Involvement of Schizosaccharomyces pombe rrp1+ and rrp2+ in the Srs2- and Swi5/Sfr1-dependent pathway in response to DNA damage and replication inhibition

Previously we identified Rrp1 and Rrp2 as two proteins required for the Sfr1/Swi5-dependent branch of homologous recombination (HR) in Schizosaccharomyces pombe. Here we use a yeast two-hybrid approach to demonstrate that Rrp1 and Rrp2 can interact with each other and with Swi5, an HR mediator protein. Rrp1 and Rrp2 form co-localizing methyl methanesulphonate–induced foci in nuclei, further suggesting they function as a complex. To place the Rrp1/2 proteins more accurately within HR sub-pathways, we carried out extensive epistasis analysis between mutants defining Rrp1/2, Rad51 (recombinase), Swi5 and Rad57 (HR-mediators) plus the anti-recombinogenic helicases Srs2 and Rqh1. We confirm that Rrp1 and Rrp2 act together with Srs2 and Swi5 and independently of Rad57 and show that Rqh1 also acts independently of Rrp1/2. Mutants devoid of Srs2 are characterized by elevated recombination frequency with a concomitant increase in the percentage of conversion-type recombinants. Strains devoid of Rrp1 or Rrp2 did not show a change in HR frequency, but the number of conversion-type recombinants was increased, suggesting a possible function for Rrp1/2 with Srs2 in counteracting Rad51 activity. Our data allow us to propose a model placing Rrp1 and Rrp2 functioning together with Swi5 and Srs2 in a synthesis-dependent strand annealing HR repair pathway.     

A novel DNA damage recognition protein in Schizosaccharomyces pombe

Toxic and mutagenic O⁶-alkylguanine adducts in DNA are repaired by O⁶-alkylguanine-DNA alkyltransferases (MGMT) by transfer of the alkyl group to a cysteine residue in the active site. Comparisons in silico of prokaryotes and lower eukaryotes reveal the presence of a group of proteins [alkyltransferase-like (ATL) proteins] showing amino acid sequence similarity to MGMT, but where the cysteine at the putative active site is replaced by tryptophan. To examine whether ATL proteins play a role in the biological effects of alkylating agents, we inactivated the gene, referred to as atl1⁺, in Schizosaccharomyces pombe, an organism that does not possess a functional MGMT homologue. The mutants are substantially more susceptible to the toxic effects of the methylating agents, N-methyl-N-nitrosourea, N-methyl-N′nitro-N-nitrosoguanidine and methyl methanesulfonate and longer chain alkylating agents including N-ethyl-N-nitrosourea, ethyl methanesulfonate, N-propyl-N-nitrosourea and N-butyl-N-nitrosourea. Purified Atl1 protein does not transfer methyl groups from O⁶-methylguanine in [³H]-methylated DNA but reversibly inhibits methyl transfer by human MGMT. Atl1 binds to short single-stranded oligonucleotides containing O⁶-methyl, -benzyl, -4-bromothenyl or -hydroxyethyl-guanine but does not remove the alkyl group or base and does not cleave the oligonucleotide in the region of the lesion. This suggests that Atl1 acts by binding to O⁶-alkylguanine lesions and signalling them for processing by other DNA repair pathways. This is the first report describing an activity that protects S.pombe against the toxic effects of O⁶-alkylguanine adducts and the biological function of a family of proteins that is widely found in prokaryotes and lower eukaryotes.     

Non-productive DNA damage binding by DNA glycosylase-like protein Mag2 from Schizosaccharomyces pombe

Schizosaccharomyces pombe contains two paralogous proteins, Mag1 and Mag2, related to the helix-hairpin-helix (HhH) superfamily of alkylpurine DNA glycosylases from yeast and bacteria. Phylogenetic analysis of related proteins from four Schizosaccharomyces and other fungal species shows that the Mag1/Mag2 duplication is unique to the genus Schizosaccharomyces and most likely occurred in its ancestor. Mag1 excises N3- and N7-alkylguanines and 1,N⁶-ethenoadenine from DNA, whereas Mag2 has been reported to have no detectible alkylpurine base excision activity despite high sequence and active site similarity to Mag1. To understand this discrepancy we determined the crystal structure of Mag2 bound to abasic DNA and compared it to our previously determined Mag1–DNA structure. In contrast to Mag1, Mag2 does not flip the abasic moiety into the active site or stabilize the DNA strand 5′ to the lesion, suggesting that it is incapable of forming a catalytically competent protein–DNA complex. Subtle differences in Mag1 and Mag2 interactions with the DNA duplex illustrate how Mag2 can stall at damage sites without fully engaging the lesion. We tested our structural predictions by mutational analysis of base excision and found a single amino acid responsible at least in part for Mag2's lack of activity. Substitution of Mag2 Asp56, which caps the helix at the base of the DNA intercalation loop, with the corresponding serine residue in Mag1 endows Mag2 with ?A excision activity comparable to Mag1. This work provides novel insight into the chemical and physical determinants by which the HhH glycosylases engage DNA in a catalytically productive manner.     

