The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes

Tess Tsai Hsiu Lu; Steffen Heyne; Erez Dror; Eduard Casas; Laura Leonhardt; Thorina Boenke; Chih Hsiang Yang; Sagar; Laura Arrigoni; Kevin Dalgaard; Raffaele Teperino; Lennart Enders; Madhan Selvaraj; Marius Ruf; Sunil J. Raja; Huafeng Xie; Ulrike Boenisch; Stuart H. Orkin; Francis C. Lynn; Brad G. Hoffman; Dominic Grün; Tanya Vavouri; Adelheid M. Lempradl; J. Andrew Pospisilik

doi:10.1016/j.cmet.2018.04.013

The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes

Tess Tsai Hsiu Lu, Steffen Heyne, Erez Dror, Eduard Casas, Laura Leonhardt, Thorina Boenke, Chih Hsiang Yang, Sagar, Laura Arrigoni, Kevin Dalgaard, Raffaele Teperino, Lennart Enders, Madhan Selvaraj, Marius Ruf, Sunil J. Raja, Huafeng Xie, Ulrike Boenisch, Stuart H. Orkin, Francis C. Lynn, Brad G. HoffmanDominic Grün, Tanya Vavouri, Adelheid M. Lempradl, J. Andrew Pospisilik^*

^*Corresponding author for this work

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

104 Scopus citations

Abstract

To date, it remains largely unclear to what extent chromatin machinery contributes to the susceptibility and progression of complex diseases. Here, we combine deep epigenome mapping with single-cell transcriptomics to mine for evidence of chromatin dysregulation in type 2 diabetes. We find two chromatin-state signatures that track β cell dysfunction in mice and humans: ectopic activation of bivalent Polycomb-silenced domains and loss of expression at an epigenomically unique class of lineage-defining genes. β cell-specific Polycomb (Eed/PRC2) loss of function in mice triggers diabetes-mimicking transcriptional signatures and highly penetrant, hyperglycemia-independent dedifferentiation, indicating that PRC2 dysregulation contributes to disease. The work provides novel resources for exploring β cell transcriptional regulation and identifies PRC2 as necessary for long-term maintenance of β cell identity. Importantly, the data suggest a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes. Lu et al. provide evidence of chromatin dysregulation in type 2 diabetes in mice and humans. Loss of Polycomb silencing in mouse pancreas triggers hyperglycemia-independent dedifferentiation of β cells and diabetes, suggesting a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes.

Original language	English
Pages (from-to)	1294-1308.e7
Journal	Cell Metabolism
Volume	27
Issue number	6
DOIs	https://doi.org/10.1016/j.cmet.2018.04.013
State	Published - 5 Jun 2018
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2018 The Author(s)

Keywords

Eed
Polycomb
cell identity
chromatin
complex diseases
de-differentiation
diabetes
epigenetic
type 2 diabetes
β cells

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.cmet.2018.04.013

Cite this

Lu, T. T. H., Heyne, S., Dror, E., Casas, E., Leonhardt, L., Boenke, T., Yang, C. H., Sagar, Arrigoni, L., Dalgaard, K., Teperino, R., Enders, L., Selvaraj, M., Ruf, M., Raja, S. J., Xie, H., Boenisch, U., Orkin, S. H., Lynn, F. C., ... Pospisilik, J. A. (2018). The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes. Cell Metabolism, 27(6), 1294-1308.e7. https://doi.org/10.1016/j.cmet.2018.04.013

@article{23e3ecd570964ba19e3b0220aa1fe864,

title = "The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes",

abstract = "To date, it remains largely unclear to what extent chromatin machinery contributes to the susceptibility and progression of complex diseases. Here, we combine deep epigenome mapping with single-cell transcriptomics to mine for evidence of chromatin dysregulation in type 2 diabetes. We find two chromatin-state signatures that track β cell dysfunction in mice and humans: ectopic activation of bivalent Polycomb-silenced domains and loss of expression at an epigenomically unique class of lineage-defining genes. β cell-specific Polycomb (Eed/PRC2) loss of function in mice triggers diabetes-mimicking transcriptional signatures and highly penetrant, hyperglycemia-independent dedifferentiation, indicating that PRC2 dysregulation contributes to disease. The work provides novel resources for exploring β cell transcriptional regulation and identifies PRC2 as necessary for long-term maintenance of β cell identity. Importantly, the data suggest a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes. Lu et al. provide evidence of chromatin dysregulation in type 2 diabetes in mice and humans. Loss of Polycomb silencing in mouse pancreas triggers hyperglycemia-independent dedifferentiation of β cells and diabetes, suggesting a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes.",

