DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice

Martine de Boer; Maaike te Lintel Hekkert; Jiang Chang; Bibi S. van Thiel; Leonie Martens; Maxime M. Bos; Marion G. J. de Kleijnen; Yanto Ridwan; Yanti Octavia; Elza D. van Deel; Lau A. Blonden; Renata M. C. Brandt; Sander Barnhoorn; Paula K. Bautista-Niño; Ilona Krabbendam-Peters; Rianne Wolswinkel; Banafsheh Arshi; Mohsen Ghanbari; Christian Kupatt; Leon J. de Windt; A. H. Jan Danser; Ingrid van der Pluijm; Carol Ann Remme; Monika Stoll; Joris Pothof; Anton J. M. Roks; Maryam Kavousi; Jeroen Essers; Jolanda van der Velden; Jan H. J. Hoeijmakers; Dirk J. Duncker

doi:https://doi.org/10.1111/acel.13768

DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice

Martine de Boer, Maaike te Lintel Hekkert, Jiang Chang, Bibi S. van Thiel, Leonie Martens, Maxime M. Bos, Marion G. J. de Kleijnen, Yanto Ridwan, Yanti Octavia, Elza D. van Deel, Lau A. Blonden, Renata M. C. Brandt, Sander Barnhoorn, Paula K. Bautista-Niño, Ilona Krabbendam-Peters, Rianne Wolswinkel, Banafsheh Arshi, Mohsen Ghanbari, Christian Kupatt, Leon J. de WindtA. H. Jan Danser, Ingrid van der Pluijm, Carol Ann Remme, Monika Stoll, Joris Pothof, Anton J. M. Roks, Maryam Kavousi, Jeroen Essers, Jolanda van der Velden, Jan H. J. Hoeijmakers, Dirk J. Duncker

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

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Abstract

Heart failure has reached epidemic proportions in a progressively ageing population. The molecular mechanisms underlying heart failure remain elusive, but evidence indicates that DNA damage is enhanced in failing hearts. Here, we tested the hypothesis that endogenous DNA repair in cardiomyocytes is critical for maintaining normal cardiac function, so that perturbed repair of spontaneous DNA damage drives early onset of heart failure. To increase the burden of spontaneous DNA damage, we knocked out the DNA repair endonucleases xeroderma pigmentosum complementation group G (XPG) and excision repair cross-complementation group 1 (ERCC1), either systemically or cardiomyocyte-restricted, and studied the effects on cardiac function and structure. Loss of DNA repair permitted normal heart development but subsequently caused progressive deterioration of cardiac function, resulting in overt congestive heart failure and premature death within 6 months. Cardiac biopsies revealed increased oxidative stress associated with increased fibrosis and apoptosis. Moreover, gene set enrichment analysis showed enrichment of pathways associated with impaired DNA repair and apoptosis, and identified TP53 as one of the top active upstream transcription regulators. In support of the observed cardiac phenotype in mutant mice, several genetic variants in the ERCC1 and XPG gene in human GWAS data were found to be associated with cardiac remodelling and dysfunction. In conclusion, unrepaired spontaneous DNA damage in differentiated cardiomyocytes drives early onset of cardiac failure. These observations implicate DNA damage as a potential novel therapeutic target and highlight systemic and cardiomyocyte-restricted DNA repair-deficient mouse mutants as bona fide models of heart failure.

Original language	English
Article number	e13768
Journal	Aging cell
Volume	22
Issue number	3
Early online date	2023
DOIs	https://doi.org/10.1111/acel.13768
Publication status	Published - 1 Mar 2023

Keywords

DNA damage
DNA repair
apoptosis
cardiac function
congestive heart failure

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https://doi.org/10.1111/acel.13768

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de Boer, M., te Lintel Hekkert, M., Chang, J., van Thiel, B. S., Martens, L., Bos, M. M., de Kleijnen, M. G. J., Ridwan, Y., Octavia, Y., van Deel, E. D., Blonden, L. A., Brandt, R. M. C., Barnhoorn, S., Bautista-Niño, P. K., Krabbendam-Peters, I., Wolswinkel, R., Arshi, B., Ghanbari, M., Kupatt, C., ... Duncker, D. J. (2023). DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice. Aging cell, 22(3), Article e13768. https://doi.org/10.1111/acel.13768

