Acute hydroxyurea-induced replication blockade results in replisome components disengagement from nascent DNA without causing fork collapse.
Amaia ErcillaSonia FeuSergi ArandaAlba LlopisSólveig Hlín BrynjólfsdóttirClaus Storgaard SørensenLuis Ignacio ToledoNeus AgellPublished in: Cellular and molecular life sciences : CMLS (2019)
During S phase, replication forks can encounter several obstacles that lead to fork stalling, which if persistent might result in fork collapse. To avoid this collapse and to preserve the competence to restart, cells have developed mechanisms that maintain fork stability upon replication stress. In this study, we aimed to understand the mechanisms involved in fork stability maintenance in non-transformed human cells by performing an isolation of proteins on nascent DNA-mass spectrometry analysis in hTERT-RPE cells under different replication stress conditions. Our results show that acute hydroxyurea-induced replication blockade causes the accumulation of large amounts of single-stranded DNA at the fork. Remarkably, this results in the disengagement of replisome components from nascent DNA without compromising fork restart. Notably, Cdc45-MCM-GINS helicase maintains its integrity and replisome components remain associated with chromatin upon acute hydroxyurea treatment, whereas replisome stability is lost upon a sustained replication stress that compromises the competence to restart.
Keyphrases
- circulating tumor
- liver failure
- drug induced
- induced apoptosis
- cell free
- single molecule
- respiratory failure
- mass spectrometry
- cell cycle arrest
- nucleic acid
- high glucose
- sickle cell disease
- gene expression
- dna damage
- diabetic rats
- stress induced
- liquid chromatography
- endoplasmic reticulum stress
- signaling pathway
- dna methylation
- intensive care unit
- high resolution
- simultaneous determination
- acute respiratory distress syndrome