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Predicting cell type-specific epigenomic profiles accounting for distal genetic effects

Alan E Murphy, William Beardall, Marek Rei, Mike Phuycharoen, Nathan Skene

2024Nature Communications11 citationsDOIOpen Access PDF

Abstract

Understanding how genetic variants affect the epigenome is key to interpreting GWAS, yet profiling these effects across the non-coding genome remains challenging due to experimental scalability. This necessitates accurate computational models. Existing machine learning approaches, while progressively improving, are confined to the cell types they were trained on, limiting their applicability. Here, we introduce Enformer Celltyping, a deep learning model which incorporates distal effects of DNA interactions, up to 100,000 base-pairs away, to predict epigenetic signals in previously unseen cell types. Using DNA and chromatin accessibility data for epigenetic imputation, Enformer Celltyping outperforms current best-in-class approaches and generalises across cell types and biological regions. Moreover, we propose a framework for evaluating models on genetic variant effect prediction using regulatory quantitative trait loci mapping studies, highlighting current limitations in genomic deep learning models. Despite this, Enformer Celltyping can also be used to study cell type-specific genetic enrichment of complex traits.

Topics & Concepts

EpigenomicsComputer scienceComputational biologyEpigenomeChromatinEpigeneticsGenome-wide association studyArtificial intelligenceInterpretabilityQuantitative trait locusMachine learningBiologyDNA methylationGeneticsDNAGeneSingle-nucleotide polymorphismGenotypeGene expressionGenomics and Chromatin DynamicsEpigenetics and DNA MethylationSingle-cell and spatial transcriptomics