The Saccharomyces cerevisiae checkpoint genes RAD9, CHK1 and PDS1 are required for elevated homologous recombination in a mec1 (ATR) hypomorphic mutant

Specific ataxia telangiectasia and Rad3-related (ATR) mutations confer higher frequencies of homologous recombination. The genetic requirements for hyper-recombination in ATR mutants are unknown. MEC1, the essential yeast ATR/ATM homolog, controls S and G2 checkpoints and the DNA damage-inducibility of genes after radiation exposure. Since the mec1-D (null) mutant is defective in both S and G2 checkpoints, we measured spontaneous and DNA damage-associated sister chromatid exchange (SCE), homolog (heteroallelic) recombination, and homology-directed translocations in the mec1-21 hypomorphic mutant, which is defective in the S phase checkpoint but retains some G2 checkpoint function. We observed a sixfold, tenfold and 30-fold higher rate of spontaneous SCE, heteroallelic recombination, and translocations, respectively, in mec1-21 mutants compared to wild type. The mec1-21 hyper-recombination was partially reduced in rad9, pds1, and chk1 mutants, and abolished in rad52 mutants, suggesting the hyper-recombination results from RAD52-dependent recombination pathway(s) that require G2 checkpoint functions. The HU and UV sensitivities of mec1-21 rad9 and mec1-21 rad52 were synergistically increased, compared to the single mutants, indicating that mec1-21, rad52 and rad9 mutants are defective in independent pathways for HU and UV resistance. G2-arrested mec1-21 rad9 cells exhibit more UV resistance than non-synchronized cells, indicating that one function of RAD9 in conferring UV resistance in mec1-21 is by triggering G2 arrest. We suggest that checkpoint genes that function in the RAD9-mediated pathway are required for either homologous recombination or DNA damage resistance in the S phase checkpoint mutant mec1-21.     

Cell Cycle Arrest of Cdc Mutants and Specificity of the Rad9 Checkpoint

In eucaryotes a cell cycle control called a checkpoint ensures that mitosis occurs only after chromosomes are completely replicated and any damage is repaired. The function of this checkpoint in budding yeast requires the RAD9 gene. Here we examine the role of the RAD9 gene in the arrest of the 12 cell division cycle (cdc) mutants, temperature-sensitive lethal mutants that arrest in specific phases of the cell cycle at a restrictive temperature. We found that in four cdc mutants the cdc rad9 cells failed to arrest after a shift to the restrictive temperature, rather they continued cell division and died rapidly, whereas the cdc RAD cells arrested and remained viable. The cell cycle and genetic phenotypes of the 12 cdc RAD mutants indicate the function of the RAD9 checkpoint is phase-specific and signal-specific. First, the four cdc RAD mutants that required RAD9 each arrested in the late S/G(2) phase after a shift to the restrictive temperature when DNA replication was complete or nearly complete, and second, each leaves DNA lesions when the CDC gene product is limiting for cell division. Three of the four CDC genes are known to encode DNA replication enzymes. We found that the RAD17 gene is also essential for the function of the RAD9 checkpoint because it is required for phase-specific arrest of the same four cdc mutants. We also show that both X- or UV-irradiated cells require the RAD9 and RAD17 genes for delay in the G(2) phase. Together, these results indicate that the RAD9 checkpoint is apparently activated only by DNA lesions and arrests cell division only in the late S/G(2) phase.     

Cell cycle progression in the presence of irreparable DNA damage is controlled by a Mec1- and Rad53-dependent checkpoint in budding yeast.

