A synergistic DNA logic predicts genome-wide chromatin accessibility

Author(s)

Sherwood, Richard I.; Emons, Bart J.M.; Hashimoto, Tatsunori Benjamin; Kang, Daniel D.; Rajagopal, Nisha; Barkal, Amira; Zeng, Haoyang; Srinivasan, Sharanya; Jaakkola, Tommi S.; Gifford, David K.; ... Show more Show less

Abstract

Enhancers and promoters commonly occur in accessible chromatin characterized by depleted nucleosome contact; however, it is unclear how chromatin accessibility is governed. We show that log-additive cis-acting DNA sequence features can predict chromatin accessibility at high spatial resolution. We develop a new type of high-dimensional machine learning model, the Synergistic Chromatin Model (SCM), which when trained with DNase-seq data for a cell type is capable of predicting expected read counts of genome-wide chromatin accessibility at every base from DNA sequence alone, with the highest accuracy at hypersensitive sites shared across cell types. We confirm that a SCM accurately predicts chromatin accessibility for thousands of synthetic DNA sequences using a novel CRISPR-based method of highly efficient site-specific DNA library integration. SCMs are directly interpretable and reveal that a logic based on local, nonspecific synergistic effects, largely among pioneer TFs, is sufficient to predict a large fraction of cellular chromatin accessibility in a wide variety of cell types.

Date issued

206-08

URI

http://hdl.handle.net/1721.1/107146

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory
Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science

Journal

Genome Research

Publisher

Cold Spring Harbor Laboratory Press

Citation

Hashimoto, Tatsunori et al. “A Synergistic DNA Logic Predicts Genome-Wide Chromatin Accessibility.” Genome Research 26.10 (2016): 1430–1440.

Version: Final published version

ISSN

1088-9051

1549-5469