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Matrix factorization and transfer learning uncover regulatory biology across multiple single-cell ATAC-seq data sets

Rossin Erbe, Michael D. Kessler, Alexander V. Favorov, Hariharan Easwaran, Daria A. Gaykalova, Elana J. Fertig

2020Nucleic Acids Research17 citationsDOIOpen Access PDF

Abstract

While the methods available for single-cell ATAC-seq analysis are well optimized for clustering cell types, the question of how to integrate multiple scATAC-seq data sets and/or sequencing modalities is still open. We present an analysis framework that enables such integration across scATAC-seq data sets by applying the CoGAPS Matrix Factorization algorithm and the projectR transfer learning program to identify common regulatory patterns across scATAC-seq data sets. We additionally integrate our analysis with scRNA-seq data to identify orthogonal evidence for transcriptional regulators predicted by scATAC-seq analysis. Using publicly available scATAC-seq data, we find patterns that accurately characterize cell types both within and across data sets. Furthermore, we demonstrate that these patterns are both consistent with current biological understanding and reflective of novel regulatory biology.

Topics & Concepts

BiologyComputational biologyNon-negative matrix factorizationCluster analysisGeneticsMatrix decompositionComputer scienceMachine learningEigenvalues and eigenvectorsQuantum mechanicsPhysicsSingle-cell and spatial transcriptomicsRNA Research and SplicingGenomics and Chromatin Dynamics
Matrix factorization and transfer learning uncover regulatory biology across multiple single-cell ATAC-seq data sets | Litcius