We studied the response of nucleotide excision repair (NER)-defective rad14Delta cells to UV irradiation in G(1) followed by release into the cell cycle. Only a subset of checkpoint proteins appears to mediate cell cycle arrest and regulate the timely activation of replication origins in the presence of unrepaired UV-induced lesions. In fact, Mec1 and Rad53, but not Rad9 and the Rad24 group of checkpoint proteins, are required to delay cell cycle progression in rad14Delta cells after UV damage in G(1). Consistently, Mec1-dependent Rad53 phosphorylation after UV irradiation takes place in rad14Delta cells also in the absence of Rad9, Rad17, Rad24, Mec3 and Ddc1, and correlates with entry into S phase. Two-dimensional gel analysis indicates that late replication origins are not fired in rad14Delta cells UV-irradiated in G(1) and released into the cell cycle, which instead initiate DNA replication from early origins and accumulate replication and recombination intermediates. Progression through S phase of UV-treated NER-deficient mec1 and rad53 mutants correlates with late origin firing, suggesting that unregulated DNA replication in the presence of irreparable UV-induced lesions might result from a failure to prevent initiation at late origins.     

Cisplatin DNA cross-links do not inhibit S-phase and cause only a G2/M arrest in Saccharomyces cerevisiae.

Cisplatin (CDDP) has been used as a DNA cross-linking agent to evaluate whether there is a specific cell cycle checkpoint response to such damage in Saccharomyces cerevisiae (S. cerevisiae). Fluorescent-activated cell sorting (FACS) analysis showed only a G2/M checkpoint, normal exit from G1 and progression through S-phase following alpha-factor arrest and CDDP treatment. Of the checkpoint mutants tested, rad9, rad17 and rad24, did not show increased sensitivity to CDDP compared to isogenic wild-type cells. However, other checkpoint mutants tested (mec1, mec3 and rad53) showed increased sensitivity to CDDP, as did controls with a defect in excision repair (rad1 and rad14) or a defect in recombination (rad51 and rad52). Thus, by survival and cell cycle kinetics, it appears that DNA cross-links do not inhibit entry into S-phase or slow DNA replication and that replication continues after cisplatin treatment in yeast.     

A novel mutant allele of Schizosaccharomyces pombe rad26 defective in monitoring S-phase progression to prevent premature mitosis.

A semipermissive growth condition was defined for a Schizosaccharomyces pombe strain carrying a thermosensitive allele of DNA polymerase delta (pol delta ts03). Under this condition, DNA polymerase delta is semidisabled and causes a delay in S-phase progression. Using a genetic strategy, we have isolated a panel of mutants that enter premature mitosis when DNA replication is incomplete but which are not defective for arrest in G2/M following DNA damage. We characterized the aya14 mutant, which enters premature mitosis when S phase is arrested by genetic or chemical means. However, this mutant is sensitive to neither UV nor gamma irradiation. Two genomic clones, rad26+ and cds1+, were found to suppress the hydroxyurea sensitivity of the aya14 mutant. Genetic analysis indicates that aya14 is a novel allele of the cell cycle checkpoint gene rad26+, which we have named rad26.a14. cds1+ is a suppressor which suppresses the S-phase feedback control defect of rad26.a14 when S phase is inhibited by either hydroxyurea or cdc22, but it does not suppress the defect when S phase is arrested by a mutant DNA polymerase. Analyses of rad26.a14 in a variety of cdc mutant backgrounds indicate that strains containing rad26.a14 bypass S-phase arrest but not G1 or late S/G2 arrest. A model of how Rad26 monitors S-phase progression to maintain the dependency of cell cycle events and coordinates with other rad/hus checkpoint gene products in responding to radiation damage is proposed.     

Effects of hexavalent chromium on the survival and cell cycle distribution of DNA repair-deficient S. cerevisiae

