Predicting A/B Compartments from Histone Modifications Using Deep Learning

Overview

Journal iScience

Publisher Cell Press

Date 2024 Apr 22

PMID 38646172

Authors

Suchen Zheng

Nitya Thakkar

Hannah L Harris

Susanna Liu

Megan Zhang

Mark Gerstein

Erez Lieberman Aiden

M Jordan Rowley

William Stafford Noble

Gamze Gursoy

Ritambhara Singh

Affiliations

Soon will be listed here.

Abstract

The three-dimensional organization of genomes plays a crucial role in essential biological processes. The segregation of chromatin into A and B compartments highlights regions of activity and inactivity, providing a window into the genomic activities specific to each cell type. Yet, the steep costs associated with acquiring Hi-C data, necessary for studying this compartmentalization across various cell types, pose a significant barrier in studying cell type specific genome organization. To address this, we present a prediction tool called compartment prediction using recurrent neural networks (CoRNN), which predicts compartmentalization of 3D genome using histone modification enrichment. CoRNN demonstrates robust cross-cell-type prediction of A/B compartments with an average AuROC of 90.9%. Cell-type-specific predictions align well with known functional elements, with H3K27ac and H3K36me3 identified as highly predictive histone marks. We further investigate our mispredictions and found that they are located in regions with ambiguous compartmental status. Furthermore, our model's generalizability is validated by predicting compartments in independent tissue samples, which underscores its broad applicability.

Citing Articles

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Kalluchi A, Harris H, Reznicek T, Rowley M Front Mol Biosci. 2023; 10:1168562.

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