Dynamic lineage priming is driven via direct enhancer regulation by ERK

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Standard

Dynamic lineage priming is driven via direct enhancer regulation by ERK. / Hamilton, William B.; Mosesson, Yaron; Monteiro, Rita S.; Emdal, Kristina B.; Knudsen, Teresa E.; Francavilla, Chiara; Barkai, Naama; Olsen, Jesper V.; Brickman, Joshua M.

I: Nature, Bind 575, 2019, s. 355-360.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Hamilton, WB, Mosesson, Y, Monteiro, RS, Emdal, KB, Knudsen, TE, Francavilla, C, Barkai, N, Olsen, JV & Brickman, JM 2019, 'Dynamic lineage priming is driven via direct enhancer regulation by ERK', Nature, bind 575, s. 355-360. https://doi.org/10.1038/s41586-019-1732-z

APA

Hamilton, W. B., Mosesson, Y., Monteiro, R. S., Emdal, K. B., Knudsen, T. E., Francavilla, C., Barkai, N., Olsen, J. V., & Brickman, J. M. (2019). Dynamic lineage priming is driven via direct enhancer regulation by ERK. Nature, 575, 355-360. https://doi.org/10.1038/s41586-019-1732-z

Vancouver

Hamilton WB, Mosesson Y, Monteiro RS, Emdal KB, Knudsen TE, Francavilla C o.a. Dynamic lineage priming is driven via direct enhancer regulation by ERK. Nature. 2019;575:355-360. https://doi.org/10.1038/s41586-019-1732-z

Author

Hamilton, William B. ; Mosesson, Yaron ; Monteiro, Rita S. ; Emdal, Kristina B. ; Knudsen, Teresa E. ; Francavilla, Chiara ; Barkai, Naama ; Olsen, Jesper V. ; Brickman, Joshua M. / Dynamic lineage priming is driven via direct enhancer regulation by ERK. I: Nature. 2019 ; Bind 575. s. 355-360.

Bibtex

@article{440bb80d960246ab9d106d00f67cbd8c,
title = "Dynamic lineage priming is driven via direct enhancer regulation by ERK",
abstract = "Central to understanding cellular behaviour in multi-cellular organisms is the question of how a cell exits one transcriptional state to adopt and eventually become committed to another. Fibroblast growth factor-extracellular signal-regulated kinase (FGF -ERK) signalling drives differentiation of mouse embryonic stem cells (ES cells) and pre-implantation embryos towards primitive endoderm, and inhibiting ERK supports ES cell self-renewal1. Paracrine FGF-ERK signalling induces heterogeneity, whereby cells reversibly progress from pluripotency towards primitive endoderm while retaining their capacity to re-enter self-renewal2. Here we find that ERK reversibly regulates transcription in ES cells by directly affecting enhancer activity without requiring a change in transcription factor binding. ERK triggers the reversible association and disassociation of RNA polymerase II and associated co-factors from genes and enhancers with the mediator component MED24 having an essential role in ERK-dependent transcriptional regulation. Though the binding of mediator components responds directly to signalling, the persistent binding of pluripotency factors to both induced and repressed genes marks them for activation and/or reactivation in response to fluctuations in ERK activity. Among the repressed genes are several core components of the pluripotency network that act to drive their own expression and maintain the ES cell state; if their binding is lost, the ability to reactivate transcription is compromised. Thus, as long as transcription factor occupancy is maintained, so is plasticity, enabling cells to distinguish between transient and sustained signals. If ERK signalling persists, pluripotency transcription factor levels are reduced by protein turnover and irreversible gene silencing and commitment can occur.",
author = "Hamilton, {William B.} and Yaron Mosesson and Monteiro, {Rita S.} and Emdal, {Kristina B.} and Knudsen, {Teresa E.} and Chiara Francavilla and Naama Barkai and Olsen, {Jesper V.} and Brickman, {Joshua M.}",
year = "2019",
doi = "10.1038/s41586-019-1732-z",
language = "English",
volume = "575",
pages = "355--360",
journal = "Nature",
issn = "0028-0836",
publisher = "nature publishing group",

}

RIS

TY - JOUR

T1 - Dynamic lineage priming is driven via direct enhancer regulation by ERK

AU - Hamilton, William B.