A broad spectrum of genetic damage results from exposure to hexavalent chromium. These lesions can result in DNA and RNA polymerase arrest, chromosomal aberrations, point mutations and deletions. Because of the complexity of Cr genotoxicity, the repair of Cr(VI)-induced DNA damage is poorly understood. Therefore, our aim was to investigate the sensitivities of DNA repair-deficient Saccharomyces cerevisiae strains to Cr(VI)-induced growth inhibition and lethality. Wild-type, translesion synthesis (rev3) and excision repair (apn1, ntg1, ntg2, rad1) mutants exhibited similar survival following Cr(VI) treatment (0-50mM) and underwent at least one population doubling within 2-4h post-treatment. The simultaneous loss of several excision repair genes (apn1 rad1 ntg1 ntg2) led to slower growth after Cr(VI) exposure (10mM) manifested as an initial delay in S phase progression. Higher concentrations of Cr(VI) (25mM) resulted in a prolonged transit through S phase in every strain tested. A G(2)/M arrest was evident within 1-2h after Cr(VI) treatment (10mM) in all strains and cells subsequently divided after this transient delay. In contrast to all other strains, only recombination-deficient (rad52, rad52 rev3) yeast were markedly hypersensitive towards Cr(VI) lethality. RAD52 mutant strains (rad52, rad52 rev3) also exhibited a significant delay (>6h) in the resumption of replication after Cr(VI) exposure which was related to the immediate and apparently terminal arrest of these yeast in G(2)/M after Cr(VI) treatment. These results, taken together with the recombinogenic effects of Cr(VI) in yeast containing a functional RAD52 gene, suggest that RAD52-mediated recombination is critical for the normal processing of lethal Cr-induced genetic lesions and exit from G(2) arrest. Furthermore, only the combined inactivation of multiple excision repair genes affects cell growth after Cr(VI) treatment.     

Cellular radiation effects and hyperthermia cell cycle kinetics of radiation sensitive mutants of Saccharomyces cerevisiae after X-irradiation and hyperthermia

Radiosensitive mutants rad2, rad9, and rad51 of Saccharomyces cerevisiae were X-irradiated with 120 Gy or 60 Gy, heated at 50 degrees C for 30 min or treated with a combination of both and incubated in nutrient medium at 30 degrees C. Cell number, percentage of budding cells, and cell cycle progression were determined in 45-min intervals. Cell cycle kinetics were investigated by flow cytofluorometry. Hyperthermia leads mainly to a lengthening of G1, whereas X-rays arrest cells of the rad2 and rad9 mutant in G2 and the rad51--mutant additionaly in a state with DNA contents above G2. Cell division delay is influenced by oxygen in all strains but to a lesser extent in the rad2 mutant. The effect of the combined treatment appears to be merely additive in the rad2 and rad9 mutant while the rad51 mutant is sensitized to X-irradiation by hyperthermia. No selective action of hyperthermia on hypoxic cells was found.     

X-ray-induced mutants resistant to 8-azaguanine. II. Cell cycle dose response.

Synchronous Chinese hamster ovary cells were irradiated in G1 or S phase. Colony survival in Alpha MEM medium with dialyzed serum was determined with or without 15 mug/ml 8-azaguanine (AG). An expression period of over three generations (multiplicity of 20) was utilized, with expression times ranging from 58 to 114 h. Both G1 and S phase were practically identical in sensitivity to X-ray-induced mutations, with mutant frequency/viable cell/rad ranging from 1 X 10(-7) (75-100 rad) to 8 X 10(-7) (1000 rad). The spontaneous mutation rate, shown by Luria-Delbruck fluctuation analysis, was 5 X 10(-7) per generation. Thirty-three mutants, isolated at random and grown for over 30 generations in the absence of AG, were analyzed for plating efficiency (PE) in different concentrations of AG or in hypoxanthine-aminopterin-thymidine (HAT) medium. Of these, 64% were resistant (PE greater than 0.1) to 7.5 mug/ml AG, 85% to 5.0 mug/ml, and 91% to 3.5 mug/ml. Only 42% showed possible hypoxanthine-phosphoribosyltransferase (hprtase) deficiency as evidenced by HAT sensitivity (PE less than 0.1). Wild type controls exhibited PE's in 3.5 mug/ml AG of less than 0.001 and in HAT of greater than 0.5. Of ten mutants studied, all demonstrated survival response to radiation similar to wild type cells (D0 of approx. 120 rad). For radiation protection standards, the radiation dose required to induce mutations at a rate equal to that occurring spontaneously is called the doubling dose. The doubling dose observed for acute irradiation was about 3 rad and was estimated to be 10-60 rad for chronic irradiation, similar to that often reported for in vivo studies.     