@article{183e06ae164b42f88d59c5f1121b1af1,

title = "DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice",

abstract = "Heart failure has reached epidemic proportions in a progressively ageing population. The molecular mechanisms underlying heart failure remain elusive, but evidence indicates that DNA damage is enhanced in failing hearts. Here, we tested the hypothesis that endogenous DNA repair in cardiomyocytes is critical for maintaining normal cardiac function, so that perturbed repair of spontaneous DNA damage drives early onset of heart failure. To increase the burden of spontaneous DNA damage, we knocked out the DNA repair endonucleases xeroderma pigmentosum complementation group G (XPG) and excision repair cross-complementation group 1 (ERCC1), either systemically or cardiomyocyte-restricted, and studied the effects on cardiac function and structure. Loss of DNA repair permitted normal heart development but subsequently caused progressive deterioration of cardiac function, resulting in overt congestive heart failure and premature death within 6 months. Cardiac biopsies revealed increased oxidative stress associated with increased fibrosis and apoptosis. Moreover, gene set enrichment analysis showed enrichment of pathways associated with impaired DNA repair and apoptosis, and identified TP53 as one of the top active upstream transcription regulators. In support of the observed cardiac phenotype in mutant mice, several genetic variants in the ERCC1 and XPG gene in human GWAS data were found to be associated with cardiac remodelling and dysfunction. In conclusion, unrepaired spontaneous DNA damage in differentiated cardiomyocytes drives early onset of cardiac failure. These observations implicate DNA damage as a potential novel therapeutic target and highlight systemic and cardiomyocyte-restricted DNA repair-deficient mouse mutants as bona fide models of heart failure.",

keywords = "DNA damage, DNA repair, apoptosis, cardiac function, congestive heart failure",

author = "{de Boer}, Martine and {te Lintel Hekkert}, Maaike and Jiang Chang and {van Thiel}, {Bibi S.} and Leonie Martens and Bos, {Maxime M.} and {de Kleijnen}, {Marion G. J.} and Yanto Ridwan and Yanti Octavia and {van Deel}, {Elza D.} and Blonden, {Lau A.} and Brandt, {Renata M. C.} and Sander Barnhoorn and Bautista-Ni{\~n}o, {Paula K.} and Ilona Krabbendam-Peters and Rianne Wolswinkel and Banafsheh Arshi and Mohsen Ghanbari and Christian Kupatt and {de Windt}, {Leon J.} and Danser, {A. H. Jan} and {van der Pluijm}, Ingrid and Carol Ann Remme and Monika Stoll and Joris Pothof and Roks, {Anton J. M.} and Maryam Kavousi and Jeroen Essers and {van der Velden}, Jolanda and Hoeijmakers, {Jan H. J.} and Duncker, {Dirk J.}",

note = "Funding Information: Alpha-MHC-Cre mice were kindly provided by Johannes Backs (University of Heidelberg, Heidelberg, Germany); floxed Ercc1 mice were kindly provided by David W. Melton (MRC Institute of Genetics and Molecular Medicine, University of Edinburgh, MRC Human Genetics Unit, Western General Hospital, Crewe Road, Edinburgh EH4 2XU, UK). Molecular imaging was enabled by the use of imaging equipment provided by the Applied Molecular Imaging Erasmus MC facility. We gratefully acknowledge Hans Bosch for the use of the Vevo770 High-Resolution Imaging System (FUJIFILM VisualSonics Inc.), the Core Facility Genomics of the Medical Faculty M{\"u}nster for performing RNA sequencing and Robert Beurskens, Wies Lommen, Ruud Zaremba, Jennifer Sarikaya and Rene de Vries for their expert technical support. Funding Information: This work was supported by the Dutch CardioVascular Alliance: An initiative with financial support of the Dutch Heart Foundation [Grants 2017B018‐ARENA‐PRIME (to L.J.W., J.V. and D.J.D.), 2018B030‐PREDICT2 (to C.A.R.) and 2021B008‐RECONNEXT (to D.J.D.)], Lijf en leven [Grant DIVERS (to J.E.)], National Institute of Health (NIH)/National Institute of Ageing (NIA) [Grant PO1 AG017242 (to J.H.J.H. and J.P.)], European Research Council Advanced Grants [Grants DamAge (to J.H.J.H.) and Dam2Age (to J.H.J.H.)], Dutch Cancer Society [Grant ONCODE (to J.H.J.H.)], Memorabel and Chembridge (ZonMW; to J.H.J.H. and J.P), BBoL (NWO‐ENW; to J.H.J.H.) and the Deutsche Forschungsgemeinschaft [Grant SFB 829 (to J.H.J.H.). Publisher Copyright: {\textcopyright} 2023 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.",

