Polymerase δ replicates both strands after homologous recombination-dependent fork restart.

To maintain genetic stability, DNA must be replicated only once per cell cycle, and replication must be completed even when individual replication forks are inactivated. Because fork inactivation is common, passive convergence of an adjacent fork is insufficient to rescue all inactive forks. Thus, eukaryotic cells have evolved homologous recombination-dependent mechanisms to restart persistent inactive forks. Completing DNA synthesis via homologous recombination-restarted replication (HoRReR) ensures cell survival, but at a cost. One such cost is increased mutagenesis because HoRReR is more error prone than canonical replication. This increased error rate implies the HoRReR mechanism is distinct from that of a canonical fork. Here we demonstrate, in Schizosaccharomyces pombe, that a DNA sequence duplicated by HoRReR during S phase is replicated semiconservatively, but both the leading and lagging strands are synthesized by DNA polymerase δ.

Analyzing the Response to Dysfunction Replication Forks Using the RTS1 Barrier System in Fission Yeast.

The study of how eukaryotic cells overcome problems associated with dysfunctional DNA replication forks is assisted by experimental systems that allow site-specific replication fork arrest. Here we provide protocols for the use of the fission yeast RTS1 replication fork barrier. The RTS1 barrier is a directional, or polar, replication fork barrier that evolved to ensure directional replication of the fission yeast mating-type locus. We have moved the 859 bp RTS1 sequence to another locus in the genome and demonstrated that it arrests replication forks in a dysfunctional confirmation and that replication is restarted within ~20 min by the action of homologous recombination. We describe here the barrier constructs currently available, the methods by which we regulate the activity of the barrier, how to synchronize cells for analysis of replication intermediates by 2D gel electrophoresis, and the use of a replication slippage assay to measure fork fidelity.

Checkpoints are blind to replication restart and recombination intermediates that result in gross chromosomal rearrangements.

Replication fork inactivation can be overcome by homologous recombination, but this can cause gross chromosomal rearrangements that subsequently missegregate at mitosis, driving further chromosome instability. It is unclear when the chromosome rearrangements are generated and whether individual replication problems or the resulting recombination intermediates delay the cell cycle. Here we have investigated checkpoint activation during HR-dependent replication restart using a site-specific replication fork-arrest system. Analysis during a single cell cycle shows that HR-dependent replication intermediates arise in S phase, shortly after replication arrest, and are resolved into acentric and dicentric chromosomes in G2. Despite this, cells progress into mitosis without delay. Neither the DNA damage nor the intra-S phase checkpoints are activated in the first cell cycle, demonstrating that these checkpoints are blind to replication and recombination intermediates as well as to rearranged chromosomes. The dicentrics form anaphase bridges that subsequently break, inducing checkpoint activation in the second cell cycle.

Optimisation of the Schizosaccharomyces pombe urg1 expression system.

The ability to study protein function in vivo often relies on systems that regulate the presence and absence of the protein of interest. Two limitations for previously described transcriptional control systems that are used to regulate protein expression in fission yeast are: the time taken for inducing conditions to initiate transcription and the ability to achieve very low basal transcription in the "OFF-state". In previous work, we described a Cre recombination-mediated system that allows the rapid and efficient regulation of any gene of interest by the urg1 promoter, which has a dynamic range of approximately 75-fold and which is induced within 30-60 minutes of uracil addition. In this report we describe easy-to-use and versatile modules that can be exploited to significantly tune down Purg1 "OFF-levels" while maintaining an equivalent dynamic range. We also provide plasmids and tools for combining Purg1 transcriptional control with the auxin degron tag to help maintain a null-like phenotype. We demonstrate the utility of this system by improved regulation of HO-dependent site-specific DSB formation, by the regulation Rtf1-dependent replication fork arrest and by controlling Rhp18(Rad18)-dependent post replication repair.