Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo

Ralf Gilsbach; Martin Schwaderer; Sebastian Preissl; Björn A. Grüning; David Kranzhöfer; Pedro Schneider; Thomas G. Nührenberg; Sonia Mulero-Navarro; Dieter Weichenhan; Christian Braun; Martina Dreßen; Adam R. Jacobs; Harald Lahm; Torsten Doenst; Rolf Backofen; Markus Krane; Bruce D. Gelb; Lutz Hein

doi:10.1038/s41467-017-02762-z

Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo

Ralf Gilsbach
, Martin Schwaderer
, Sebastian Preissl
, Björn A. Grüning
, David Kranzhöfer
, Pedro Schneider
, Thomas G. Nührenberg
, Sonia Mulero-Navarro
, Dieter Weichenhan
, Christian Braun
, Martina Dreßen
, Adam R. Jacobs
, Harald Lahm
, Torsten Doenst
, Rolf Backofen
, Markus Krane
, Bruce D. Gelb
, Lutz Hein

Clinic for Heart and Vascular Surgery

University Medical Center
University of Freiburg
University Heart Center Freiburg
Mount Sinai School of Medicine
German Cancer Research Center
University of Munich
Technical University of Munich
University Heart Center
Partner Site Munich Heart Alliance

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

197 Scopus citations

Abstract

Epigenetic mechanisms and transcription factor networks essential for differentiation of cardiac myocytes have been uncovered. However, reshaping of the epigenome of these terminally differentiated cells during fetal development, postnatal maturation, and in disease remains unknown. Here, we investigate the dynamics of the cardiac myocyte epigenome during development and in chronic heart failure. We find that prenatal development and postnatal maturation are characterized by a cooperation of active CpG methylation and histone marks at cis-regulatory and genic regions to shape the cardiac myocyte transcriptome. In contrast, pathological gene expression in terminal heart failure is accompanied by changes in active histone marks without major alterations in CpG methylation and repressive chromatin marks. Notably, cis-regulatory regions in cardiac myocytes are significantly enriched for cardiovascular disease-associated variants. This study uncovers distinct layers of epigenetic regulation not only during prenatal development and postnatal maturation but also in diseased human cardiac myocytes.

Original language	English
Article number	391
Journal	Nature Communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-017-02762-z
State	Published - 1 Dec 2018

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Gilsbach, R., Schwaderer, M., Preissl, S., Grüning, B. A., Kranzhöfer, D., Schneider, P., Nührenberg, T. G., Mulero-Navarro, S., Weichenhan, D., Braun, C., Dreßen, M., Jacobs, A. R., Lahm, H., Doenst, T., Backofen, R., Krane, M., Gelb, B. D., & Hein, L. (2018). Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo. Nature Communications, 9(1), Article 391. https://doi.org/10.1038/s41467-017-02762-z

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title = "Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo",

abstract = "Epigenetic mechanisms and transcription factor networks essential for differentiation of cardiac myocytes have been uncovered. However, reshaping of the epigenome of these terminally differentiated cells during fetal development, postnatal maturation, and in disease remains unknown. Here, we investigate the dynamics of the cardiac myocyte epigenome during development and in chronic heart failure. We find that prenatal development and postnatal maturation are characterized by a cooperation of active CpG methylation and histone marks at cis-regulatory and genic regions to shape the cardiac myocyte transcriptome. In contrast, pathological gene expression in terminal heart failure is accompanied by changes in active histone marks without major alterations in CpG methylation and repressive chromatin marks. Notably, cis-regulatory regions in cardiac myocytes are significantly enriched for cardiovascular disease-associated variants. This study uncovers distinct layers of epigenetic regulation not only during prenatal development and postnatal maturation but also in diseased human cardiac myocytes.",

author = "Ralf Gilsbach and Martin Schwaderer and Sebastian Preissl and Gr{\"u}ning, \{Bj{\"o}rn A.\} and David Kranzh{\"o}fer and Pedro Schneider and N{\"u}hrenberg, \{Thomas G.\} and Sonia Mulero-Navarro and Dieter Weichenhan and Christian Braun and Martina Dre{\ss}en and Jacobs, \{Adam R.\} and Harald Lahm and Torsten Doenst and Rolf Backofen and Markus Krane and Gelb, \{Bruce D.\} and Lutz Hein",

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Gilsbach, R, Schwaderer, M, Preissl, S, Grüning, BA, Kranzhöfer, D, Schneider, P, Nührenberg, TG, Mulero-Navarro, S, Weichenhan, D, Braun, C, Dreßen, M, Jacobs, AR, Lahm, H, Doenst, T, Backofen, R, Krane, M, Gelb, BD & Hein, L 2018, 'Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo', Nature Communications, vol. 9, no. 1, 391. https://doi.org/10.1038/s41467-017-02762-z

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T1 - Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo

AU - Gilsbach, Ralf

AU - Schwaderer, Martin

AU - Preissl, Sebastian

AU - Grüning, Björn A.

AU - Kranzhöfer, David

AU - Schneider, Pedro

AU - Nührenberg, Thomas G.

AU - Mulero-Navarro, Sonia

AU - Weichenhan, Dieter

AU - Braun, Christian

AU - Dreßen, Martina

AU - Jacobs, Adam R.

AU - Lahm, Harald

AU - Doenst, Torsten

AU - Backofen, Rolf

AU - Krane, Markus

AU - Gelb, Bruce D.

AU - Hein, Lutz

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N2 - Epigenetic mechanisms and transcription factor networks essential for differentiation of cardiac myocytes have been uncovered. However, reshaping of the epigenome of these terminally differentiated cells during fetal development, postnatal maturation, and in disease remains unknown. Here, we investigate the dynamics of the cardiac myocyte epigenome during development and in chronic heart failure. We find that prenatal development and postnatal maturation are characterized by a cooperation of active CpG methylation and histone marks at cis-regulatory and genic regions to shape the cardiac myocyte transcriptome. In contrast, pathological gene expression in terminal heart failure is accompanied by changes in active histone marks without major alterations in CpG methylation and repressive chromatin marks. Notably, cis-regulatory regions in cardiac myocytes are significantly enriched for cardiovascular disease-associated variants. This study uncovers distinct layers of epigenetic regulation not only during prenatal development and postnatal maturation but also in diseased human cardiac myocytes.

AB - Epigenetic mechanisms and transcription factor networks essential for differentiation of cardiac myocytes have been uncovered. However, reshaping of the epigenome of these terminally differentiated cells during fetal development, postnatal maturation, and in disease remains unknown. Here, we investigate the dynamics of the cardiac myocyte epigenome during development and in chronic heart failure. We find that prenatal development and postnatal maturation are characterized by a cooperation of active CpG methylation and histone marks at cis-regulatory and genic regions to shape the cardiac myocyte transcriptome. In contrast, pathological gene expression in terminal heart failure is accompanied by changes in active histone marks without major alterations in CpG methylation and repressive chromatin marks. Notably, cis-regulatory regions in cardiac myocytes are significantly enriched for cardiovascular disease-associated variants. This study uncovers distinct layers of epigenetic regulation not only during prenatal development and postnatal maturation but also in diseased human cardiac myocytes.

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Distinct epigenetic programs regulate cardiac myocyte development and disease in the human heart in vivo

Abstract

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