Checkpoint independence of most DNA replication origins in fission yeast

Background

In budding yeast, the replication checkpoint slows progress through S phase by inhibiting replication origin firing. In mammals, the replication checkpoint inhibits both origin firing and replication fork movement. To find out which strategy is employed in the fission yeast, Schizosaccharomyces pombe, we used microarrays to investigate the use of origins by wild-type and checkpoint-mutant strains in the presence of hydroxyurea (HU), which limits the pool of deoxyribonucleoside triphosphates (dNTPs) and activates the replication checkpoint. The checkpoint-mutant cells carried deletions either of rad3 (which encodes the fission yeast homologue of ATR) or cds1 (which encodes the fission yeast homologue of Chk2).

Results

Our microarray results proved to be largely consistent with those independently obtained and recently published by three other laboratories. However, we were able to reconcile differences between the previous studies regarding the extent to which fission yeast replication origins are affected by the replication checkpoint. We found (consistent with the three previous studies after appropriate interpretation) that, in surprising contrast to budding yeast, most fission yeast origins, including both early- and late-firing origins, are not significantly affected by checkpoint mutations during replication in the presence of HU. A few origins (~3%) behaved like those in budding yeast: they replicated earlier in the checkpoint mutants than in wild type. These were located primarily in the heterochromatic subtelomeric regions of chromosomes 1 and 2. Indeed, the subtelomeric regions defined by the strongest checkpoint restraint correspond precisely to previously mapped subtelomeric heterochromatin. This observation implies that subtelomeric heterochromatin in fission yeast differs from heterochromatin at centromeres, in the mating type region, and in ribosomal DNA, since these regions replicated at least as efficiently in wild-type cells as in checkpoint-mutant cells.

Conclusion

The fact that ~97% of fission yeast replication origins – both early and late – are not significantly affected by replication checkpoint mutations in HU-treated cells suggests that (i) most late-firing origins are restrained from firing in HU-treated cells by at least one checkpoint-independent mechanism, and (ii) checkpoint-dependent slowing of S phase in fission yeast when DNA is damaged may be accomplished primarily by the slowing of replication forks.     

Enforcement of late replication origin firing by clusters of short G-rich DNA sequences

Previous studies in budding yeast suggested that the default firing time of most DNA replication origins is early in S phase and that origins can be forced to fire later by proximity to certain cis-acting sequences. However, these cis-acting sequences were not well defined. We have attempted to characterize cis-acting sequences that affect replication timing in the fission yeast. We identified a stretch of 200 bp that was sufficient to compel nearby origins to fire late. The 200-bp stretch was able to force an origin to fire late whether adjacent to the origin or approximately 800 bp away in opposite orientation. The stretch contains a cluster of three close matches to a G-rich, 10-bp late consensus sequence (LCS). The three LCS elements cooperate with each other and with other sequences within the 200-bp stretch to enforce late replication. Although only a few origins that fire in very late S phase have been identified in fission yeast, all of them are located close to a cluster of LCS elements.     

Influence of a replication enhancer on the hierarchy of origin efficiencies within a cluster of DNA replication origins.

DNA replication origins in animal cells sometimes occur in clusters. Often one of the multiple origins within these clusters fires more frequently than the others. The reason for this hierarchy remains unknown. Similar origin clusters occur in the fission yeast, Schizosaccharomyces pombe. One such cluster is located near the ura4 gene on chromosome III and contains three origins: ars3002, ars3003, and ars3004. In their natural chromosomal context (ars3003 is about 2.5 kb upstream of ars3002 and ars3004 is adjacent to ars3002 on the downstream side) their initiation frequencies display a striking hierarchy: ars3002 > ars3003 > ars3004. Here, we describe experiments that reveal a 400 bp replication enhancer within ars3004, adjacent to ars3002. The enhancer is essential for ars3004 origin function in a plasmid, but even with the enhancer ars3004 is an inefficient origin. The enhancer is not essential for ars3002 plasmid origin activity, but dramatically stimulates this activity, converting ars3002 from an inefficient plasmid origin to a very efficient one. It also stimulates the plasmid origin activity of ars3001 and ars3003 at all tested positions and orientations on both sides of each autonomously replicating sequence (ARS) element. If ars3002 is redefined to include the enhancer, then the relative activities of the three ARS elements as single origins within separate plasmids or as origins when all three ARS elements are present in a single plasmid is the same as the chromosomal hierarchy. Thus, this replication enhancer defines the relative activities of the three origins in the ura4 origin region. Similar enhancers may affect relative activities in the origin clusters of animal cells.     

