Chromatin Folding and Nuclear Architecture: PRC1 Function in 3D

Robert Illingworth

doi:10.1016/j.gde.2019.06.006

Chromatin Folding and Nuclear Architecture: PRC1 Function in 3D

Research output: Contribution to journal › Article › peer-review

Abstract

Embryonic development requires the intricate balance between the expansion and specialisation of defined cell types in time and space. The gene expression
programmes that underpin this balance are regulated, in part, by modulating the
chemical and structural state of chromatin. Polycomb repressive complexes (PRCs), a family of essential developmental regulators, operate at this level to stabilise or perpetuate a repressed but transcriptionally poised chromatin configuration. This dynamic state is required to control the timely initiation of productive gene transcription during embryonic development. The two major PRCs cooperate to target the genome, but it is PRC1 that appears to be the primary effector that controls gene expression. In this review I will discuss recent findings relating to how PRC1 alters chromatin accessibility, folding and global 3D nuclear organisation to control gene transcription.

Original language	English
Journal	Current Opinion in Genetics and Development
DOIs	https://doi.org/10.1016/j.gde.2019.06.006
Publication status	Published - 16 Jul 2019

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10.1016/j.gde.2019.06.006

RI Final_Article_FigsAccepted author manuscript, 748 KBLicence: Creative Commons: Attribution Non-Commercial (CC-BY-NC)

Cell-Specific PRC1 Accessory Proteins and the Regulation of Mammalian Neurodevelopment
Illingworth, R.
MRC
1/04/19 → 31/03/24
Project: Research

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AB - Embryonic development requires the intricate balance between the expansion and specialisation of defined cell types in time and space. The gene expressionprogrammes that underpin this balance are regulated, in part, by modulating thechemical and structural state of chromatin. Polycomb repressive complexes (PRCs), a family of essential developmental regulators, operate at this level to stabilise or perpetuate a repressed but transcriptionally poised chromatin configuration. This dynamic state is required to control the timely initiation of productive gene transcription during embryonic development. The two major PRCs cooperate to target the genome, but it is PRC1 that appears to be the primary effector that controls gene expression. In this review I will discuss recent findings relating to how PRC1 alters chromatin accessibility, folding and global 3D nuclear organisation to control gene transcription.

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JF - Current Opinion in Genetics and Development

SN - 0959-437X

ER -

Chromatin Folding and Nuclear Architecture: PRC1 Function in 3D

Abstract

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Cell-Specific PRC1 Accessory Proteins and the Regulation of Mammalian Neurodevelopment

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