The cellular responses to DNA damage

The ability to survive spontaneous and induced DNA damage, and to minimize the number of heritable mutations that this causes, is essential to the maintenance of genome integrity for all organisms. Early studies on model eukaryotes focused on genes acting in defined DNA repair pathways. More recent work with the budding and fission yeasts and mammalian cells has started to integrate the DNA damage response with cell physiology and the cell cycle.     

Repair of deaminated base damage by Schizosaccharomyces pombe thymine DNA glycosylase

Thymine DNA glycosylases (TDG) in eukaryotic organisms are known for their double-stranded glycosylase activity on guanine/uracil (G/U) base pairs. Schizosaccharomyces pombe (Spo) TDG is a member of the MUG/TDG family that belongs to a uracil DNA glycosylase superfamily. This work investigates the DNA repair activity of Spo TDG on all four deaminated bases: xanthine (X) and oxanine (O) from guanine, hypoxanthine (I) from adenine, and uracil from cytosine. Unexpectedly, Spo TDG exhibits glycosylase activity on all deaminated bases in both double-stranded and single-stranded DNA in the descending order of X > I > U  O. In comparison, human TDG only excises deaminated bases from G/U and, to a much lower extent, A/U and G/I base pairs. Amino acid substitutions in motifs 1 and 2 of Spo TDG show a significant impact on deaminated base repair activity. The overall mutational effects are characterized by a loss of glycosylase activity on oxanine in all five mutants. L157I in motif 1 and G288M in motif 2 retain xanthine DNA glycosylase (XDG) activity but reduce excision of hypoxanthine and uracil, in particular in C/I, single-stranded hypoxanthine (ss-I), A/U, and single-stranded uracil (ss-U). A proline substitution at I289 in motif 2 causes a significant reduction in XDG activity and a loss of activity on C/I, ss-I, A/U, C/U, G/U, and ss-U. S291G only retains reduced activity on T/I and G/I base pairs. S163A can still excise hypoxanthine and uracil in mismatched base pairs but loses XDG activity, making it the closest mutant, functionally, to human TDG. The relationship among amino acid substitutions, binding affinity and base recognition is discussed.     

Redundant roles of Srs2 helicase and replication checkpoint in survival and rDNA maintenance in Schizosaccharomyces pombe

Srs2 helicase is believed to function as an anti-recombinase by resolving inappropriate Rad51-DNA filament. We found synthetic lethality or poor growth of srs2 with rad3 or mrc1 in Schizossacharomyces pombe. Lethality may result from a defect in non-checkpoint function of Rad3 or Mrc1 in the absence of Srs2, because srs2∆ rad9∆, srs2∆ chk1∆ cds1∆ or srs2∆ mrc1-14A (non-phosphorylatable mrc1 allele) did not show significant growth impairment. Notably, the inactivation of rhp51/RAD51 or rad22/RAD52 failed to rescue the growth, suggesting that events that impose lethality are independent of homologous recombination. Incubation of the conditional srs2∆ rad3 ^ts cells at restrictive temperature led not only to a viability decrease but also to a remarkable shortening of rDNA clusters (~100 copies). As opposed to the growth defect, shortening of rDNA clusters was also observed in srs2∆ rad9∆, srs2∆ chk1∆ cds1∆ or srs2∆ mrc1-14A, indicating that proper replication checkpoint signaling is critical for rDNA maintenance. Activation of Chk1 in the unchallenged mrc1-14A srs2∆ cells implies a certain level of spontaneous fork damage that might be the cause for rDNA instability. The data suggest that redundant functions of Srs2 and checkpoint proteins are essential for two independent aspects of genome maintenance. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Differential activation of eIF2 kinases in response to cellular stresses in Schizosaccharomyces pombe