Association of Fission Yeast Orp1 and Mcm6 Proteins with Chromosomal Replication Origins

We have previously shown that replication of fission yeast chromosomes is initiated in distinct regions. Analyses of autonomous replicating sequences have suggested that regions required for replication are very different from those in budding yeast. Here, we present evidence that fission yeast replication origins are specifically associated with proteins that participate in initiation of replication. Most Orp1p, a putative subunit of the fission yeast origin recognition complex (ORC), was found to be associated with chromatin-enriched insoluble components throughout the cell cycle. In contrast, the minichromosome maintenance (Mcm) proteins, SpMcm2p and SpMcm6p, encoded by the nda1(+)/cdc19(+) and mis5(+) genes, respectively, were associated with chromatin DNA only during the G(1) and S phases. Immunostaining of spread nuclei showed SpMcm6p to be localized at discrete foci on chromatin during the G(1) and S phases. A chromatin immunoprecipitation assay demonstrated that Orp1p was preferentially localized at the ars2004 and ars3002 origins of the chromosome throughout the cell cycle, while SpMcm6p was associated with these origins only in the G(1) and S phases. Both Orp1p and SpMcm6p were associated with a 1-kb region that contains elements required for autonomous replication of ars2004. The results suggest that the fission yeast ORC specifically interacts with chromosomal replication origins and that Mcm proteins are loaded onto the origins to play a role in initiation of replication.     

Replication Origins and Timing of Temporal Replication in Budding Yeast: How to Solve the Conundrum?

Similarly to metazoans, the budding yeast Saccharomyces cereviasiae replicates its genome with a defined timing. In this organism, well-defined, site-specific origins, are efficient and fire in almost every round of DNA replication. However, this strategy is neither conserved in the fission yeast Saccharomyces pombe, nor in Xenopus or Drosophila embryos, nor in higher eukaryotes, in which DNA replication initiates asynchronously throughout S phase at random sites. Temporal and spatial controls can contribute to the timing of replication such as Cdk activity, origin localization, epigenetic status or gene expression. However, a debate is going on to answer the question how individual origins are selected to fire in budding yeast. Two opposing theories were proposed: the “replicon paradigm” or “temporal program” vs. the “stochastic firing”. Recent data support the temporal regulation of origin activation, clustering origins into temporal blocks of early and late replication. Contrarily, strong evidences suggest that stochastic processes acting on origins can generate the observed kinetics of replication without requiring a temporal order. In mammalian cells, a spatiotemporal model that accounts for a partially deterministic and partially stochastic order of DNA replication has been proposed. Is this strategy the solution to reconcile the conundrum of having both organized replication timing and stochastic origin firing also for budding yeast? In this review we discuss this possibility in the light of our recent study on the origin activation, suggesting that there might be a stochastic component in the temporal activation of the replication origins, especially under perturbed conditions.     

Comparison of the two major ARS elements of the ura4 replication origin region with other ARS elements in the fission yeast,Schizosaccharomyces pombe

We have previously peported that the replication orgin region located near the ura4 gene on chromosome III of the fission yeast, Schizosaccharomyces pombe, contains three closely spaced origins, each associated with an autonomously replicating sequence (ARS) element. Here we report the nucleotide sequences of two of these ARS elements, ars3002 and ars3003. The two ARS elements are located on either side of a transcribed 1.5 kb open reading frame. Like 11 other S. pombe ARS elements whose sequences have previously been determined in other laboratories, the 2 new ARS elements are unusually A+T-rich. All 13 ARS elements contain easily unwound stretches of DNA. Each of the ARS elements contains numerous copies, at a higher than expected frequency, of short stretches of A+T-rich DNA in which most of the Ts are on one strand and most of the As are on the complementary strand. We discuss the potential significance for ARS function of these multiple asymmetric A+T-rich sequences.     

