Extensive Long-range Polycomb Interactions and Weak Compartmentalization Are Hallmarks of Human Neuronal 3D Genome

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2024 Apr 22

PMID 38647066

Authors

Ilya A Pletenev

Maria Bazarevich

Diana R Zagirova

Anna D Kononkova

Alexander V Cherkasov

Olga I Efimova

Eugenia A Tiukacheva

Kirill V Morozov

Kirill A Ulianov

Dmitriy Komkov

Anna V Tvorogova

Vera E Golimbet

Nikolay V Kondratyev

Sergey V Razin

Philipp Khaitovich

Sergey V Ulianov

Ekaterina E Khrameeva

Affiliations

Soon will be listed here.

Abstract

Chromatin architecture regulates gene expression and shapes cellular identity, particularly in neuronal cells. Specifically, polycomb group (PcG) proteins enable establishment and maintenance of neuronal cell type by reorganizing chromatin into repressive domains that limit the expression of fate-determining genes and sustain distinct gene expression patterns in neurons. Here, we map the 3D genome architecture in neuronal and non-neuronal cells isolated from the Wernicke's area of four human brains and comprehensively analyze neuron-specific aspects of chromatin organization. We find that genome segregation into active and inactive compartments is greatly reduced in neurons compared to other brain cells. Furthermore, neuronal Hi-C maps reveal strong long-range interactions, forming a specific network of PcG-mediated contacts in neurons that is nearly absent in other brain cells. These interacting loci contain developmental transcription factors with repressed expression in neurons and other mature brain cells. But only in neurons, they are rich in bivalent promoters occupied by H3K4me3 histone modification together with H3K27me3, which points to a possible functional role of PcG contacts in neurons. Importantly, other layers of chromatin organization also exhibit a distinct structure in neurons, characterized by an increase in short-range interactions and a decrease in long-range ones.

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