Phosphorylation of eukaryotic initiation factor-2 (eIF2) is an important mechanism mitigating cellular injury in response to diverse environmental stresses. While all eukaryotic organisms characterized to date contain an eIF2 kinase stress response pathway, the composition of eIF2 kinases differs, with mammals containing four distinct family members and the well-studied lower eukaryote Saccharomyces cerevisiae expressing only a single eIF2 kinase. We are interested in the mechanisms by which multiple eIF2 kinases interface with complex stress signals and elicit response pathways. In this report we find that in addition to two previously described eIF2 kinases related to mammalian HRI, designated Hri1p and Hri2p, the yeast Schizosaccharomyces pombe expresses a third eIF2 kinase, a Gcn2p ortholog. To delineate the roles of each eIF2 kinase, we constructed S. pombe strains expressing only a single eIF2 kinase gene or deleted for the entire eIF2 kinase family. We find that Hri2p is the primary activated eIF2 kinase in response to exposure to heat shock, arsenite, or cadmium. Gcn2p serves as the primary eIF2 kinase induced during a nutrient downshift, treatment with the amino acid biosynthetic inhibitor 3-aminotriazole, or upon exposure to high concentrations of sodium chloride. In one stress example, exposure to H₂O₂, there is early tandem activation of both Hri2p and Gcn2p. Interestingly, with extended stress conditions there is activation of alternative secondary eIF2 kinases, suggesting that eukaryotes have mechanisms of coordinate activation of eIF2 kinase in their stress remediation responses. Deletion of these eIF2 kinases renders S. pombe more sensitive to many of these stress conditions.     

Schizosaccharomyces pombe checkpoint response to DNA interstrand cross-links

Drugs that produce covalent interstrand cross-links (ICLs) in DNA remain central to the treatment of cancer, but the cell cycle checkpoints activated by ICLs have received little attention. We have used the fission yeast, Schizosaccharomyces pombe, to elucidate the checkpoint responses to the ICL-inducing anticancer drugs nitrogen mustard and mitomycin C. First we confirmed that the repair pathways acting on ICLs in this yeast are similar to those in the main organisms studied to date (Escherichia coli, budding yeast, and mammalian cells), principally nucleotide excision repair and homologous recombination. We also identified and disrupted the S. pombe homologue of the Saccharomyces cerevisiae SNM1/PSO2 ICL repair gene and found that this activity is required for normal resistance to cross-linking agents, but not other forms of DNA damage. Survival and biochemical analysis indicated a key role for the "checkpoint Rad" family acting through the chk1-dependent DNA damage checkpoint in the ICL response. Rhp9-dependent phosphorylation of Chk1 correlates with G(2) arrest following ICL induction. In cells able to bypass the G(2) block, a second-cycle (S-phase) arrest was observed. Only a transient activation of the Cds1 DNA replication checkpoint factor occurs following ICL formation in wild-type cells, but this is increased and persists in G(2) arrest-deficient mutants. This likely reflects the fraction of cells escaping the G(2) damage checkpoint and arresting in the subsequent S phase due to ICL replication blocks. Disruption of cds1 confers increased resistance to ICLs, suggesting that this second-cycle S-phase arrest might be a lethal event.     

Involvement of nuclear domains in the cellular response to DNA damage

All cells of human organism are continuously damaged, and a damage of the genetic material can be especially dangerous. The reaction of the cell to DNA damage is a complex process, which includes damage signaling, repair, apoptosis or cell death. It is connected with serious changes in the cell nucleus, which are caused by posttranslational modifications and dynamic relocalizations of proteins as well as alterations in the expression of many genes. These changes are not limited to the sites of DNA damage, but involve whole cell nucleus, including its domains: PML bodies, nucleolus and Cajal bodies.     

RecQ helicases and cellular responses to DNA damage

The faithful replication of the genome is essential for the survival of all organisms. It is not surprising therefore that numerous mechanisms have evolved to ensure that duplication of the genome occurs with only minimal risk of mutation induction. One mechanism of genome destabilization is replication fork demise, which can occur when a translocating fork meets a lesion or adduct in the template. Indeed, the collapse of replication forks has been suggested to occur in every replicative cell cycle making this a potentially significant problem for all proliferating cells. The RecQ helicases, which are essential for the maintenance of genome stability, are thought to function during DNA replication. In particular, RecQ helicase mutants display replication defects and have phenotypes consistent with an inability to efficiently reinitiate replication following replication fork demise. Here, we review some current models for how replication fork repair might be effected, and discuss potential roles for RecQ helicases in this process.     

Sexual reproduction as a response to H2O2 damage in Schizosaccharomyces pombe.