Identification and characterization of a complex chromosomal replication origin in<Emphasis Type="Italic">Schizosaccharomyces pombe</Emphasis>

In the budding yeast,S. cerevisiae, two-dimensional (2D) gel electrophoresis techniques permit mapping of DNA replication origins to short stretches of DNA (±300 bp). In contrast, in mammalian cells andDrosophila, 2D gel techniques do not permit precise origin localization; the results have been interpreted to suggest that replication initiates in broad zones (several kbp or more). However, alternative techniques (replication timing, nascent strand polarity analysis, nascent strand size analysis) suggest that mammalian origins can be mapped to short DNA stretches, just likeS. cerevisiae origins. Because the fission yeast,Schizosaccharomyces pombe, resembles higher organisms in several ways to a greater extent than doesS. cerevisiae, we thought thatS. pombe replication origins might prove to resemble — and thus be helpful models for — animal cell origins. An attempt to test this possibility using 2D gel techiques resulted in identification of a replication origin near theura4 gene on chromosome III ofS. pombe. The 2D gel patterns produced by thisS. pombe origin indeed resemble the patterns produced by animal cell origins and show that theS. pombe origin cannot be precisely located. The data suggest an initiation zone of 3–5 kbp. Some aspects of the 2D gel patterns detected at theS. pombe origin cannot be explained by the rationale of initiation in broad zones, suggesting that future biochemical and genetic studies of this complex origin are likely to provide information useful in helping to understand the apparent conflict between the 2D gel mapping techniques and other mapping techniques at animal cell origins.     

Motifs in Schizosaccharomyces pombe ars3002 important for replication origin activity in Saccharomyces cerevisiae

Ars3002 is an efficient single-copy replication origin in the fission yeast, Schizosaccharomyces pombe. In a previous study, we tested the effects of consecutive approximately 50-bp deletions throughout ars3002 on the replication efficiency of those origins in S. pombe. Here we report the results of our use of the same approximately 50-bp deletions to test the hypothesis that some of the cis-acting sequences important for replication origin activity in fission yeast might be conserved in the evolutionarily distant budding yeast, Saccharomyces cerevisiae. We found that in most cases there was no correlation between the effects of particular mutations in S. pombe and in S. cerevisiae. We conclude that it is unlikely that any of the cis-acting sequences recognised by homologous replication proteins is conserved between these two yeast species.     

Initiation of DNA Replication from Non-Canonical Sites on an Origin-Depleted Chromosome

Eukaryotic DNA replication initiates from multiple sites on each chromosome called replication origins (origins). In the budding yeast Saccharomyces cerevisiae, origins are defined at discrete sites. Regular spacing and diverse firing characteristics of origins are thought to be required for efficient completion of replication, especially in the presence of replication stress. However, a S. cerevisiae chromosome III harboring multiple origin deletions has been reported to replicate relatively normally, and yet how an origin-deficient chromosome could accomplish successful replication remains unknown. To address this issue, we deleted seven well-characterized origins from chromosome VI, and found that these deletions do not cause gross growth defects even in the presence of replication inhibitors. We demonstrated that the origin deletions do cause a strong decrease in the binding of the origin recognition complex. Unexpectedly, replication profiling of this chromosome showed that DNA replication initiates from non-canonical loci around deleted origins in yeast. These results suggest that replication initiation can be unexpectedly flexible in this organism.     

Genetic analysis of an ARS element from the fission yeast Schizosaccharomyces pombe.

