Project description:In response to DNA replication stress, DNA replication checkpoint is activated to maintain fork stability, a process critical for maintenance of genome stability. However, how DNA replication checkpoint regulates replication forks remain elusive. Here we show that Rad53, a highly conserved replication checkpoint kinase, functions to couple leading and lagging strand DNA synthesis. In wild type cells under HU induced replication stress, synthesis of lagging strand, which contains ssDNA gaps, is comparable to leading strand DNA. In contrast, synthesis of lagging strand is much more than leading strand, and consequently, leading template ssDNA coated with ssDNA binding protein RPA was detected in rad53-1 mutant cells, suggesting that synthesis of leading strand and lagging strand DNA is uncoupled. Mechanistically, we show that replicative helicase MCM and leading strand DNA polymerase Pole move beyond actual DNA synthesis and that an increase in dNTP pools largely suppresses the uncoupled leading and lagging strand DNA synthesis. Our studies reveal an unexpected mechanism whereby Rad53 regulates replication fork stability.

Project description:Here we show that the asymmetric DNA synthesis is also observed in mec1-100 and mrc1-AQ cells defective in replication checkpoint, but surprisingly, not in mrc1∆ cells in which both DNA replication and checkpoint functions of Mrc1 are missing. Furthermore, depletion of Mrc1 or its partner in DNA replication, Tof1, suppresses the asymmetric DNA synthesis in rad53-1 mutant cells.

Project description:DNA replication fidelity is essential for maintaining genetic stability. Forks arrested at replication fork barriers can be stabilised by the intra-S phase checkpoint, subsequently being rescued by a converging fork, or resuming when the barrier is removed. However, some arrested forks cannot be stabilised and fork convergence cannot rescue in all situations. Thus, cells have developed homologous recombination-dependent mechanisms to restart persistently inactive forks. To understand the dynamics of HR-restart, we visualized in vivo replication dynamics at an S. pombe replication barrier, RTS1, using polymerase usage sequencing and model replication dynamics by Monte Carlo simulation. We confirm that HR-restarted forks synthesise both strands with Pol d and that Pol a is not used significantly on either strand: the lagging strand template remains as a gap that is filled in later. We further demonstrate that HR-restarted forks progress for >30 kb kilobases without maturing to a d/e configuration and can progress through a fork barrier that arrests canonical forks. Finally, by manipulating lagging strand resection during HR-restart by deleting pku70, we show that the leading strand initiates replication at the same position, demonstrating the stability of the 3' single strand in the context of increased resection.

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