AU - Mosesson, Yaron

AU - Monteiro, Rita S.

AU - Emdal, Kristina B.

AU - Knudsen, Teresa E.

AU - Francavilla, Chiara

AU - Barkai, Naama

AU - Olsen, Jesper V.

AU - Brickman, Joshua M.

PY - 2019

Y1 - 2019

N2 - Central to understanding cellular behaviour in multi-cellular organisms is the question of how a cell exits one transcriptional state to adopt and eventually become committed to another. Fibroblast growth factor-extracellular signal-regulated kinase (FGF -ERK) signalling drives differentiation of mouse embryonic stem cells (ES cells) and pre-implantation embryos towards primitive endoderm, and inhibiting ERK supports ES cell self-renewal1. Paracrine FGF-ERK signalling induces heterogeneity, whereby cells reversibly progress from pluripotency towards primitive endoderm while retaining their capacity to re-enter self-renewal2. Here we find that ERK reversibly regulates transcription in ES cells by directly affecting enhancer activity without requiring a change in transcription factor binding. ERK triggers the reversible association and disassociation of RNA polymerase II and associated co-factors from genes and enhancers with the mediator component MED24 having an essential role in ERK-dependent transcriptional regulation. Though the binding of mediator components responds directly to signalling, the persistent binding of pluripotency factors to both induced and repressed genes marks them for activation and/or reactivation in response to fluctuations in ERK activity. Among the repressed genes are several core components of the pluripotency network that act to drive their own expression and maintain the ES cell state; if their binding is lost, the ability to reactivate transcription is compromised. Thus, as long as transcription factor occupancy is maintained, so is plasticity, enabling cells to distinguish between transient and sustained signals. If ERK signalling persists, pluripotency transcription factor levels are reduced by protein turnover and irreversible gene silencing and commitment can occur.

AB - Central to understanding cellular behaviour in multi-cellular organisms is the question of how a cell exits one transcriptional state to adopt and eventually become committed to another. Fibroblast growth factor-extracellular signal-regulated kinase (FGF -ERK) signalling drives differentiation of mouse embryonic stem cells (ES cells) and pre-implantation embryos towards primitive endoderm, and inhibiting ERK supports ES cell self-renewal1. Paracrine FGF-ERK signalling induces heterogeneity, whereby cells reversibly progress from pluripotency towards primitive endoderm while retaining their capacity to re-enter self-renewal2. Here we find that ERK reversibly regulates transcription in ES cells by directly affecting enhancer activity without requiring a change in transcription factor binding. ERK triggers the reversible association and disassociation of RNA polymerase II and associated co-factors from genes and enhancers with the mediator component MED24 having an essential role in ERK-dependent transcriptional regulation. Though the binding of mediator components responds directly to signalling, the persistent binding of pluripotency factors to both induced and repressed genes marks them for activation and/or reactivation in response to fluctuations in ERK activity. Among the repressed genes are several core components of the pluripotency network that act to drive their own expression and maintain the ES cell state; if their binding is lost, the ability to reactivate transcription is compromised. Thus, as long as transcription factor occupancy is maintained, so is plasticity, enabling cells to distinguish between transient and sustained signals. If ERK signalling persists, pluripotency transcription factor levels are reduced by protein turnover and irreversible gene silencing and commitment can occur.

U2 - 10.1038/s41586-019-1732-z

DO - 10.1038/s41586-019-1732-z

M3 - Journal article

C2 - 31695196

VL - 575

SP - 355

EP - 360

JO - Nature

JF - Nature

SN - 0028-0836

ER -

ID: 230145199