Saccharomyces cerevisiae MGS1 is essential in strains deficient in the RAD6-dependent DNA damage tolerance pathway

Mgs1 and Rad18/Rad5/Mms2 are required for survival of Saccharomyces cerevisiae mutants with novel temperature/cold sensitive alleles of the DNA polymerase δ subunit, Pol31

Saccharomyces cerevisiae DNA polymerase delta (Pol delta) is a heterotrimeric enzyme consisting of Pol3 (the catalytic subunit), Pol31 and Pol32. New pol31 alleles were constructed by introducing mutations into conserved amino acid residues in all 10 identified regions of Pol31. Six novel temperature-sensitive (ts) or cold-sensitive (cs) alleles, carrying mutations in regions III, IV, VII, VIII or IX, conferred a range of defects in the response to replication stress or DNA damage. Deletion of SGS1, RAD52, SRS2, MRC1 or RAD24 had a deleterious effect only in combination with those pol31 alleles that had a phenotype as single mutants, suggesting a requirement for recombination and checkpoint functions in processing the DNA lesions or structures that form as a consequence of replication with a defective Pol delta. In contrast, deletion of POL32 negatively affected the growth of almost all pol31 mutants, suggesting an important role for all conserved amino acids of Pol31 in maintaining the integrity of Pol delta complex structurally, at least in the absence of the third subunit. Surprisingly, deletions of RAD18 and MGS1 aggravated the temperature sensitivity conferred by most ts or cs alleles and specifically suppressed the hys2-1 and hys2-1-like mutations of POL31. Deletion of RAD5 or MMS2 had an effect on pol31 ts/cs mutants similar to that of RAD18, whereas deletion of RAD30 or REV3 had no effect. We propose that Rad18/Rad5/Mms2 and Mgs1 are required to promote replication when forks are destabilized or stalled due to defects in Pol delta. These data are consistent with the biochemical activity of the human Mgs1 orthologue, which binds and stimulates Pol deltain vitro. We also demonstrate that Mgs1 interacts physically with Pol31 in vivo. Moreover, regions I and VII of Pol31, which are specifically sensitive to high levels of Mgs1 and PCNA, could be sites of interaction.

Replication-dependent and -independent responses of RAD18 to DNA damage in human cells

Postreplication repair facilitates tolerance of DNA damage during replication, overcoming termination of replication at sites of DNA damage. A major post-replication repair pathway in mammalian cells is translesion synthesis, which is carried out by specialized polymerase(s), such as polymerase eta, and is identified by focus formation by the polymerase after irradiation with UVC light. The formation of these foci depends on RAD18, which ubiquitinates PCNA for the exchange of polymerases. To understand the initial processes in translesion synthesis, we have here analyzed the response to damage of RAD18 in human cells. We find that human RAD18 accumulates very rapidly and remains for a long period of time at sites of different types of DNA damage, including UVC light-induced lesions, and x-ray microbeam- and laser-induced single-strand breaks, in a cell cycle-independent manner. The accumulation of RAD18 at DNA damage is observed even when DNA replication is inhibited, and a small region containing a zinc finger motif located in the middle of RAD18 is essential and sufficient for the replication-independent damage accumulation. The zinc finger motif of RAD18 is not necessary for UV-induced polymerase eta focus formation, but another SAP (SAF-A/B, Acinus and PIAS) motif near the zinc finger is required. These data indicate that RAD18 responds to DNA damage in two distinct ways, one replication-dependent and one replication-independent, involving the SAP and zinc finger motifs, respectively.

Analyses of the interaction of WRNIP1 with Werner syndrome protein (WRN) in vitro and in the cell

Werner was originally identified as a protein that interacts with the product of the Werner syndrome (WS) gene, WRN. To examine the function of the WRNIP1/WRN complex in cells, we generated knock-out cell lines that were deficient in either WRN (WRN(-/-)), WRNIP1 (WRNIP10(-/-/-)), or both (WRNIP1(-/-/-)/WRN(-/-)), using a chicken B lymphocyte cell line, DT40. WRNIP1(-/-/-)/WRN(-/-) DT40 cells grew at a similar rate as wild-type cells, but the rate of spontaneous sister-chromatid exchange was augmented compared to that of either of the single mutant cell lines. Moreover, while WRNIP1(-/-/-) and WRN(-/-) cells were moderately sensitive to camptothecin (CPT), double mutant cells showed a synergistic increase in CPT sensitivity. This suggested that WRNIP1 and WRN do not always function cooperatively to repair DNA lesions. The lack of a discernable functional interaction between WRNIP1 and WRN prompted us to reevaluate the nature of the physical interaction between these proteins. We found that MBP-tagged WRNIP1 interacted directly with WRN, and that the interaction was enhanced by the addition of ATP. Mutations in the Walker A motifs of the two proteins revealed that WRNIP1, but not WRN, must bind ATP before an efficient interaction can occur.

