基于机器学习的可解释脑脊液蛋白质组学预测年龄时钟揭示了大脑衰老的新见解。

IF 7.8 1区 医学 Q1 Biochemistry, Genetics and Molecular Biology Aging Cell Pub Date : 2024-06-24 DOI:10.1111/acel.14230
Justin Melendez, Yun Ju Sung, Miranda Orr, Andrew Yoo, Suzanne Schindler, Carlos Cruchaga, Randall Bateman
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引用次数: 0

摘要

机器学习可用于创建预测年龄的 "生物钟"。然而,器官、组织和生物流体的衰老速度可能与机体整体的衰老速度不同。我们试图了解脑脊液(CSF)是如何随着年龄的增长而变化的,从而为大脑衰老相关疾病机制的发展提供信息,并确定潜在的抗衰老治疗靶点。目前已有几种基于血浆和神经元组织的表观遗传时钟;但是,血浆可能无法具体反映大脑的衰老,而基于组织的时钟需要从活体参与者身上获取样本,这很困难。为了解决这些问题,我们开发了一种机器学习时钟,利用脑脊液蛋白质组学预测个人的年代年龄,在我们的验证队列中,皮尔逊相关性为 0.79,平均估计误差 (MAE) 为 4.30 岁。此外,我们还分析了该算法高度加权的蛋白质,以深入了解 CSF 的变化,发现大脑衰老的新见解。我们还展示了一种创建最小蛋白质时钟的新方法,该方法仅使用原始时钟中的 109 个蛋白质特征,就达到了类似的准确度(相关性为 0.75,MAE 为 5.41)。最后,我们证明了我们的时钟能识别出在与其他蛋白质相互作用中高度预测年龄的新型蛋白质,但这些蛋白质本身并不直接与计时年龄相关。总之,我们提出,我们的 CSF 蛋白质老化时钟可以识别影响中枢神经系统(CNS)老化速度的新型蛋白质,而这种方式无法通过研究它们各自与年龄的关系来识别。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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An interpretable machine learning-based cerebrospinal fluid proteomics clock for predicting age reveals novel insights into brain aging

Machine learning can be used to create “biologic clocks” that predict age. However, organs, tissues, and biofluids may age at different rates from the organism as a whole. We sought to understand how cerebrospinal fluid (CSF) changes with age to inform the development of brain aging-related disease mechanisms and identify potential anti-aging therapeutic targets. Several epigenetic clocks exist based on plasma and neuronal tissues; however, plasma may not reflect brain aging specifically and tissue-based clocks require samples that are difficult to obtain from living participants. To address these problems, we developed a machine learning clock that uses CSF proteomics to predict the chronological age of individuals with a 0.79 Pearson correlation and mean estimated error (MAE) of 4.30 years in our validation cohort. Additionally, we analyzed proteins highly weighted by the algorithm to gain insights into changes in CSF and uncover novel insights into brain aging. We also demonstrate a novel method to create a minimal protein clock that uses just 109 protein features from the original clock to achieve a similar accuracy (0.75 correlation, MAE 5.41). Finally, we demonstrate that our clock identifies novel proteins that are highly predictive of age in interactions with other proteins, but do not directly correlate with chronological age themselves. In conclusion, we propose that our CSF protein aging clock can identify novel proteins that influence the rate of aging of the central nervous system (CNS), in a manner that would not be identifiable by examining their individual relationships with age.

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来源期刊
Aging Cell
Aging Cell 生物-老年医学
CiteScore
14.40
自引率
2.60%
发文量
212
审稿时长
8 weeks
期刊介绍: Aging Cell, an Open Access journal, delves into fundamental aspects of aging biology. It comprehensively explores geroscience, emphasizing research on the mechanisms underlying the aging process and the connections between aging and age-related diseases.
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