将减少线粒体直接重复作为提高人类寿命的策略:常见重复的案例

Victor A. Shamanskiy, Konstantin V. Gunbin, Evgenii O. Tretiakov, Ilia O. Mazunin, Victoria Skripskaya, Alina A. Mihailova, Alina G. Mikhailova, Natalia Ree, Valeriia Timonina, Dmitry Knorre, Wolfram S. Kunz, Yukinori Okada, Nathan Fiorell, Alexandre Reymond, Georgii A. Bazykin, Jacques Fellay, Masashi Tanaka, Konstantin Khrapko, Konstantin Popadin
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引用次数: 0

摘要

衰老的特征是一系列与年龄增长相关的功能衰退,其中线粒体 DNA(mtDNA)是重要的组成部分,而体细胞的 mtDNA 缺失起着核心作用。在神经元和骨骼肌等有丝分裂后或分裂缓慢的细胞中,自私的 mtDNA 缺失会在细胞内克隆扩增,最终导致宿主细胞退化和死亡,并出现与年龄相关的表型。因此,减少体细胞缺失的负担会对整个人体产生深远的系统性益处。鉴于直接核苷酸重复序列在线粒体缺失形成过程中的关键作用,我们假设尽量减少人类线粒体基因组中的这些重复序列可以通过减少体细胞缺失来延长健康寿命。为了研究这一假设,我们重点研究了 "共同重复",即分别位于 8470-8482 和 13447-13459 位置的 13 碱基对完美直接重复序列(ACCTCCCTCACCA)。这个完美重复序列:(i) 高度流行,其潜在的有害后果影响着大多数人类;(ii) 是最脆弱的位点之一,极易形成缺失;(iii) 一旦被破坏,与体细胞缺失负荷的减少和人类健康寿命的延长有关;(iv) 由于 "祖母效应 "等间接的健康效应和(v) 突变率的降低等直接的健康效应,在目前或不久的将来很可能会经历积极的选择。这些观察结果支持这样一种论点,即通过有针对性地破坏这些重复序列,或在线粒体药物中使用具有破坏性重复序列的天然多态性来减少 mtDNA 体细胞缺失负荷,可能是延长人类寿命的一种有效方法。
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Mitochondrial direct repeat reduction as a strategy for enhancing human longevity: the case of the common repeat
Aging, characterized by a series of functional declines correlated with advancing chronological age, has a significant mitochondrial DNA (mtDNA) component, with somatic mtDNA deletions playing a central role. In post-mitotic or slow-dividing cells like neurons and skeletal muscles, selfish mtDNA deletions clonally expand within a cell, ultimately leading to the deterioration and death of host cells and appearence of age-related phenotypes. Thus reducing the burden of somatic deletions could have far-reaching systemic benefits for the entire human body. Given the crucial role of direct nucleotide repeats in the formation of mitochondrial deletions, we hypothesize that minimizing these repeats in the human mitochondrial genome could enhance healthspan by decreasing somatic deletions. To investigate this hypothesis, we focus on the "common repeat", a 13-base pair perfect direct repeat sequence (ACCTCCCTCACCA) located at positions 8470-8482 and 13447-13459, respectively. This perfect repeat: (i) is highly prevalent, with its potential deleterious consequences affecting the majority of humans; (ii) represents one of the most fragile sites, highly prone to forming deletions; (iii) when disrupted, is associated with a decreased somatic deletion load and enhanced human healthspan; (iv) is likely to experience positive selection in the present or near future due to indirect fitness effects, such as the "grandmother effect", and direct fitness effects, such as (v) a decreased mutation rate. These observations support the argument that reducing the mtDNA somatic deletion load through targeted disruption of these repeats, or by using naturally occurring polymorphisms with disrupted repeats in mitochondrial medicine, could be an effective approach to increasing human longevity.
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