Functional and physical interaction of yeast Mgs1 with PCNA: impact on RAD6-dependent DNA damage tolerance

Proliferating cell nuclear antigen (PCNA), a sliding clamp required for processive DNA synthesis, provides attachment sites for various other proteins that function in DNA replication, DNA repair, cell cycle progression and chromatin assembly. It has been shown that differential posttranslational modifications of PCNA by ubiquitin or SUMO play a pivotal role in controlling the choice of pathway for rescuing stalled replication forks. Here, we explored the roles of Mgs1 and PCNA in replication fork rescue. We provide evidence that Mgs1 physically associates with PCNA and that Mgs1 helps suppress the RAD6 DNA damage tolerance pathway in the absence of exogenous DNA damage. We also show that PCNA sumoylation inhibits the growth of mgs1 rad18 double mutants, in which PCNA sumoylation and the Srs2 DNA helicase coordinately prevent RAD52-dependent homologous recombination. The proposed roles for Mgs1, Srs2, and modified PCNA during replication arrest highlight the importance of modulating the RAD6 and RAD52 pathways to avoid genome instability.

Accumulation of FFA-1, the Xenopus homolog of Werner helicase, and DNA polymerase delta on chromatin in response to replication fork arrest

Werner syndrome is a genetic disorder characterized by premature aging and cancer-prone symptoms, and is caused by mutation of the WRN gene. WRN is a member of the RecQ helicase family and is thought to function in processes implicated in DNA replication and repair to maintain genome stability; however, its precise function is still unclear. We found that replication fork arrest markedly enhances chromatin binding of focus-forming activity 1 (FFA-1), a Xenopus WRN homolog, in Xenopus egg extracts. In addition to FFA-1, DNA polymerase delta (Poldelta) and replication protein A, but not DNA polymerase epsilon and proliferating cell nuclear antigen, accumulated increasingly on replication-arrested chromatin. Elevated accumulation of these proteins was dependent on formation of pre-replicative complexes (pre-RCs). Double-strand break (DSB) formation also enhanced chromatin binding of FFA-1, but not Poldelta, independently of pre-RC formation. In contrast to FFA-1, chromatin binding of Xenopus Bloom syndrome helicase (xBLM) only slightly increased after replication arrest or DSB formation. Thus, WRN-specific, distinct processes can be reproduced in the in vitro system in egg extracts, and this system is useful for biochemical analysis of WRN functions during DNA metabolism.

In vivo and in vitro studies of Mgs1 suggest a link between genome instability and Okazaki fragment processing

The non-essential MGS1 gene of Saccharomyces cerevisiae is highly conserved in eukaryotes and encodes an enzyme containing both DNA-dependent ATPase and DNA annealing activities. MGS1 appears to function in post-replicational repair processes that contribute to genome stability. In this study, we identified MGS1 as a multicopy suppressor of the temperature-sensitive dna2Delta405N mutation, a DNA2 allele lacking the N-terminal 405 amino acid residues. Mgs1 stimulates the structure-specific nuclease activity of Rad27 (yeast Fen1 or yFen1) in an ATP-dependent manner. ATP binding but not hydrolysis was sufficient for the stimulatory effect of Mgs1, since non-hydrolyzable ATP analogs are as effective as ATP. Suppression of the temperature-sensitive growth defect of dna2Delta405N required the presence of a functional copy of RAD27, indicating that Mgs1 suppressed the dna2Delta405N mutation by increasing the activity of yFen1 (Rad27) in vivo. Our results provide in vivo and in vitro evidence that Mgs1 is involved in Okazaki fragment processing by modulating Fen1 activity. The data presented raise the possibility that the absence of MGS1 may impair the processing of Okazaki fragments, leading to genomic instability.