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author = "Lu, \{Tess Tsai Hsiu\} and Steffen Heyne and Erez Dror and Eduard Casas and Laura Leonhardt and Thorina Boenke and Yang, \{Chih Hsiang\} and Sagar and Laura Arrigoni and Kevin Dalgaard and Raffaele Teperino and Lennart Enders and Madhan Selvaraj and Marius Ruf and Raja, \{Sunil J.\} and Huafeng Xie and Ulrike Boenisch and Orkin, \{Stuart H.\} and Lynn, \{Francis C.\} and Hoffman, \{Brad G.\} and Dominic Gr{\"u}n and Tanya Vavouri and Lempradl, \{Adelheid M.\} and Pospisilik, \{J. Andrew\}",

note = "Publisher Copyright: {\textcopyright} 2018 The Author(s)",

year = "2018",

month = jun,

day = "5",

doi = "10.1016/j.cmet.2018.04.013",

language = "אנגלית",

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Lu, TTH, Heyne, S, Dror, E, Casas, E, Leonhardt, L, Boenke, T, Yang, CH, Sagar, Arrigoni, L, Dalgaard, K, Teperino, R, Enders, L, Selvaraj, M, Ruf, M, Raja, SJ, Xie, H, Boenisch, U, Orkin, SH, Lynn, FC, Hoffman, BG, Grün, D, Vavouri, T, Lempradl, AM & Pospisilik, JA 2018, 'The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes', Cell Metabolism, vol. 27, no. 6, pp. 1294-1308.e7. https://doi.org/10.1016/j.cmet.2018.04.013

TY - JOUR

T1 - The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes

AU - Lu, Tess Tsai Hsiu

AU - Heyne, Steffen

AU - Dror, Erez

AU - Casas, Eduard

AU - Leonhardt, Laura

AU - Boenke, Thorina

AU - Yang, Chih Hsiang

AU - Sagar,

AU - Arrigoni, Laura

AU - Dalgaard, Kevin

AU - Teperino, Raffaele

AU - Enders, Lennart

AU - Selvaraj, Madhan

AU - Ruf, Marius

AU - Raja, Sunil J.

AU - Xie, Huafeng

AU - Boenisch, Ulrike

AU - Orkin, Stuart H.

AU - Lynn, Francis C.

AU - Hoffman, Brad G.

AU - Grün, Dominic

AU - Vavouri, Tanya

AU - Lempradl, Adelheid M.

AU - Pospisilik, J. Andrew

PY - 2018/6/5

Y1 - 2018/6/5

N2 - To date, it remains largely unclear to what extent chromatin machinery contributes to the susceptibility and progression of complex diseases. Here, we combine deep epigenome mapping with single-cell transcriptomics to mine for evidence of chromatin dysregulation in type 2 diabetes. We find two chromatin-state signatures that track β cell dysfunction in mice and humans: ectopic activation of bivalent Polycomb-silenced domains and loss of expression at an epigenomically unique class of lineage-defining genes. β cell-specific Polycomb (Eed/PRC2) loss of function in mice triggers diabetes-mimicking transcriptional signatures and highly penetrant, hyperglycemia-independent dedifferentiation, indicating that PRC2 dysregulation contributes to disease. The work provides novel resources for exploring β cell transcriptional regulation and identifies PRC2 as necessary for long-term maintenance of β cell identity. Importantly, the data suggest a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes. Lu et al. provide evidence of chromatin dysregulation in type 2 diabetes in mice and humans. Loss of Polycomb silencing in mouse pancreas triggers hyperglycemia-independent dedifferentiation of β cells and diabetes, suggesting a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes.

AB - To date, it remains largely unclear to what extent chromatin machinery contributes to the susceptibility and progression of complex diseases. Here, we combine deep epigenome mapping with single-cell transcriptomics to mine for evidence of chromatin dysregulation in type 2 diabetes. We find two chromatin-state signatures that track β cell dysfunction in mice and humans: ectopic activation of bivalent Polycomb-silenced domains and loss of expression at an epigenomically unique class of lineage-defining genes. β cell-specific Polycomb (Eed/PRC2) loss of function in mice triggers diabetes-mimicking transcriptional signatures and highly penetrant, hyperglycemia-independent dedifferentiation, indicating that PRC2 dysregulation contributes to disease. The work provides novel resources for exploring β cell transcriptional regulation and identifies PRC2 as necessary for long-term maintenance of β cell identity. Importantly, the data suggest a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes. Lu et al. provide evidence of chromatin dysregulation in type 2 diabetes in mice and humans. Loss of Polycomb silencing in mouse pancreas triggers hyperglycemia-independent dedifferentiation of β cells and diabetes, suggesting a two-hit (chromatin and hyperglycemia) model for loss of β cell identity in diabetes.

KW - Eed

KW - Polycomb

KW - cell identity

KW - chromatin

KW - complex diseases

KW - de-differentiation

KW - diabetes

KW - epigenetic

KW - type 2 diabetes

KW - β cells

UR - https://www.scopus.com/pages/publications/85046683882

U2 - 10.1016/j.cmet.2018.04.013

DO - 10.1016/j.cmet.2018.04.013

M3 - ???researchoutput.researchoutputtypes.contributiontojournal.article???

C2 - 29754954

AN - SCOPUS:85046683882

SN - 1550-4131

VL - 27

SP - 1294-1308.e7

JO - Cell Metabolism

JF - Cell Metabolism

IS - 6

ER -

The Polycomb-Dependent Epigenome Controls β Cell Dysfunction, Dedifferentiation, and Diabetes

Abstract

Bibliographical note

Keywords

UN SDGs

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