Raghav Sehgal, Yaroslav Markov, Chenxi Qin, Margarita Meer, Courtney Hadley, Aladdin H Shadyab, Ramon Casanova, JoAnn E Manson, Parveen Bhatti, Eileen M Crimmins, Sara Hägg, Themistocles L Assimes, Eric A Whitsel, Albert Tzongyang Higgins-Chen, Morgan Levine
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引用次数: 0
Abstract
Individuals, organs, tissues, and cells age in diverse ways throughout the lifespan. Epigenetic clocks attempt to quantify differential aging between individuals, but they typically summarize aging as a single measure, ignoring within-person heterogeneity. Our aim was to develop novel systems-based methylation clocks that, when assessed in blood, capture aging in distinct physiological systems. We combined supervised and unsupervised machine learning methods to link DNA methylation, system-specific clinical chemistry and functional measures, and mortality risk. This yielded a panel of 11 system-specific scores- Heart, Lung, Kidney, Liver, Brain, Immune, Inflammatory, Blood, Musculoskeletal, Hormone, and Metabolic. Each system score predicted a wide variety of outcomes, aging phenotypes, and conditions specific to the respective system. We also combined the system scores into a composite Systems Age clock that is predictive of aging across physiological systems in an unbiased manner. Finally, we showed that the system scores clustered individuals into unique aging subtypes that had different patterns of age-related disease and decline. Overall, our biological systems based epigenetic framework captures aging in multiple physiological systems using a single blood draw and assay and may inform the development of more personalized clinical approaches for improving age-related quality of life.
在人的一生中,个体、器官、组织和细胞的衰老方式多种多样。表观遗传时钟试图量化个体之间的衰老差异,但它们通常将衰老概括为单一的衡量标准,忽略了个体内部的异质性。我们的目标是开发基于系统的新型甲基化时钟,在对血液进行评估时,可以捕捉不同生理系统的衰老情况。我们结合了有监督和无监督的机器学习方法,将 DNA 甲基化、系统特异性临床化学和功能测量以及死亡风险联系起来。这产生了一个由 11 个系统特异性评分组成的小组--心脏、肺、肾、肝、脑、免疫、炎症、血液、肌肉骨骼、激素和代谢。每个系统得分都能预测各种结果、衰老表型和各系统特有的状况,而且往往比现有的报告单一总体测量结果的表观遗传时钟更强。我们还将各系统得分合并成一个综合系统年龄时钟,该时钟能以无偏的方式预测各生理系统的衰老。最后,我们表明,系统得分将个体聚类为独特的衰老亚型,这些亚型具有不同的与年龄相关的疾病和衰退模式。总之,我们基于生物系统的表观遗传学框架只需一次抽血和检测就能捕捉到多个生理系统中的衰老现象,并能为开发更个性化的临床方法提供信息,从而改善与年龄相关的生活质量。
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