SSRP1-mediated histone H1 eviction promotes replication origin assembly and accelerated development.

In several metazoans, the number of active replication origins in embryonic nuclei is higher than in somatic ones, ensuring rapid genome duplication during synchronous embryonic cell divisions. High replication origin density can be restored by somatic nuclear reprogramming. However, mechanisms underlying high replication origin density formation coupled to rapid cell cycles are poorly understood. Here, using Xenopus laevis, we show that SSRP1 stimulates replication origin assembly on somatic chromatin by promoting eviction of histone H1 through its N-terminal domain. Histone H1 removal derepresses ORC and MCM chromatin binding, allowing efficient replication origin assembly. SSRP1 protein decays at mid-blastula transition (MBT) when asynchronous somatic cell cycles start. Increasing levels of SSRP1 delay MBT and, surprisingly, accelerate post-MBT cell cycle speed and embryo development. These findings identify a major epigenetic mechanism regulating DNA replication and directly linking replication origin assembly, cell cycle duration and embryo development in vertebrates.

Replicon dynamics, dormant origin firing, and terminal fork integrity after double-strand break formation.

In response to replication stress, the Mec1/ATR and SUMO pathways control stalled- and damaged-fork stability. We investigated the S phase response at forks encountering a broken template (termed the terminal fork). We show that double-strand break (DSB) formation can locally trigger dormant origin firing. Irreversible fork resolution at the break does not impede progression of the other fork in the same replicon (termed the sister fork). The Mre11-Tel1/ATM response acts at terminal forks, preventing accumulation of cruciform DNA intermediates that tether sister chromatids and can undergo nucleolytic processing. We conclude that sister forks can be uncoupled during replication and that, after DSB-induced fork termination, replication is rescued by dormant origin firing or adjacent replicons. We have uncovered a Tel1/ATM- and Mre11-dependent response controlling terminal fork integrity. Our findings have implications for those genome instability syndromes that accumulate DNA breaks during S phase and for forks encountering eroding telomeres.

Characterization of the activation domain of the Rad53 checkpoint kinase.

Rad53 protein, the yeast orthologue of the human checkpoint kinase Chk2, presents two highly conserved phosphorylatable threonine residues (T354 and T358) in the activation domain, whose phosphorylation is critical to allow the activation of the kinase. In this study we found that Rad53 protein variants in which alanine and/or aspartate replace the threonine residues 354 and/or 358 do not retain kinase activity and do not undergo auto-phosphorylation, leading to defect in the checkpoint response and iper-sensitivity to DNA damage and DNA replication stress agents. Interestingly, we found that the rad53-T358D mutation severely affects the kinase activity and causes accumulation of the S129-phosphorylated isoform of histone H2A, even during an unperturbed cell cycle, thus indicating the accumulation of spontaneous DNA breaks. We further found that the protein level of Sml1, which is the physiological inhibitor of ribonucleotide reductase, remains high during DNA replication in rad53-T358D cells, suggesting that an inadequate pool of dNTPs in checkpoint defective cells causes the accumulation of spontaneous DNA breaks. In conclusion, our results indicate that phosphorylation of both T354 and T358 residues strongly influences the catalytic activity of Rad53 also in unperturbed cell cycles, and support the notion that Rad53 is essential to preserve genome integrity, by controlling the level of Sml1 and the functionality of ribonucleotide reductase.

DNA end resection, homologous recombination and DNA damage checkpoint activation require CDK1.

A single double-strand break (DSB) induced by HO endonuclease triggers both repair by homologous recombination and activation of the Mec1-dependent DNA damage checkpoint in budding yeast. Here we report that DNA damage checkpoint activation by a DSB requires the cyclin-dependent kinase CDK1 (Cdc28) in budding yeast. CDK1 is also required for DSB-induced homologous recombination at any cell cycle stage. Inhibition of homologous recombination by using an analogue-sensitive CDK1 protein results in a compensatory increase in non-homologous end joining. CDK1 is required for efficient 5' to 3' resection of DSB ends and for the recruitment of both the single-stranded DNA-binding complex, RPA, and the Rad51 recombination protein. In contrast, Mre11 protein, part of the MRX complex, accumulates at unresected DSB ends. CDK1 is not required when the DNA damage checkpoint is initiated by lesions that are processed by nucleotide excision repair. Maintenance of the DSB-induced checkpoint requires continuing CDK1 activity that ensures continuing end resection. CDK1 is also important for a later step in homologous recombination, after strand invasion and before the initiation of new DNA synthesis.