TY - JOUR T1 - A comparison of reference-based algorithms for correcting cell-type heterogeneity in Epigenome-Wide Association Studies JF - bioRxiv DO - 10.1101/101709 SP - 101709 AU - Andrew E Teschendorff AU - Charles E Breeze AU - Shijie C Zheng AU - Stephan Beck Y1 - 2017/01/01 UR - http://biorxiv.org/content/early/2017/01/19/101709.abstract N2 - Background Intra-sample cellular heterogeneity presents numerous challenges to the identification of biomarkers in large Epigenome-Wide Association Studies (EWAS). While a number of reference-based deconvolution algorithms have emerged, their potential remains underexplored and a comparative evaluation of these algorithms beyond tissues such as blood is still lacking.Results Here we present a novel framework for reference-based inference, which leverages cell-type specific DNAse Hypersensitive Site (DHS) information from the NIH Epigenomics Roadmap to construct an improved reference DNA methylation database. We show that this leads to a marginal but statistically significant improvement of cell-count estimates in whole blood as well as in mixtures involving epithelial cell-types. Using this framework we compare a widely used state-of-the-art reference-based algorithm (called constrained projection) to two non-constrained approaches including CIBERSORT and a method based on robust partial correlations. We conclude that the widely-used constrained projection technique may not always be optimal. Instead, we find that the method based on robust partial correlations is generally more robust across a range of different tissue types and for realistic noise levels. We call the combined algorithm which uses DHS data and robust partial correlations for inference, EpiDISH (Epigenetic Dissection of Intra-Sample Heterogeneity). Finally, we demonstrate the added value of EpiDISH in an EWAS of smoking.Conclusions Estimating cell-type fractions and subsequent inference in EWAS may benefit from the use of non-constrained reference-based cell-type deconvolution methods.DMCdifferentially methylated CpGEWASEpigenome-Wide-Association StudyDNAmDNA methylationFDRfalse discovery rateRUVRemoving Unwanted VariationDHSDNAse Hypersensitive SitesDMCsmoking-associated differentially methylated CpG ER -