ARS (autonomously replicating sequence) elements are DNA fragments that can function as origins of DNA replication in yeast. We report the first fine-structure analysis of ars1, an ARS element of the fission yeast Schizosaccharomyces pombe. Characterization of a series of nested deletion mutations indicated that the minimal fragment of DNA encompassing ars1 is surprisingly large. No fragment < 650 bp retained significant ARS activity. Analysis of deletion and substitution mutations scanning the entire minimal ars1 identified a single essential 50 bp fragment (segment 1). Only one other 50 bp mutation reduced activity as much as 5-fold and most deletions were without effect. Thus, the minimal ars1 is composed of two general types of genetic elements, a small segment that is absolutely required for efficient ARS activity and a much larger region that is tolerant of internal structural alterations. Higher resolution analysis of segment 1 defined a critical 30 bp A/T-rich segment which appears to contain redundant genetic elements. Schizosaccharomyces pombe ars1 promoted high frequency transformation in the budding yeast S.cerevisiae but this heterologous activity was not dependent on segment 1. Our analysis indicates that the functional elements required for ARS function in S.pombe and S.cerevisiae are clearly different.     

Chromosomal Mcm2-7 distribution and the genome replication program in species from yeast to humans

The spatio-temporal program of genome replication across eukaryotes is thought to be driven both by the uneven loading of pre-replication complexes (pre-RCs) across the genome at the onset of S-phase, and by differences in the timing of activation of these complexes during S phase. To determine the degree to which distribution of pre-RC loading alone could account for chromosomal replication patterns, we mapped the binding sites of the Mcm2-7 helicase complex (MCM) in budding yeast, fission yeast, mouse and humans. We observed similar individual MCM double-hexamer (DH) footprints across the species, but notable differences in their distribution: Footprints in budding yeast were more sharply focused compared to the other three organisms, consistent with the relative sequence specificity of replication origins in S. cerevisiae. Nonetheless, with some clear exceptions, most notably the inactive X-chromosome, much of the fluctuation in replication timing along the chromosomes in all four organisms reflected uneven chromosomal distribution of pre-replication complexes.     

Rmt1 catalyzes zinc-finger independent arginine methylation of ribosomal protein Rps2 in Saccharomyces cerevisiae

Rps2/rpS2 is a well conserved protein of the eukaryotic ribosomal small subunit. Rps2 has previously been shown to contain asymmetric dimethylarginine residues, the addition of which is catalyzed by zinc-finger-containing arginine methyltransferase 3 (Rmt3) in the fission yeast Schizosaccharomyces pombe and protein arginine methyltransferase 3 (PRMT3) in mammalian cells. Here, we demonstrate that despite the lack of a zinc-finger-containing homolog of Rmt3/PRMT3 in the budding yeast Saccharomyces cerevisiae, Rps2 is partially modified to generate asymmetric dimethylarginine and monomethylarginine residues. We find that this modification of Rps2 is dependent upon the major arginine methyltransferase 1 (Rmt1) in S. cerevisiae. These results are suggestive of a role for Rmt1 in modifying the function of Rps2 in a manner distinct from that occurring in S. pombe and mammalian cells.     

Mapping autonomously replicating sequence elements in a 73-kb region of chromosome II of the fission yeast, Schizosaccharomyces pombe

Autonomously replicating sequence (ARS) elements are the genetic determinants of replication origin function in yeasts. They can be easily identified as the plasmids containing them transform yeast cells at a high frequency. As the first step towards identifying all potential replication origins in a 73-kb region of the long arm of fission yeast chromosome II, we have mapped five new ARS elements using systematic subcloning and transformation assay. 2D analysis of one of the ARS plasmids that showed highest transformation frequency localized the replication origin activity within the cloned genomic DNA. All the new ARS elements are localized in two clusters in centromere proximal 40 kb of the region. The presence of at least six ARS elements, including the previously reported ars727, is suggestive of a higher origin density in this region than that predicted earlier using a computer based search.     