Influence of double-strand-break repair pathways on radiosensitivity throughout the cell cycle in CHO cells

Unrepaired DNA double-strand breaks (DSBs) produced by ionizing radiation (IR) are a major determinant of cell killing. To determine the contribution of DNA repair pathways to the well-established cell cycle variation in IR sensitivity, we compared the radiosensitivity of wild-type CHO cells to mutant lines defective in nonhomologous end joining (NHEJ), homologous recombination repair (HRR), and the Fanconi anemia pathway. Cells were irradiated with IR doses that killed approximately 90% of each asynchronous population, separated into synchronous fractions by centrifugal elutriation, and assayed for survival (colony formation). Wild-type cells had lowest resistance in early G1 and highest resistance in S phase, followed by declining resistance as cells move into G2/M. In contrast, HR-defective cells (xrcc3 mutation) were most resistant in early G1 and became progressively less resistant in S and G2/M, indicating that the S-phase resistance in wild-type cells requires HRR. Cells defective in NHEJ (dna-pk(cs) mutation) were exquisitely sensitive in early G1, most resistant in S phase, and then somewhat less resistant in G2/M. Fancg mutant cells had almost normal IR sensitivity and normal cell cycle dependence, suggesting that Fancg contributes modestly to survival and in a manner that is independent of cell cycle position.     

Characterization of G(1) Checkpoint Control in the Yeast Saccharomyces Cerevisiae following Exposure to DNA-Damaging Agents

The delay of S-phase following treatment of yeast cells with DNA-damaging agents is an actively regulated response that requires functional RAD9 and RAD24 genes. An analysis of cell cycle arrest indicates the existence of (at least) two checkpoints for damaged DNA prior to S-phase; one at START (a G(1) checkpoint characterized by pheromone sensitivity of arrested cells) and one between the CDC4- and CDC7-mediated steps (termed the G(1)/S checkpoint). When a dna1-1 mutant (that affects early events of replicon initiation) also carries a rad9 deletion mutation, it manifests a failure to arrest in G(1)/S following incubation at the restrictive temperature. This failure to execute regulated G(1)/S arrest is correlated with enhanced thermosensitivity of colony-forming ability. In an attempt to characterize the signal for RAD9 gene-dependent G(1) and G(1)/S cell cycle arrest, we examined the influence of the continued presence of unexcised photoproducts. In mutants defective in nucleotide excision repair, cessation of S-phase was observed at much lower doses of UV radiation compared to excision-proficient cells. However, this response was not RAD9-dependent. We suggest that an intermediate of nucleotide excision repair, such as DNA strand breaks or single-stranded DNA tracts, is required to activate RAD9-dependent G(1) and G(1)/S checkpoint controls.     

The checkpoint protein Rad24 of Saccharomyces cerevisiae is involved in processing double-strand break ends and in recombination partner choice

Upon chromosomal damage, cells activate a checkpoint response that includes cell cycle arrest and a stimulation of DNA repair. The checkpoint protein Rad24 is key to the survival of a single, repairable double-strand break (DSB). However, the low survival of rad24 cells is not due to their inability to arrest cell cycle progression. In rad24 mutants, processing of the broken ends is delayed and protracted, resulting in extended kinetics of DSB repair and in cell death. The limited resection of rad24 mutants also affects recombination partner choice by a mechanism dependent on the length of the interacting homologous donor sequences. Unexpectedly, rad24 cells with a DSB eventually accumulate and die at the G(2)/M phase of the cell cycle. This arrest depends on the spindle checkpoint protein Mad2.     