year = "2023",

month = mar,

day = "1",

doi = "https://doi.org/10.1111/acel.13768",

language = "English",

volume = "22",

journal = "Aging cell",

issn = "1474-9718",

publisher = "Wiley-Blackwell",

number = "3",

}

de Boer, M, te Lintel Hekkert, M, Chang, J, van Thiel, BS, Martens, L, Bos, MM, de Kleijnen, MGJ, Ridwan, Y, Octavia, Y, van Deel, ED, Blonden, LA, Brandt, RMC, Barnhoorn, S, Bautista-Niño, PK, Krabbendam-Peters, I, Wolswinkel, R, Arshi, B, Ghanbari, M, Kupatt, C, de Windt, LJ, Danser, AHJ, van der Pluijm, I, Remme, CA, Stoll, M, Pothof, J, Roks, AJM, Kavousi, M, Essers, J, van der Velden, J, Hoeijmakers, JHJ & Duncker, DJ 2023, 'DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice', Aging cell, vol. 22, no. 3, e13768. https://doi.org/10.1111/acel.13768

TY - JOUR

T1 - DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice

AU - de Boer, Martine

AU - te Lintel Hekkert, Maaike

AU - Chang, Jiang

AU - van Thiel, Bibi S.

AU - Martens, Leonie

AU - Bos, Maxime M.

AU - de Kleijnen, Marion G. J.

AU - Ridwan, Yanto

AU - Octavia, Yanti

AU - van Deel, Elza D.

AU - Blonden, Lau A.

AU - Brandt, Renata M. C.

AU - Barnhoorn, Sander

AU - Bautista-Niño, Paula K.

AU - Krabbendam-Peters, Ilona

AU - Wolswinkel, Rianne

AU - Arshi, Banafsheh

AU - Ghanbari, Mohsen

AU - Kupatt, Christian

AU - de Windt, Leon J.

AU - Danser, A. H. Jan

AU - van der Pluijm, Ingrid

AU - Remme, Carol Ann

AU - Stoll, Monika

AU - Pothof, Joris

AU - Roks, Anton J. M.

AU - Kavousi, Maryam

AU - Essers, Jeroen

AU - van der Velden, Jolanda

AU - Hoeijmakers, Jan H. J.

AU - Duncker, Dirk J.

N1 - Funding Information: Alpha-MHC-Cre mice were kindly provided by Johannes Backs (University of Heidelberg, Heidelberg, Germany); floxed Ercc1 mice were kindly provided by David W. Melton (MRC Institute of Genetics and Molecular Medicine, University of Edinburgh, MRC Human Genetics Unit, Western General Hospital, Crewe Road, Edinburgh EH4 2XU, UK). Molecular imaging was enabled by the use of imaging equipment provided by the Applied Molecular Imaging Erasmus MC facility. We gratefully acknowledge Hans Bosch for the use of the Vevo770 High-Resolution Imaging System (FUJIFILM VisualSonics Inc.), the Core Facility Genomics of the Medical Faculty Münster for performing RNA sequencing and Robert Beurskens, Wies Lommen, Ruud Zaremba, Jennifer Sarikaya and Rene de Vries for their expert technical support. Funding Information: This work was supported by the Dutch CardioVascular Alliance: An initiative with financial support of the Dutch Heart Foundation [Grants 2017B018‐ARENA‐PRIME (to L.J.W., J.V. and D.J.D.), 2018B030‐PREDICT2 (to C.A.R.) and 2021B008‐RECONNEXT (to D.J.D.)], Lijf en leven [Grant DIVERS (to J.E.)], National Institute of Health (NIH)/National Institute of Ageing (NIA) [Grant PO1 AG017242 (to J.H.J.H. and J.P.)], European Research Council Advanced Grants [Grants DamAge (to J.H.J.H.) and Dam2Age (to J.H.J.H.)], Dutch Cancer Society [Grant ONCODE (to J.H.J.H.)], Memorabel and Chembridge (ZonMW; to J.H.J.H. and J.P), BBoL (NWO‐ENW; to J.H.J.H.) and the Deutsche Forschungsgemeinschaft [Grant SFB 829 (to J.H.J.H.). Publisher Copyright: © 2023 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.