Specification of DNA Replication Origins and Genomic Base Composition in Fission Yeasts

In the “Replicon Theory”, Jacob, Brenner and Cuzin proposed the existence of replicators and initiators as the two major actors in DNA replication. Over the years, many protein components of initiators have been shown to be conserved in different organisms during evolution. By contrast, replicator DNA sequences (often referred to as replication origins) have diverged beyond possible comparison between eukaryotic genomes. Replication origins in the fission yeast Schizosaccharomyces pombe are made up of A + T-rich sequences that do not share any consensus elements. The information encoded in these replicators is interpreted by the Orc4 subunit of the ORC (origin recognition complex), which is unique among eukaryotes in that it contains a large domain harboring nine AT-hook subdomains that target ORC to a great variety of A + T-rich sequences along the chromosomes. Recently, the genomes of other Schizosaccharomyces species have been sequenced and the regions encompassing their replication origins have been identified. DNA sequence analysis and comparison of the organization of their Orc4 proteins have revealed species-specific differences that contribute to our understanding of how the specification of replication origins has evolved during the phylogenetic divergence of fission yeasts.     

Rif1 Regulates Initiation Timing of Late Replication Origins throughout the S. cerevisiae Genome

Chromosomal DNA replication involves the coordinated activity of hundreds to thousands of replication origins. Individual replication origins are subject to epigenetic regulation of their activity during S-phase, resulting in differential efficiencies and timings of replication initiation during S-phase. This regulation is thought to involve chromatin structure and organization into timing domains with differential ability to recruit limiting replication factors. Rif1 has recently been identified as a genome-wide regulator of replication timing in fission yeast and in mammalian cells. However, previous studies in budding yeast have suggested that Rif1’s role in controlling replication timing may be limited to subtelomeric domains and derives from its established role in telomere length regulation. We have analyzed replication timing by analyzing BrdU incorporation genome-wide, and report that Rif1 regulates the timing of late/dormant replication origins throughout the S. cerevisiae genome. Analysis of pfa4Δ cells, which are defective in palmitoylation and membrane association of Rif1, suggests that replication timing regulation by Rif1 is independent of its role in localizing telomeres to the nuclear periphery. Intra-S checkpoint signaling is intact in rif1Δ cells, and checkpoint-defective mec1Δ cells do not comparably deregulate replication timing, together indicating that Rif1 regulates replication timing through a mechanism independent of this checkpoint. Our results indicate that the Rif1 mechanism regulates origin timing irrespective of proximity to a chromosome end, and suggest instead that telomere sequences merely provide abundant binding sites for proteins that recruit Rif1. Still, the abundance of Rif1 binding in telomeric domains may facilitate Rif1-mediated repression of non-telomeric origins that are more distal from centromeres.     

Epigenetically-Inherited Centromere and Neocentromere DNA Replicates Earliest in S-Phase

Eukaryotic centromeres are maintained at specific chromosomal sites over many generations. In the budding yeast Saccharomyces cerevisiae, centromeres are genetic elements defined by a DNA sequence that is both necessary and sufficient for function; whereas, in most other eukaryotes, centromeres are maintained by poorly characterized epigenetic mechanisms in which DNA has a less definitive role. Here we use the pathogenic yeast Candida albicans as a model organism to study the DNA replication properties of centromeric DNA. By determining the genome-wide replication timing program of the C. albicans genome, we discovered that each centromere is associated with a replication origin that is the first to fire on its respective chromosome. Importantly, epigenetic formation of new ectopic centromeres (neocentromeres) was accompanied by shifts in replication timing, such that a neocentromere became the first to replicate and became associated with origin recognition complex (ORC) components. Furthermore, changing the level of the centromere-specific histone H3 isoform led to a concomitant change in levels of ORC association with centromere regions, further supporting the idea that centromere proteins determine origin activity. Finally, analysis of centromere-associated DNA revealed a replication-dependent sequence pattern characteristic of constitutively active replication origins. This strand-biased pattern is conserved, together with centromere position, among related strains and species, in a manner independent of primary DNA sequence. Thus, inheritance of centromere position is correlated with a constitutively active origin of replication that fires at a distinct early time. We suggest a model in which the distinct timing of DNA replication serves as an epigenetic mechanism for the inheritance of centromere position.     

