因素的作用下终生缩短，因此通常被用作生物老化的标志。然而，冬眠者在从冬眠状态回暖时经常暴露于急性氧化应激，却意外地长寿。在这篇综述中，我们以冬眠啮齿动物为重点，探讨了与冬眠相关的氧化应激的原因及其对不同类群端粒动态的影响。然后，我们推测冬眠动物补偿氧化应激影响的适应机制，这可能是它们寿命延长的原因。由于冬季冬眠似乎与高氧化应激有关，冬眠者，尤其是啮齿类动物，可能会定期投资于修复机制和抗氧化防御，从而导致端粒长度的季节性变化。这项研究展示了具有缓慢生活史策略的物种如何应对氧化应激的巨大变化，从而将老化的进化理论和生理学理论统一起来。由于端粒长度存在明显的季节性变化，我们还提请人们注意将端粒作为季节性异温动物以及其他季节性很强的物种生物衰老的标志物。

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

Journal of thermal biology 生物-动物学

CiteScore

5.30

自引率

7.40%

发文量

196

审稿时长

14.5 weeks

期刊介绍： The Journal of Thermal Biology publishes articles that advance our knowledge on the ways and mechanisms through which temperature affects man and animals. This includes studies of their responses to these effects and on the ecological consequences. Directly relevant to this theme are: • The mechanisms of thermal limitation, heat and cold injury, and the resistance of organisms to extremes of temperature • The mechanisms involved in acclimation, acclimatization and evolutionary adaptation to temperature • Mechanisms underlying the patterns of hibernation, torpor, dormancy, aestivation and diapause • Effects of temperature on reproduction and development, growth, ageing and life-span • Studies on modelling heat transfer between organisms and their environment • The contributions of temperature to effects of climate change on animal species and man • Studies of conservation biology and physiology related to temperature • Behavioural and physiological regulation of body temperature including its pathophysiology and fever • Medical applications of hypo- and hyperthermia Article types: • Original articles • Review articles