Unlike bacteria, mammalian cells need to complete DNA replication before segregating their chromosomes for the maintenance of genome integrity. Thus, cells have evolved efficient pathways to restore stalled and/or collapsed replication forks during S-phase, and when necessary, also to delay cell cycle progression to ensure replication completion. However, strong evidence shows that cells can proceed to mitosis with incompletely replicated DNA when under mild replication stress (RS) conditions. Consequently, the incompletely replicated genomic gaps form, predominantly at common fragile site regions, where the converging fork-like DNA structures accumulate. These branched structures pose a severe threat to the faithful disjunction of chromosomes as they physically interlink the partially duplicated sister chromatids. In this review, we provide an overview discussing how cells respond and deal with the under-replicated DNA structures that escape from the S/G2 surveillance system. We also focus on recent research of a mitotic break-induced replication pathway (also known as mitotic DNA repair synthesis), which has been proposed to operate during prophase in an attempt to finish DNA synthesis at the under-replicated genomic regions. Finally, we discuss recent data on how mild RS may cause chromosome instability and mutations that accelerate cancer genome evolution.
Keyphrases
- cell cycle
- induced apoptosis
- circulating tumor
- dna repair
- cell cycle arrest
- cell free
- single molecule
- dna damage
- cell proliferation
- high resolution
- oxidative stress
- drug induced
- genome wide
- squamous cell carcinoma
- papillary thyroid
- gene expression
- dna methylation
- circulating tumor cells
- nucleic acid
- cell death
- deep learning
- artificial intelligence
- big data
- heat stress
- diabetic rats
- childhood cancer
- stress induced