Human Werner helicase interacting protein 1 (WRNIP1) functions as a novel modulator for DNA polymerase delta

Human WRNIP1, a Werner DNA helicase interacting protein 1, was expressed in insect cells and E. coli. The purified protein behaved as a homo-oligomeric complex with a native molecular mass indicative of an octamer, and the complex copurified with an ATPase activity that was stimulated by double-stranded DNA ends. As suggested by genetic studies of budding yeast WRNIP1/Mgs1, the purified human WRNIP1 complex interacted physically with human DNA polymerase delta (pol delta), stimulating its DNA synthesis activity more than fivefold in the presence or absence of proliferating cell nuclear antigen. Analysis of reaction products demonstrated the stimulation to be partly due to an increased processivity of pol delta but more importantly to an increase in its initiation frequency. Addition of ATP to reactions partially suppressed stimulation by WRNIP1. Furthermore, a mutant WRNIP1 lacking ATPase activity could stimulate pol delta normally but was insensitive to suppression by ATP. These results indicate that WRNIP1 functions as a modulator for initiation or restart events during pol delta-mediated DNA synthesis and that its ATPase activity is utilized to sense DNA ends and to regulate the extent of stimulation.

Functional overlap between RecA and MgsA (RarA) in the rescue of stalled replication forks in Escherichia coli

Escherichia coli RecA protein plays a role in DNA homologous recombination, recombination repair, and the rescue of stalled or collapsed replication forks. The mgsA (rarA) gene encodes a highly conserved DNA-dependent ATPase, whose yeast orthologue, MGS1, plays a role in maintaining genomic stability. In this study, we show a functional relationship between mgsA and recA during DNA replication. The mgsA recA double mutant grows more slowly and has lower viability than a recA single mutant, but they are equally sensitive to UV-induced DNA damage. Mutations in mgsA and recA cause lethality in DNA polymerase I deficient cells, and suppress the temperature-dependent growth defect of dnaE486 (Pol III alpha-catalytic subunit). Moreover, recAS25P, a novel recA allele identified in this work, does not complement the slow growth of DeltamgsA DeltarecA cells or the lethality of polA12 DeltarecA, but is proficient in DNA repair, homologous recombination, SOS mutagenesis and SOS induction. These results suggest that RecA and MgsA are functionally redundant in rescuing stalled replication forks, and that the DNA repair and homologous recombination functions of RecA are separated from its function to maintain progression of replication fork.

Yeast MPH1 gene functions in an error-free DNA damage bypass pathway that requires genes from Homologous recombination, but not from postreplicative repair

The MPH1 gene from Saccharomyces cerevisiae, encoding a member of the DEAH family of proteins, had been identified by virtue of the spontaneous mutator phenotype of respective deletion mutants. Genetic analysis suggested that MPH1 functions in a previously uncharacterized DNA repair pathway that protects the cells from damage-induced mutations. We have now analyzed genetic interactions of mph1 with a variety of mutants from different repair systems with respect to spontaneous mutation rates and sensitivities to different DNA-damaging agents. The dependence of the mph1 mutator phenotype on REV3 and REV1 and the synergy with mutations in base and nucleotide excision repair suggest an involvement of MPH1 in error-free bypass of lesions. However, although we observed an unexpected partial suppression of the mph1 mutator phenotype by rad5, genetic interactions with other mutations in postreplicative repair imply that MPH1 does not belong to this pathway. Instead, mutations from the homologous recombination pathway were found to be epistatic to mph1 with respect to both spontaneous mutation rates and damage sensitivities. Determination of spontaneous mitotic recombination rates demonstrated that mph1 mutants are not deficient in homologous recombination. On the contrary, in an sgs1 background we found a pronounced hyperrecombination phenotype. Thus, we propose that MPH1 is involved in a branch of homologous recombination that is specifically dedicated to error-free bypass.

DSB repair: the yeast paradigm

Genome stability is of primary importance for the survival and proper functioning of all organisms. Double-strand breaks (DSBs) arise spontaneously during growth, or can be created by external insults. In response to even a single DSB, organisms must trigger a series of events to promote repair of the DNA damage in order to survive and restore chromosomal integrity. In doing so, cells must regulate a fine balance between potentially competing DSB repair pathways. These are generally classified as either homologous recombination (HR) or non-homologous end joining (NHEJ). The yeast Saccharomyces cerevisiae is an ideal model organism for studying these repair processes. Indeed, much of what we know today on the mechanisms of repair in eukaryotes come from studies carried out in budding yeast. Many of the proteins involved in the various repair pathways have been isolated and the details of their mode of action are currently being unraveled at the molecular level. In this review, we focus on exciting new work eminating from yeast research that provides fresh insights into the DSB repair process. This recent work supplements and complements the wealth of classical genetic research that has been performed in yeast systems over the years. Given the conservation of the repair mechanisms and genes throughout evolution, these studies have profound implications for other eukaryotic organisms.

