DNA repair in cardiomyocytes is critical for maintaining cardiac function in mice.
Martine de BoerMaaike Te Lintel HekkertJiang ChangBibi S van ThielLeonie MartensMaxime M BosMarion G J de KleijnenYanto RidwanYanti OctaviaElza D van DeelLau A BlondenRenata M C BrandtSander BarnhoornPaula K Bautista-NiñoIlona Krabbendam-PetersRianne WolswinkelBanafsheh ArshiMohsen GhanbariChristian KupattLeon J de WindtA H Jan DanserIngrid van der PluijmCarol Ann RemmeMonika StollJoris PothofAnton J M RoksMaryam KavousiJeroen EssersJolanda van der VeldenJan H J HoeijmakersDirk Jan DunckerPublished in: Aging cell (2023)
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.
Keyphrases
- dna repair
- dna damage
- heart failure
- oxidative stress
- early onset
- left ventricular
- late onset
- dna damage response
- cardiac resynchronization therapy
- ischemia reperfusion injury
- acute heart failure
- atrial fibrillation
- endoplasmic reticulum stress
- diabetic rats
- wild type
- endothelial cells
- high glucose
- induced apoptosis
- type diabetes
- copy number
- high fat diet induced
- genome wide
- transcription factor
- cell cycle arrest
- angiotensin ii
- adipose tissue
- risk factors
- dna methylation
- big data
- ultrasound guided
- skeletal muscle
- liver fibrosis
- drug induced
- artificial intelligence
- genome wide identification
- pluripotent stem cells
- deep learning