A SuperLearner-based pipeline for the development of DNA methylation-derived predictors of phenotypic traits.

IF 3.6 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS PLoS Computational Biology Pub Date : 2025-02-06 eCollection Date: 2025-02-01 DOI:10.1371/journal.pcbi.1012768

Dennis Khodasevich, Nina Holland, Lars van der Laan, Andres Cardenas

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Abstract

Background: DNA methylation (DNAm) provides a window to characterize the impacts of environmental exposures and the biological aging process. Epigenetic clocks are often trained on DNAm using penalized regression of CpG sites, but recent evidence suggests potential benefits of training epigenetic predictors on principal components.

Methodology/findings: We developed a pipeline to simultaneously train three epigenetic predictors; a traditional CpG Clock, a PCA Clock, and a SuperLearner PCA Clock (SL PCA). We gathered publicly available DNAm datasets to generate i) a novel childhood epigenetic clock, ii) a reconstructed Hannum adult blood clock, and iii) as a proof of concept, a predictor of polybrominated biphenyl exposure using the three developmental methodologies. We used correlation coefficients and median absolute error to assess fit between predicted and observed measures, as well as agreement between duplicates. The SL PCA clocks improved fit with observed phenotypes relative to the PCA clocks or CpG clocks across several datasets. We found evidence for higher agreement between duplicate samples run on alternate DNAm arrays when using SL PCA clocks relative to traditional methods. Analyses examining associations between relevant exposures and epigenetic age acceleration (EAA) produced more precise effect estimates when using predictions derived from SL PCA clocks.

Conclusions: We introduce a novel method for the development of DNAm-based predictors that combines the improved reliability conferred by training on principal components with advanced ensemble-based machine learning. Coupling SuperLearner with PCA in the predictor development process may be especially relevant for studies with longitudinal designs utilizing multiple array types, as well as for the development of predictors of more complex phenotypic traits.

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基于superlearner的管道，用于开发DNA甲基化衍生的表型性状预测因子。

背景：DNA甲基化（DNAm）为描述环境暴露和生物老化过程的影响提供了一个窗口。表观遗传时钟通常使用CpG位点的惩罚性回归对DNAm进行训练，但最近的证据表明，在主成分上训练表观遗传预测因子具有潜在的益处。方法/发现：我们开发了一个管道，同时训练三个表观遗传预测因子；一个传统的CpG时钟，一个PCA时钟和一个超级学习者PCA时钟（SL PCA）。我们收集了公开可用的DNAm数据集，以生成i)一个新的儿童表观遗传时钟，ii)一个重建的汉纳姆成人血液时钟，以及iii)作为概念证明，使用三种发育方法预测多溴联苯暴露。我们使用相关系数和中位数绝对误差来评估预测和观测测量之间的拟合，以及重复测量之间的一致性。在多个数据集上，相对于PCA时钟或CpG时钟，SL PCA时钟改善了与观察到的表型的拟合。我们发现，当使用相对于传统方法的SL PCA时钟时，在备用DNAm阵列上运行的重复样本之间存在更高的一致性。研究相关暴露与表观遗传年龄加速（EAA）之间关系的分析，在使用来自SL PCA时钟的预测时，产生了更精确的影响估计。结论：我们引入了一种开发基于dnam的预测器的新方法，该方法将主成分训练与先进的基于集成的机器学习相结合，从而提高了可靠性。在预测器开发过程中，将超级学习者与PCA相结合可能特别适用于使用多种阵列类型的纵向设计研究，以及更复杂表型性状的预测器开发。

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来源期刊

PLoS Computational Biology BIOCHEMICAL RESEARCH METHODS-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

7.10

自引率

4.70%

发文量

820

审稿时长

2.5 months

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