Although sexual reproduction is widespread, its adaptive advantage over asexual reproduction is unclear. One major advantage of sex may be its promotion of recombinational repair of DNA damage during meiosis. This idea predicts that treatment of the asexual form of a facultatively sexual-asexual eucaryote with a DNA-damaging agent may cause it to enter the sexual cycle more frequently. Endogenous hydrogen peroxide is a major natural source of DNA damage. Thus, we treated vegetative cells of Schizosaccharomyces pombe with hydrogen peroxide to test if sexual reproduction increases. Among untreated stationary-phase S. pombe populations the sexual spores produced by meiosis represented about 1% of the total cells. However, treatment of late-exponential-phase vegetative cells with hydrogen peroxide increased the percentage of meiotic spores in the stationary phase by 4- to 18-fold. Oxidative damage therefore induces sexual reproduction in a facultatively sexual organism, a result expected by the hypothesis that sex promotes DNA repair.     

DNA structure checkpoint pathways in Schizosaccharomyces pombe

The response to DNA damage includes a delay to progression through the cell cycle to aid DNA repair. Incorrectly replicated chromosomes (replication checkpoint) or DNA damage (DNA damage checkpoint) delay the onset of mitosis. These checkpoint pathways detect DNA perturbations and generate a signal. The signal is amplified and transmitted to the cell cycle machinery. Since the checkpoint pathways are essential for genome stability, the related proteins which are found in all eukaryotes (from yeast to mammals) are expected to have similar functions to the yeast progenitors. This review article focuses on the function of checkpoint proteins in the model system Schizosaccharomyces pombe. Checkpoint controls in Saccharomyces cerevisiae and mammalian cells are mentioned briefly to underscore common or diverse features.     

Dds20 operates in cds1-independent mechanism of tolerance to UV-induced DNA damage in Schizosaccharomyces pombe cells

Repair of DNA double-stranded breaks caused by ionizing radiation or cellular metabolization, homologous recombination, is an evolutionary conserved process controlled by RAD52 group genes. Genes of recombinational repair also play a leading role in the response to DNA damage caused by UV light. Cells with deletion in gene dds20 of recombinational repair were shown to manifest hypersensitivity to the action of UV light at lowered incubation temperature. Epistatic analysis revealed that dds20+ is not a member of the NER and UVER gene groups responsible for the repair of DNA damage induced by UV light. The Dds protein has functions in the Cds1-independent mechanism of UV damage tolerance of DNA.     

Repair of UV damage in the fission yeast Schizosaccharomyces pombe

This review is concerned with repair and tolerance of UV damage in the fission yeast, Schizosaccharomyces pombe and with the differences between Sch. pombe and budding yeast, Saccharomyces cerevisiae in their response to UV irradiation. Sch. pombe is not as sensitive to ultra-violet radiation as Sac. cerevisiae nor are any of its mutants as sensitive as the most sensitive Sac. cerevisiae mutants. This can be explained in part by the fact that Sch. pombe, unlike budding yeast or mammalian cells, has an extra pathway (UVER) for excision of UV photoproducts in addition to nucleotide excision repair (NER). However, even in mutants lacking this additional pathway, there are significant differences between the two yeasts. Sch. pombe mutants that lack the alternative pathway are still more UV-resistant than wild-type Sac. cerevisiae; recombination mutants are significantly UV sensitive (unlike their Sac. cerevisiae equivalents); mutants lacking the second pathway are sensitized to UV by caffeine; and checkpoint mutants are relatively more sensitive than the budding yeast equivalents. In addition, Sch. pombe has no photolyase. Thus, the response to UV in the two yeasts has a number of significant differences, which are not accounted for entirely by the existence of two alternative excision repair pathways. The long G2 in Sch. pombe, its well-developed recombination pathways and efficient cell cycle checkpoints are all significant components in survival of UV damage.     

DNA repair mutants defining G2 checkpoint pathways in Schizosaccharomyces pombe.

We have tested mutants corresponding to 20 DNA repair genes of the fission yeast Schizosaccharomyces pombe for their ability to arrest in G2 after DNA damage. Of the mutants tested, four are profoundly defective in this damage dependent G2 arrest. In addition, these four mutants are highly sensitive to a transient inhibition of DNA synthesis by hydroxyurea. This suggests that the pathway responsible for the recognition of DNA damage and the subsequent mitotic arrest, shares many functions with the mechanism that controls the dependency of mitosis on the completion of S phase. The phenotype of these checkpoint rad mutants in wee mutant backgrounds indicate that the G2 arrest response is mediated either through, or in parallel with, the activity of the cdc2 gene product.