Department of Genetics, Albert Einstein College of Medicine, Bronx, NY, USA; Center for Single-Cell Omics, School of Public Health, Shanghai Jiao Tong University, School of Medicine, Shanghai, China.
Ageing Res Rev. 2021 Jul;68:101316. doi: 10.1016/j.arr.2021.101316. Epub 2021 Mar 9.
Damage to the repository of genetic information in cells has plagued life since its very beginning 3-4 billion years ago. Initially, in the absence of an ozone layer, especially damage from solar UV radiation must have been frequent, with other sources, most notably endogenous sources related to cell metabolism, gaining in importance over time. To cope with this high frequency of damage to the increasingly long DNA molecules that came to encode the growing complexity of cellular functions in cells, DNA repair evolved as one of the earliest genetic traits. Then as now, errors during the repair of DNA damage generated mutations, which provide the substrate for evolution by natural selection. With the emergence of multicellular organisms also the soma became a target of DNA damage and mutations. In somatic cells selection against the adverse effects of DNA damage is greatly diminished, especially in postmitotic cells after the age of first reproduction. Based on an abundance of evidence, DNA damage is now considered as the single most important driver of the degenerative processes that collectively cause aging. Here I will first briefly review the evidence for DNA damage as a cause of aging since the beginning of life. Then, after discussing the possible direct adverse effects of DNA damage and its cellular responses, I will provide an overview of the considerable progress that has recently been made in analyzing a major consequence of DNA damage in humans and other complex organisms: somatic mutations and the resulting genome mosaicism. Recent advances in studying somatic mutagenesis and genome mosaicism in different human and animal tissues will be discussed with a focus on the possible mechanisms through which loss of DNA sequence integrity could cause age-related functional decline and disease.
自 30 亿至 40 亿年前生命起源以来,细胞中遗传信息储存库的损伤一直困扰着生命。最初,在缺乏臭氧层的情况下,尤其是太阳紫外线辐射的损伤,肯定是频繁发生的,随着时间的推移,其他来源,尤其是与细胞代谢有关的内源性来源,变得越来越重要。为了应对这种越来越长的 DNA 分子(这些 DNA 分子逐渐编码细胞功能的日益复杂)频繁受到的损伤,DNA 修复作为最早的遗传特征之一而进化。当时和现在一样,在修复 DNA 损伤的过程中产生的错误会产生突变,这些突变为自然选择进化提供了基础。随着多细胞生物的出现,体细胞也成为了 DNA 损伤和突变的靶点。在体细胞中,对 DNA 损伤不利影响的选择大大降低,尤其是在首次繁殖后进入有丝分裂后期的细胞中。基于大量证据,现在认为 DNA 损伤是导致衰老的退行性过程的唯一最重要的驱动因素。在这里,我将首先简要回顾生命起源以来 DNA 损伤作为衰老原因的证据。然后,在讨论 DNA 损伤及其细胞反应的可能直接不利影响之后,我将概述最近在分析 DNA 损伤在人类和其他复杂生物体中的一个主要后果方面取得的相当大的进展:体细胞突变和由此产生的基因组镶嵌性。将讨论在不同人类和动物组织中研究体细胞突变和基因组镶嵌性的最新进展,并重点讨论失去 DNA 序列完整性如何导致与年龄相关的功能下降和疾病的可能机制。
