Chromatin Alternates Between A and B Compartments at Kilobase Scale for Subgenic Organization

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Jun 6

PMID 37280210

Authors

Hannah L Harris

Huiya Gu

Moshe Olshansky

Ailun Wang

Irene Farabella

Yossi Eliaz

Achyuth Kalluchi

Akshay Krishna

Mozes Jacobs

Gesine Cauer

Melanie Pham

Suhas S P Rao

Olga Dudchenko

Arina Omer

Kiana Mohajeri

Sungjae Kim

Michael H Nichols

Eric S Davis

Dimos Gkountaroulis

Devika Udupa

Aviva Presser Aiden

Victor G Corces

Douglas H Phanstiel

William Stafford Noble

Guy Nir

Michele Di Pierro

Jeong-Sun Seo

Michael E Talkowski

Erez Lieberman Aiden

M Jordan Rowley

Affiliations

Soon will be listed here.

Abstract

Nuclear compartments are prominent features of 3D chromatin organization, but sequencing depth limitations have impeded investigation at ultra fine-scale. CTCF loops are generally studied at a finer scale, but the impact of looping on proximal interactions remains enigmatic. Here, we critically examine nuclear compartments and CTCF loop-proximal interactions using a combination of in situ Hi-C at unparalleled depth, algorithm development, and biophysical modeling. Producing a large Hi-C map with 33 billion contacts in conjunction with an algorithm for performing principal component analysis on sparse, super massive matrices (POSSUMM), we resolve compartments to 500 bp. Our results demonstrate that essentially all active promoters and distal enhancers localize in the A compartment, even when flanking sequences do not. Furthermore, we find that the TSS and TTS of paused genes are often segregated into separate compartments. We then identify diffuse interactions that radiate from CTCF loop anchors, which correlate with strong enhancer-promoter interactions and proximal transcription. We also find that these diffuse interactions depend on CTCF's RNA binding domains. In this work, we demonstrate features of fine-scale chromatin organization consistent with a revised model in which compartments are more precise than commonly thought while CTCF loops are more protracted.

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