Nuclear WRAP53 promotes neuronal survival and functional recovery after stroke.
Irene Sánchez-MoránCristina RodriguezRebeca LapresaJesús AgullaTomás SobrinoJosé CastilloJuan Pedro BolañosÁngeles AlmeidaPublished in: Science advances (2020)
Failure of neurons to efficiently repair DNA double-strand breaks (DSBs) contributes to cerebral damage after stroke. However, the molecular machinery that regulates DNA repair in this neurological disorder is unknown. Here, we found that DSBs in oxygen/glucose-deprived (OGD) neurons spatiotemporally correlated with the up-regulation of WRAP53 (WD40-encoding p53-antisense RNA), which translocated to the nucleus to activate the DSB repair response. Mechanistically, OGD triggered a burst in reactive oxygen species that induced both DSBs and translocation of WRAP53 to the nucleus to promote DNA repair, a pathway that was confirmed in an in vivo mouse model of stroke. Noticeably, nuclear translocation of WRAP53 occurred faster in OGD neurons expressing the Wrap53 human nonsynonymous single-nucleotide polymorphism (SNP) rs2287499 (c.202C>G). Patients carrying this SNP showed less infarct volume and better functional outcome after stroke. These results indicate that WRAP53 fosters DNA repair and neuronal survival to promote functional recovery after stroke.
Keyphrases
- dna repair
- dna damage
- dna damage response
- spinal cord
- mouse model
- cerebral ischemia
- reactive oxygen species
- end stage renal disease
- genome wide
- oxidative stress
- newly diagnosed
- ejection fraction
- chronic kidney disease
- single molecule
- atrial fibrillation
- acute myocardial infarction
- high glucose
- coronary artery disease
- cell free
- prognostic factors
- adipose tissue
- patient reported outcomes
- spinal cord injury
- gene expression
- high density
- brain injury
- blood pressure
- genetic diversity
- left ventricular