Small heat-shock protein Hsp9 has dual functions in stress adaptation and stress-induced G2-M checkpoint regulation via Cdc25 inactivation in Schizosaccharomyces pombe

The small heat-shock protein Hsp9 from Schizosaccharomyces pombe was previously reported to be a homologue of Saccharomyces cerevisiae HSP12. Although Hsp9 is expressed in response to heat shock and nutritional limitation, its function is still not completely understood. Here, we explored the biological function of Hsp9 in S. pombe. The hsp9 gene might play a role in stress adaptation; hsp9 deletion caused heat sensitivity and overexpression induced heat tolerance. In addition, Hsp9 also contribute to cell cycle regulation in the nucleus. Δhsp9 cells grew more quickly and were shorter in length than wild-type cells. Moreover, Δhsp9 cells did not achieve checkpoint arrest under stress conditions, leading to cell death, and exhibited a short doubling time and short G2 phase. Overexpression of hsp9 induced cell cycle delay, increased the population of G2 phase cells, and rescued the phenotypes of cdc2-33, cdc25-22, Δrad24, and Δrad25 mutants, suggesting that Hsp9 probably regulates Cdc2 phosphorylation by modulating the Cdc25 activity. Indeed, immunoprecipitation experiments revealed that Hsp9 is associated with 14-3-3 and Cdc25. In Δhsp9 cells, the association of 14-3-3 with Cdc25 was weakened and Cdc2 phosphorylaton was reduced. Together, our data suggest that Hsp9 has dual functions in stress adaptation and regulating a G2-M checkpoint by the Cdc25 inactivation; this differs from S. cerevisiae HSP12, which maintains cell membrane stability under stress conditions.     

Saccharomyces cerevisiae RAD53 (CHK2) but not CHK1 is required for double-strand break-initiated SCE and DNA damage-associated SCE after exposure to X rays and chemical agents

Saccharomyces cerevisiae RAD53 (CHK2) and CHK1 control two parallel branches of the RAD9-mediated pathway for DNA damage-induced G(2) arrest. Previous studies indicate that RAD9 is required for X-ray-associated sister chromatid exchange (SCE), suppresses homology-directed translocations, and is involved in pathways for double-strand break repair (DSB) repair that are different than those controlled by PDS1. We measured DNA damage-associated SCE in strains containing two tandem fragments of his3, his3-Delta5' and his3-Delta3'::HOcs, and rates of spontaneous translocations in diploids containing GAL1::his3-Delta5' and trp1::his3-Delta3'::HOcs. DNA damage-associated SCE was measured after log phase cells were exposed to methyl methanesulfonate (MMS), 4-nitroquinoline 1-oxide (4-NQO), UV, X rays and HO-induced DSBs. We observed that rad53 mutants were defective in MMS-, 4-NQO, X-ray-associated and HO-induced SCE but not in UV-associated SCE. Similar to rad9 pds1 double mutants, rad53 pds1 double mutants exhibited more X-ray sensitivity than the single mutants. rad53 sml1 diploid mutants exhibited a 10-fold higher rate of spontaneous translocations compared to the sml1 diploid mutants. chk1 mutants were not deficient in DNA damage-associated SCE after exposure to DNA damaging agents or after DSBs were generated at trp1::his3-Delta5'his3-Delta3'::HOcs. These data indicate that RAD53, not CHK1, is required for DSB-initiated SCE, and DNA damage-associated SCE after exposure to X-ray-mimetic and UV-mimetic chemicals.     

Mutations in SID2, a novel gene in Saccharomyces cerevisiae, cause synthetic lethality with sic1 deletion and may cause a defect during S phase

