Telomeres and aging: on and off the planet!

IF 4.4 4区 医学 Q1 GERIATRICS & GERONTOLOGY Biogerontology Pub Date : 2024-04-01 DOI:10.1007/s10522-024-10098-7
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Abstract

Improving human healthspan in our rapidly aging population has never been more imperative. Telomeres, protective “caps” at the ends of linear chromosomes, are essential for maintaining genome stability of eukaryotic genomes. Due to their physical location and the “end-replication problem” first envisioned by Dr. Alexey Olovnikov, telomeres shorten with cell division, the implications of which are remarkably profound. Telomeres are hallmarks and molecular drivers of aging, as well as fundamental integrating components of the cumulative effects of genetic, lifestyle, and environmental factors that erode telomere length over time. Ongoing telomere attrition and the resulting limit to replicative potential imposed by cellular senescence serves a powerful tumor suppressor function, and also underlies aging and a spectrum of age-related degenerative pathologies, including reduced fertility, dementias, cardiovascular disease and cancer. However, very little data exists regarding the extraordinary stressors and exposures associated with long-duration space exploration and eventual habitation of other planets, nor how such missions will influence telomeres, reproduction, health, disease risk, and aging. Here, we briefly review our current understanding, which has advanced significantly in recent years as a result of the NASA Twins Study, the most comprehensive evaluation of human health effects associated with spaceflight ever conducted. Thus, the Twins Study is at the forefront of personalized space medicine approaches for astronauts and sets the stage for subsequent missions. We also extrapolate from current understanding to future missions, highlighting potential biological and biochemical strategies that may enable human survival, and consider the prospect of longevity in the extreme environment of space.

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端粒与衰老:地球上和地球外!
摘要 在人口迅速老龄化的今天,改善人类的健康寿命比以往任何时候都更为迫切。端粒是线性染色体末端的保护性 "帽子",对于维持真核生物基因组的稳定性至关重要。由于端粒的物理位置以及阿列克谢-奥洛夫尼科夫(Alexey Olovnikov)博士首次提出的 "末端复制问题",端粒会随着细胞分裂而缩短,其影响极为深远。端粒是衰老的标志和分子驱动因素,也是遗传、生活方式和环境因素累积效应的基本整合成分,这些因素会随着时间的推移侵蚀端粒长度。端粒的持续损耗以及由此导致的细胞衰老对复制潜能的限制具有强大的肿瘤抑制功能,同时也是衰老和一系列与年龄相关的退行性病变(包括生育能力下降、痴呆症、心血管疾病和癌症)的基础。然而,关于长期太空探索和最终居住在其他行星上所带来的巨大压力和暴露,以及这些任务将如何影响端粒、生殖、健康、疾病风险和衰老,目前的数据还非常少。在此,我们简要回顾一下我们目前的认识,近年来,由于美国国家航空航天局双胞胎研究(NASA Twins Study)的开展,我们的认识有了长足的进步,该研究是迄今为止对与太空飞行相关的人类健康影响进行的最全面的评估。因此,双胞胎研究走在了为宇航员提供个性化太空医疗方法的前沿,并为后续任务奠定了基础。我们还从目前的理解推断未来的任务,强调可能使人类生存的潜在生物和生化策略,并考虑在极端的太空环境中长寿的前景。
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来源期刊
Biogerontology
Biogerontology 医学-老年医学
CiteScore
8.00
自引率
4.40%
发文量
54
审稿时长
>12 weeks
期刊介绍: The journal Biogerontology offers a platform for research which aims primarily at achieving healthy old age accompanied by improved longevity. The focus is on efforts to understand, prevent, cure or minimize age-related impairments. Biogerontology provides a peer-reviewed forum for publishing original research data, new ideas and discussions on modulating the aging process by physical, chemical and biological means, including transgenic and knockout organisms; cell culture systems to develop new approaches and health care products for maintaining or recovering the lost biochemical functions; immunology, autoimmunity and infection in aging; vertebrates, invertebrates, micro-organisms and plants for experimental studies on genetic determinants of aging and longevity; biodemography and theoretical models linking aging and survival kinetics.
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