A new Saccharomyces cerevisiae strain with a mutant Smt3-deconjugating Ulp1 protein is affected in DNA replication and requires Srs2 and homologous recombination for its viability

The Saccharomyces cerevisiae Srs2 protein is involved in DNA repair and recombination. In order to gain better insight into the roles of Srs2, we performed a screen to identify mutations that are synthetically lethal with an srs2 deletion. One of them is a mutated allele of the ULP1 gene that encodes a protease specifically cleaving Smt3-protein conjugates. This allele, ulp1-I615N, is responsible for an accumulation of Smt3-conjugated proteins. The mutant is unable to grow at 37 degrees C. At permissive temperatures, it still shows severe growth defects together with a strong hyperrecombination phenotype and is impaired in meiosis. Genetic interactions between ulp1 and mutations that affect different repair pathways indicated that the RAD51-dependent homologous recombination mechanism, but not excision resynthesis, translesion synthesis, or nonhomologous end-joining processes, is required for the viability of the mutant. Thus, both Srs2, believed to negatively control homologous recombination, and the process of recombination per se are essential for the viability of the ulp1 mutant. Upon replication, mutant cells accumulate single-stranded DNA interruptions. These structures are believed to generate different recombination intermediates. Some of them are fixed by recombination, and others require Srs2 to be reversed and fixed by an alternate pathway.

Yeast MPH1 Gene Functions in an Error-Free DNA Damage Bypass Pathway That Requires Genes From Homologous Recombination, but Not From Postreplicative Repair

The MPH1 gene from Saccharomyces cerevisiae, encoding a member of the DEAH family of proteins, had been identified by virtue of the spontaneous mutator phenotype of respective deletion mutants. Genetic analysis suggested that MPH1 functions in a previously uncharacterized DNA repair pathway that protects the cells from damage-induced mutations. We have now analyzed genetic interactions of mph1 with a variety of mutants from different repair systems with respect to spontaneous mutation rates and sensitivities to different DNA-damaging agents. The dependence of the mph1 mutator phenotype on REV3 and REV1 and the synergy with mutations in base and nucleotide excision repair suggest an involvement of MPH1 in error-free bypass of lesions. However, although we observed an unexpected partial suppression of the mph1 mutator phenotype by rad5, genetic interactions with other mutations in postreplicative repair imply that MPH1 does not belong to this pathway. Instead, mutations from the homologous recombination pathway were found to be epistatic to mph1 with respect to both spontaneous mutation rates and damage sensitivities. Determination of spontaneous mitotic recombination rates demonstrated that mph1 mutants are not deficient in homologous recombination. On the contrary, in an sgs1 background we found a pronounced hyperrecombination phenotype. Thus, we propose that MPH1 is involved in a branch of homologous recombination that is specifically dedicated to error-free bypass.

Rapid transcriptome responses of maize (Zea mays) to UV-B in irradiated and shielded tissues

Profiling the transcriptional response of maize tissues to UV-B irradiation suggests that a signal is transmitted from irradiated to shielded tissue. The transcriptional response occurs rapidly, even in shielded tissue.

Background

Depletion of stratospheric ozone has raised terrestrial levels of ultraviolet-B radiation (UV-B), an environmental change linked to an increased risk of skin cancer and with potentially deleterious consequences for plants. To better understand the processes of UV-B acclimation that result in altered plant morphology and physiology, we investigated gene expression in different organs of maize at several UV-B fluence rates and exposure times.

Results

Microarray hybridization was used to assess UV-B responses in directly exposed maize organs and organs shielded by a plastic that absorbs UV-B. After 8 hours of high UV-B, the abundance of 347 transcripts was altered: 285 were increased significantly in at least one organ and 80 were downregulated. More transcript changes occurred in directly exposed than in shielded organs, and the levels of more transcripts were changed in adult compared to seedling tissues. The time course of transcript abundance changes indicated that the response kinetics to UV-B is very rapid, as some transcript levels were altered within 1 hour of exposure.

Conclusions

Most of the UV-B regulated genes are organ-specific. Because shielded tissues, including roots, immature ears, and leaves, displayed altered transcriptome profiles after exposure of the plant to UV-B, some signal(s) must be transmitted from irradiated to shielded tissues. These results indicate that there are integrated responses to UV-B radiation above normal levels. As the same total UV-B irradiation dose applied at three intensities elicited different transcript profiles, the transcriptome changes exhibit threshold effects rather than a reciprocal dose-effect response. Transcriptome profiling highlights possible signaling pathways and molecules for future research.