SIC1 encodes a nonessential B-type cyclin/CDK inhibitor that functions at the G1/S transition and the exit from mitosis. To understand more completely the regulation of these transitions, mutations causing synthetic lethality with sic1 Delta were isolated. In this screen, we identified a novel gene, SID2, which encodes an essential protein that appears to be required for DNA replication or repair. sid2-1 sic1 Delta strains and sid2-21 temperature-sensitive strains arrest preanaphase as large-budded cells with a single nucleus, a short spindle, and an approximately 2C DNA content. RAD9, which is necessary for the DNA damage checkpoint, is required for the preanaphase arrest of sid2-1 sic1 Delta cells. Analysis of chromosomes in mutant sid2-21 cells by field inversion gel electrophoresis suggests the presence of replication forks and bubbles at the arrest. Deleting the two S phase cyclins, CLB5 and CLB6, substantially suppresses the sid2-1 sic1 Delta inviability, while stabilizing Clb5 protein exacerbates the defects of sid2-1 sic1 Delta cells. In synchronized sid2-1 mutant strains, the onset of replication appears normal, but completion of DNA synthesis is delayed. sid2-1 mutants are sensitive to hydroxyurea indicating that sid2-1 cells may suffer DNA damage that, when combined with additional insult, leads to a decrease in viability. Consistent with this hypothesis, sid2-1 rad9 cells are dead or very slow growing even when SIC1 is expressed.     

Studies on mammalian mutants defective in rejoining double-strand breaks in DNA

Mutants with defects in the rejoining of DNA double-strand breaks (dsbs) have been identified and characterised from E. coli and the yeast, Saccharomyces cerevisiae. More recently, 3 mammalian cell mutants with defective dsb rejoining have also been described. These mutants are xrs, XR-1 and L5178Y/S, and they are derived from at least two distinct complementation groups. The aim of this article is to review the current status of the studies with these mammalian cell mutants which are defective in dsb rejoining and, in particular, to compare their properties with those mutants identified from lower organisms. Possible mechanistic differences in the process of dsb rejoining between prokaryotes and lower and higher eukaryotes are discussed. All the mammalian mutants defective in dsb rejoining, are sensitive primarily to ionising radiation with little cross-sensitivity to UV-radiation. This is similar to the rad52 mutants of S. cerevisiae but contrasts to the majority of the E. coli mutants with defective dsb rejoining. Where studied, the mammalian cell mutants show enhanced resistance to ionizing radiation in late S/G2 phase, which, in one case, correlates with an enhanced ability to rejoin dsbs. This, together with other evidence, suggests that two mechanisms of dsb rejoining may exist in higher eukaryotes, one which operates uniquely in S/G2 phase and a second mechanism operating throughout the cell cycle and dependent upon the xrs and XR-1 gene products (although whether the xrs and XR-1 dependent pathways are distinct cannot at present be ascertained). Since duplicate homologues will be present in late S/G2 phase cells, this pathway may involve a recombinational mechanism. The xrs-dependent pathway might involve illegitimate recombination, but the xrs mutants do not appear to have a major defect in homologous recombination (involving plasmid DNA) and in this respect are distinct from rad52 mutants.     

Analysis of Rad3 and Chk1 protein kinases defines different checkpoint responses.

Eukaryotic cells respond to DNA damage and S phase replication blocks by arresting cell-cycle progression through the DNA structure checkpoint pathways. In Schizosaccharomyces pombe, the Chk1 kinase is essential for mitotic arrest and is phosphorylated after DNA damage. During S phase, the Cds1 kinase is activated in response to DNA damage and DNA replication blocks. The response of both Chk1 and Cds1 requires the six 'checkpoint Rad' proteins (Rad1, Rad3, Rad9, Rad17, Rad26 and Hus1). We demonstrate that DNA damage-dependent phosphorylation of Chk1 is also cell-cycle specific, occurring primarily in late S phase and G2, but not during M/G1 or early S phase. We have also isolated and characterized a temperature-sensitive allele of rad3. Rad3 functions differently depending on which checkpoint pathway is activated. Following DNA damage, rad3 is required to initiate but not maintain the Chk1 response. When DNA replication is inhibited, rad3 is required for both initiation and maintenance of the Cds1 response. We have identified a strong genetic interaction between rad3 and cds1, and biochemical evidence shows a physical interaction is possible between Rad3 and Cds1, and between Rad3 and Chk1 in vitro. Together, our results highlight the cell-cycle specificity of the DNA structure-dependent checkpoint response and identify distinct roles for Rad3 in the different checkpoint responses. Keywords: ATM/ATR/cell-cycle checkpoints/Chk1/Rad3     

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.