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从细胞动力学推断表观遗传年龄加速。

Probabilistic inference of epigenetic age acceleration from cellular dynamics.

机构信息

School of Informatics, University of Edinburgh, Edinburgh, UK.

MRC Human Genetics Unit, University of Edinburgh, Edinburgh, UK.

出版信息

Nat Aging. 2024 Oct;4(10):1493-1507. doi: 10.1038/s43587-024-00700-5. Epub 2024 Sep 23.

DOI:10.1038/s43587-024-00700-5
PMID:39313745
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11485233/
Abstract

The emergence of epigenetic predictors was a pivotal moment in geroscience, propelling the measurement and concept of biological aging into a quantitative era; however, while current epigenetic clocks show strong predictive power, they are data-driven in nature and are not based on the underlying biological mechanisms driving methylation dynamics. We show that predictions of these clocks are susceptible to several confounding non-age-related phenomena that make interpretation of these estimates and associations difficult. To address these limitations, we developed a probabilistic model describing methylation transitions at the cellular level. Our approach reveals two measurable components, acceleration and bias, which directly reflect perturbations of the underlying cellular dynamics. Acceleration is the proportional increase in the speed of methylation transitions across CpG sites, whereas bias corresponds to global changes in methylation levels. Using data from 15,900 participants from the Generation Scotland study, we develop a robust inference framework and show that these are two distinct processes confounding current epigenetic predictors. Our results show improved associations of acceleration and bias with physiological traits known to impact healthy aging, such as smoking and alcohol consumption, respectively. Furthermore, a genome-wide association study of epigenetic age acceleration identified seven genomic loci.

摘要

表观遗传预测因子的出现是衰老科学的一个关键时刻,将生物衰老的测量和概念推进到了定量时代;然而,尽管目前的表观遗传时钟显示出很强的预测能力,但它们本质上是数据驱动的,并且不是基于驱动甲基化动态的潜在生物学机制。我们表明,这些时钟的预测容易受到几种混杂的与年龄无关的现象的影响,这使得这些估计和关联的解释变得困难。为了解决这些限制,我们开发了一个描述细胞水平甲基化转变的概率模型。我们的方法揭示了两个可测量的成分,即加速和偏差,它们直接反映了潜在细胞动力学的干扰。加速是 CpG 位点上甲基化转变速度的比例增加,而偏差对应于甲基化水平的全局变化。利用来自苏格兰世代研究的 15900 名参与者的数据,我们开发了一个强大的推理框架,并表明这些是混淆当前表观遗传预测因子的两个不同过程。我们的结果表明,加速和偏差与已知影响健康衰老的生理特征(如吸烟和饮酒)的关联得到了改善。此外,对表观遗传年龄加速的全基因组关联研究确定了七个基因组位点。

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