Abstract
Duplication and transmission of chromosomes require precise control of chromosome replication and segregation. Here we present evidence that RecG is a major factor influencing these processes in bacteria. We show that the extensive DnaA-independent stable DNA replication observed without RecG can lead to replication of any area of the chromosome. This replication is further elevated following irradiation with UV light and appears to be perpetuated by secondary events that continue long after the elimination of UV lesions. The resulting pathological cascade is associated with an increased number of replication forks traversing the chromosome, sometimes with extensive regional amplification of the chromosome, and with the accumulation of highly branched DNA intermediates containing few Holliday junctions. We propose that the cascade is triggered by replication fork collisions that generate 3′ single-strand DNA flaps, providing sites for PriA to initiate re-replication of the DNA and thus to generate linear duplexes that provoke recombination, allowing priming of even further replication. Our results shed light on why termination of replication in bacteria is normally limited to a single encounter of two forks and carefully orchestrated within a restricted area, and explain how a system of multiple forks and random termination can operate in eukaryotes.
Highlights
Duplication and transmission of the genome are major challenges for dividing cells
To gain further insight into the nature of the stable DNA replication (SDR) induced by UV-irradiation, and that elevated constitutively in cells lacking RecG, we investigated whether it can extend DNA synthesis to any area of the chromosome
Exponential phase cells were shifted from 30°C to 42°C to eliminate further oriC firing and the rate of subsequent DNA synthesis monitored by pulse labelling with BrdU, with or without prior UV-irradiation
Summary
Duplication and transmission of the genome are major challenges for dividing cells. Studies with numerousBacteria have evolved systems that tend to bring replication to a halt within a restricted region of the chromosome. If one of the forks becomes blocked and fails to be rescued, the remaining portion of the replichore will not be duplicated in time as the second fork will be trapped in the terminus area (Sharma and Hill, 1995). This constraint imposed by Tus-ter may explain why mechanisms promoting fork rescue and replication restart appear to be so important for bacteria (McGlynn and Lloyd, 2002; Heller and Marians, 2006)
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