Characterization of mutations that are synthetic lethal with pol3-13, a mutated allele of DNA polymerase delta in Saccharomyces cerevisiae

The pol3-13 mutation is located in the C-terminal end of POL3, the gene encoding the catalytic subunit of polymerase delta, and confers thermosensitivity onto the Saccharomyces cerevisiae mutant strain. To get insight about DNA replication control, we performed a genetic screen to identify genes that are synthetic lethal with pol3-13. Mutations in genes encoding the two other subunits of DNA polymerase delta (HYS2, POL32) were identified. Mutations in two recombination genes (RAD50, RAD51) were also identified, confirming that homologous recombination is necessary for pol3-13 mutant strain survival. Other mutations were identified in genes involved in repair and genome stability (MET18/ MMS19), in the control of origin-firing and/or transcription (ABF1, SRB7), in the S/G2 checkpoint (RAD53), in the Ras-cAMP signal transduction pathway (MKS1), in nuclear pore metabolism (SEH1), in protein degradation (DOC1) and in folding (YDJ1). Finally, mutations in three genes of unknown function were isolated (NBP35, DRE2, TAH18). Synthetic lethality between pol3-13 and each of the three mutants pol32, mms19 and doc1 could be suppressed by a rad18 deletion, suggesting an important role of ubiquitination in DNA replication control. We propose that the pol3-13 mutant generates replicative problems that need both homologous recombination and an intact checkpoint machinery to be overcome.

Bre1, an E3 ubiquitin ligase required for recruitment and substrate selection of Rad6 at a promoter

Ubiquitination of histone H2B catalyzed by Rad6 is required for methylation of histone H3 by COMPASS. We identified Bre1 as the probable E3 for Rad6's role in transcription. Bre1 contains a C3HC4 (RING) finger and is present with Rad6 in a complex. The RING finger of Bre1 is required for ubiquitination of histone H2B, methylation of lysine 4 and 79 of H3 and for telomeric silencing. Chromatin immunoprecipitation experiments indicated that both Rad6 and Bre1 are recruited to a promoter. Bre1 is essential for this recruitment of Rad6 and is dedicated to the transcriptional pathway of Rad6. These results suggest that Bre1 is the likely E3 enzyme that directs Rad6 to modify chromatin and ultimately to affect gene expression.

Methylation of histone H3 by COMPASS requires ubiquitination of histone H2B by Rad6

The DNA of eukaryotes is wrapped around nucleosomes and packaged into chromatin. Covalent modifications of the histone proteins that comprise the nucleosome alter chromatin structure and have major effects on gene expression. Methylation of lysine 4 of histone H3 by COMPASS is required for silencing of genes located near chromosome telomeres and within the rDNA (Krogan, N. J, Dover, J., Khorrami, S., Greenblatt, J. F., Schneider, J., Johnston, M., and Shilatifard, A. (2002) J. Biol. Chem. 277, 10753-10755; Briggs, S. D., Bryk, M., Strahl, B. D., Cheung, W. L., Davie, J. K., Dent, S. Y., Winston, F., and Allis, C. D. (2001) Genes. Dev. 15, 3286-3295). To learn about the mechanism of histone methylation, we surveyed the genome of the yeast Saccharomyces cerevisiae for genes necessary for this process. By analyzing approximately 4800 mutant strains, each deleted for a different non-essential gene, we discovered that the ubiquitin-conjugating enzyme Rad6 is required for methylation of lysine 4 of histone H3. Ubiquitination of histone H2B on lysine 123 is the signal for the methylation of histone H3, which leads to silencing of genes located near telomeres.

Characterization of the slow-growth phenotype of S. cerevisiae Whip/Mgs1 Sgs1 double deletion mutants

RecQ DNA helicases from many organisms have been indicated to function in the maintenance of genomic stability. In human cells, mutation in the WRN helicase, a RecQ-like DNA helicase, results in the Werner syndrome (WS), a genetic disorder characterized by genomic instability and premature ageing. Similarly, mutation in SGS1, the RECQ homologue in budding yeast, results in genomic instability and accelerated ageing. We previously demonstrated that mouse WRN interacts physically with a novel, highly conserved protein that we named WHIP, and that in budding yeast cells, simultaneous deletion of WHIP/MGS1 and SGS1 results in slow growth and shortened life span. Here we show by using genetic analysis in Saccharomyces cerevisiae that mgs1Delta sgs1Delta cells have increased rates of terminal G2/M arrest, and show elevated rates of spontaneous sister chromatid recombination (SCR) and rDNA array recombination. Finally, we report that complementation of the synthetic relationship between SGS1 and WHIP/MGS1 requires both the helicase and Top3-binding activities of Sgs1, as well as the ATPase activity of Mgs1. Our results suggest that Whip/Mgs1 is implicated in DNA metabolism, and is required for normal growth and cell cycle progression in the absence of Sgs1.