PY - 2023/3/1

Y1 - 2023/3/1

N2 - Heart failure has reached epidemic proportions in a progressively ageing population. The molecular mechanisms underlying heart failure remain elusive, but evidence indicates that DNA damage is enhanced in failing hearts. Here, we tested the hypothesis that endogenous DNA repair in cardiomyocytes is critical for maintaining normal cardiac function, so that perturbed repair of spontaneous DNA damage drives early onset of heart failure. To increase the burden of spontaneous DNA damage, we knocked out the DNA repair endonucleases xeroderma pigmentosum complementation group G (XPG) and excision repair cross-complementation group 1 (ERCC1), either systemically or cardiomyocyte-restricted, and studied the effects on cardiac function and structure. Loss of DNA repair permitted normal heart development but subsequently caused progressive deterioration of cardiac function, resulting in overt congestive heart failure and premature death within 6 months. Cardiac biopsies revealed increased oxidative stress associated with increased fibrosis and apoptosis. Moreover, gene set enrichment analysis showed enrichment of pathways associated with impaired DNA repair and apoptosis, and identified TP53 as one of the top active upstream transcription regulators. In support of the observed cardiac phenotype in mutant mice, several genetic variants in the ERCC1 and XPG gene in human GWAS data were found to be associated with cardiac remodelling and dysfunction. In conclusion, unrepaired spontaneous DNA damage in differentiated cardiomyocytes drives early onset of cardiac failure. These observations implicate DNA damage as a potential novel therapeutic target and highlight systemic and cardiomyocyte-restricted DNA repair-deficient mouse mutants as bona fide models of heart failure.

AB - Heart failure has reached epidemic proportions in a progressively ageing population. The molecular mechanisms underlying heart failure remain elusive, but evidence indicates that DNA damage is enhanced in failing hearts. Here, we tested the hypothesis that endogenous DNA repair in cardiomyocytes is critical for maintaining normal cardiac function, so that perturbed repair of spontaneous DNA damage drives early onset of heart failure. To increase the burden of spontaneous DNA damage, we knocked out the DNA repair endonucleases xeroderma pigmentosum complementation group G (XPG) and excision repair cross-complementation group 1 (ERCC1), either systemically or cardiomyocyte-restricted, and studied the effects on cardiac function and structure. Loss of DNA repair permitted normal heart development but subsequently caused progressive deterioration of cardiac function, resulting in overt congestive heart failure and premature death within 6 months. Cardiac biopsies revealed increased oxidative stress associated with increased fibrosis and apoptosis. Moreover, gene set enrichment analysis showed enrichment of pathways associated with impaired DNA repair and apoptosis, and identified TP53 as one of the top active upstream transcription regulators. In support of the observed cardiac phenotype in mutant mice, several genetic variants in the ERCC1 and XPG gene in human GWAS data were found to be associated with cardiac remodelling and dysfunction. In conclusion, unrepaired spontaneous DNA damage in differentiated cardiomyocytes drives early onset of cardiac failure. These observations implicate DNA damage as a potential novel therapeutic target and highlight systemic and cardiomyocyte-restricted DNA repair-deficient mouse mutants as bona fide models of heart failure.

KW - DNA damage

KW - DNA repair

KW - apoptosis

KW - cardiac function

KW - congestive heart failure

UR - http://www.scopus.com/inward/record.url?scp=85147438378&partnerID=8YFLogxK

U2 - https://doi.org/10.1111/acel.13768

DO - https://doi.org/10.1111/acel.13768

M3 - Article

C2 - 36756698

SN - 1474-9718

VL - 22

JO - Aging cell

JF - Aging cell

IS - 3

M1 - e13768

ER -

DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice

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Keywords

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