Checkpoint-Dependent Regulation of Origin Firing and Replication Fork Movement in Response to DNA Damage in Fission Yeast

To elucidate the checkpoint mechanism responsible for slowing passage through S phase when fission yeast cells are treated with the DNA-damaging agent methyl methanesulfonate (MMS), we carried out two-dimensional gel analyses of replication intermediates in cells synchronized by cdc10 block (in G₁) followed by release into synchronous S phase. The results indicated that under these conditions early-firing centromeric origins were partially delayed but late-firing telomeric origins were not delayed. Replication intermediates persisted in MMS-treated cells, suggesting that replication fork movement was inhibited. These effects were dependent on the Cds1 checkpoint kinase and were abolished in cells overexpressing the Cdc25 phosphatase, suggesting a role for the Cdc2 cyclin-dependent kinase. We conclude that both partial inhibition of the firing of a subset of origins and inhibition of replication fork movement contribute to the slowing of S phase in MMS-treated fission yeast cells.In response to low levels of the DNA-alkylating agent methyl methanesulfonate (MMS), wild-type yeast cells slow their progression through S phase, while cells lacking the appropriate upstream checkpoint kinase (Mec1 in the budding yeast Saccharomyces cerevisiae; Rad3 in the fission yeast Schizosaccharomyces pombe) or the appropriate downstream checkpoint kinase (Rad53 in budding yeast, Cds1 in fission yeast) fail to do so. Other DNA-damaging agents also cause a checkpoint-dependent slowing of S phase, in vertebrates as well as in yeasts. This slowing of S phase in response to DNA damage is sometimes called the “intra-S-phase” checkpoint (3, 6, 22, 23, 26, 28, 36, 37, 45, 53). Here we shall refer to it as the “S-phase damage” checkpoint.Prior to this report, the downstream portions of the checkpoint pathway(s) that slow S phase in response to DNA damage in fission yeast were unclear. However, the upstream portions of these pathways in fission yeast and other organisms have been partially elucidated, and downstream mechanisms in other organisms have been partially clarified. In all studied systems, upon detection of DNA damage in S phase, checkpoint proteins initiate a phosphorylation cascade that ultimately leads to slowing of replication. Upstream signaling in these systems involves the activation of one or more of the phosphatidylinositol-3-kinase-like protein kinases (PIK kinases; ATR and/or ATM in humans, Mec1 and/or Tel1 in budding yeast, and Rad3 in fission yeast). The activated PIK kinases then phosphorylate several proteins, including certain Ser/Thr kinases (Chk1 and/or Chk2 in humans, Rad53 in budding yeast, and Cds1 in fission yeast). These kinases, in turn, phosphorylate other substrates that, directly or indirectly, mediate the slowing of S phase (reviewed in reference 3).In budding yeast, two different mechanisms were shown to slow S phase upon DNA damage by MMS. Of these, one mechanism, inhibition of late-firing origins, depended on the Mec1-Rad53 checkpoint pathway (45, 53), while the other mechanism, inhibition of replication forks, appeared to be a direct consequence of DNA damage rather than a result of checkpoint activation (53). Tercero and Diffley (53) found that, in MMS-treated cells with mutations in the RAD53 gene, unregulated origin firing compensated for checkpoint-independent replication fork slowing, thus permitting a relatively normal overall rate of DNA synthesis. The mechanism by which the Rad53 protein modulates late origin activity is not yet clear, but one possibility is inhibition (by Rad53-catalyzed phosphorylation) of Dbf4, the regulatory subunit of the Cdc7-Dbf4 kinase, which is essential for initiation of replication (7, 8, 14, 55).In vertebrates, at least three different pathways have been shown to contribute to the slowing of S phase after DNA damage. In some cases checkpoint-mediated phosphorylation of Dbf4 inhibits progression through