Quantitative Classification of Chromatin Dynamics Reveals Regulators of Intestinal Stem Cell Differentiation

Overview

Journal Development

Specialty Biology

Date 2019 Dec 22

PMID 31862843

Citations 16

Authors

Jesse R Raab

Deepthi Y Tulasi

Kortney E Wager

Jeremy M Morowitz

Scott T Magness

Adam D Gracz

Affiliations

Soon will be listed here.

Abstract

Intestinal stem cell (ISC) plasticity is thought to be regulated by broadly permissive chromatin shared between ISCs and their progeny. Here, we have used a Sox9 reporter to examine chromatin across ISC differentiation. We find that open chromatin regions (OCRs) can be defined as broadly permissive or dynamic in a locus-specific manner, with dynamic OCRs found primarily in loci consistent with distal enhancers. By integrating gene expression with chromatin accessibility at transcription factor (TF) motifs in the context of Sox9 populations, we classify broadly permissive and dynamic chromatin relative to TF usage. These analyses identify known and potential regulators of ISC differentiation via association with dynamic changes in chromatin. Consistent with computational predictions, Id3-null mice exhibit increased numbers of cells expressing the ISC-specific biomarker OLFM4. Finally, we examine the relationship between gene expression and 5-hydroxymethylcytosine (5hmC) in Sox9 populations, which reveals 5hmC enrichment in absorptive lineage-specific genes. Our data demonstrate that intestinal chromatin dynamics can be quantitatively defined in a locus-specific manner, identify novel potential regulators of ISC differentiation and provide a chromatin roadmap for further dissecting regulation of cell fate in the intestine.

Citing Articles

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