S phase by downregulating origin firing (7, 14), as may take place in budding yeast. In other cases, checkpoint-mediated phosphorylation leads to inhibition and destruction of the protein phosphatase Cdc25A, which is an activator of Cdk2. Cdk2 is the S-phase-specific cyclin-dependent kinase. Cdk2 activity is crucial for initiation of DNA replication and is modulated by inhibitory phosphorylation at Tyr-15. Cdc25A activates Cdk2 by dephosphorylating Tyr-15. Thus, when Cdc25A is phosphorylated by checkpoint kinases after DNA damage and subsequently destroyed, Cdk2 can no longer promote initiation of DNA replication (9, 27). The third mechanism by which vertebrate cells can slow progression through S phase is inhibition of replication fork movement. In vertebrate cells, slowing of replication forks in response to DNA damage is frequently checkpoint dependent; in contrast, in budding yeast, such slowing appeared to be checkpoint independent. In the tested cases, fork slowing has proved to be dependent on the PIK kinase ATR (homologous to budding yeast Mec1 and fission yeast Rad3) and on the Ser/Thr kinase Chk1 (a functional analogue of budding yeast''s Rad53 and fission yeast''s Cds1). In each of these cases, the checkpoint response to DNA damage led to inhibition of origin firing as well as to inhibition of replication fork movement (42, 44, 54). The precise mechanism leading to slowing of replication fork movement has not been fully worked out, but the mechanism appears to involve interactions between Chk1 and the proteins Tim and Tipin (54), whose yeast homologues (Swi1 and Swi3 in fission yeast, Tof1 and Csm3 in budding yeast) form a “replication fork protection complex” that is associated with replication forks (19, 33).Although it is clear that slowing of S phase in response to MMS-induced DNA damage in fission yeast requires both the Rad3 and Cds1 kinases, the pathways operating downstream of Cds1 have been uncertain. We obtained results indicating that Cdc25, which was already known to be a target of Cds1 in hydroxyurea (HU)-treated cells, is also a target of Cds1 in MMS-treated cells, because both overproduction of Cdc25 and conversion of Tyr-15 on Cdc2 (the major cyclin-dependent kinase of fission yeast; also known as Cdk1) to a nonphosphorylatable residue (Cdc2-Y15F; this mutation rendered Cdc2 constitutively active) were sufficient to prevent MMS-induced slowing of S phase (23). We concluded that, in fission yeast, the Rad3→Cds1⊣Cdc25→Cdc2 pathway forms a checkpoint signaling module very similar to the corresponding one of vertebrates. However, Kommajosyula and Rhind were not able to repeat our observations regarding the roles of Cdc25 and Cdc2 (22), so the relevance of Cdc25 and Cdc2 to checkpoint-induced slowing of S phase in fission yeast has remained uncertain until now. In addition, whether S phase in MMS-treated fission yeast cells is slowed by inhibition of origin firing, by reduction in rate of fork movement, or by a combination of these has been equally unclear.In order to resolve these issues, we initiated the series of experiments reported in this paper. To measure the rate of progression through S phase, we followed S phase by flow cytometry and by two-dimensional (2D) gel electrophoresis in cells released from a G₁ block (achieved by incubating cells bearing a cdc10 temperature-sensitive mutation at the restrictive temperature, then releasing to the permissive temperature [21, 23]). We found that, in MMS-treated, checkpoint-competent cells, the firing of early origins near centromeres was partially delayed but that the firing of late origins near telomeres was unaffected. Furthermore, the lifetimes of replication intermediates (RIs) were prolonged, consistent with slowing of replication forks. These effects were completely abrogated both in cells lacking the Cds1 kinase and in cells overproducing the Cdc25 phosphatase, showing that these effects were checkpoint dependent and that the relevant checkpoint pathway probably involved inhibition of Cdc25.