The roles of human MTH1, MTH2 and MTH3 proteins in maintaining genome stability under oxidative stress.

The hydrolysis of nucleotides containing 8-oxo-7,8-dihydroguanine (8-oxoG) is important in the maintenance of genome stability. Human cells possess three types of proteins, MTH1 (NUDT1), MTH2 (NUDT15) and MTH3 (NUDT18), which have the potential to hydrolyze deoxyribonucleoside di- and triphosphates containing 8-oxoG to the monophosphate, the form of which is unusable for DNA synthesis. To elucidate the physiological roles of these enzymes, we constructed single knockout (KO) cell lines for each of the MTH1, MTH2 and MTH3 genes and MTH1 and MTH2-double KO cell lines from the human HeLa S3 line using CRISPR/Cas9. With the exception of MTH3-KO, all of the KO cell lines showed similar proliferation rates to the parental line, HeLa S3, indicating that the MTH1 and MTH2 functions are dispensable for cell growth. On the other hand, the MTH3-KO cells showed a significantly slower growth rate, suggesting that MTH3 has a definite role in cell growth in addition to the cleavage of 8-oxoG-containing deoxyribonucleotide. MTH1-KO, MTH2-KO and MTH1- MTH2-KO cells exhibited increased sensitivity to hydrogen peroxide, whereas MTH3-KO did not. MTH1-KO cells showed only a slight increase in mutant frequency in comparison to the parental HeLa S3 line. The overproduction of MTH1 and MTH2 suppressed the mutator phenotype of mutT-deficient E. coli cells, whereas the overproduction of MTH3 did not show such a suppressive effect. Our findings suggest that both MTH1 and MTH2 are involved in the maintaining genome stability in human cells against oxidative stress, while MTH3 may play some other role(s).

Homologous recombination is required for recovery from oxidative DNA damage.

We have been studying the genetic events, including chromosome loss, chromosome rearrangements and intragenic point mutations, that are responsible for the deletion of a URA3 marker in a loss of heterozygosity (LOH) assay in the yeast Saccharomycess cerevisiae. With this assay, we previously showed that homologous recombination plays an important role in genome maintenance in response to DNA lesions that occur spontaneously in normally growing cells. Here, to investigate DNA lesions capable of triggering homologous recombination, we examined the effects of oxidative stress, a prominent cause of endogenous DNA damage, on LOH events. Treatment of log-phase cells with H2O2 first caused growth arrest and then, during the subsequent recovery, chromosome loss and various chromosome rearrangements were induced more than 10-fold. Further analysis of the rearrangements showed that gene conversion was strongly induced, approximately 100 times more frequently than in untreated cells. Consistent with these results, two diploid strains deficient for homologous recombination, rad52Δ/rad52Δ and rad51Δ/rad51Δ, were sensitive to H2O2 treatment. In addition, chromosome DNA breaks were detected in H2O2-treated cells using pulsed-field gel electrophoresis. Altogether, these results suggest that oxidative stress induced recombinogenic lesions on chromosomes, which then triggered homologous recombination leading to chromosome rearrangements, and that this response contributed to the survival of cells afflicted by oxidative DNA damage. We therefore conclude that homologous recombination is required for the recovery of cells from oxidative stress.

Phenyl hydroquinone, an Ames test-negative carcinogen, induces Hog1-dependent stress response signaling.

Recently, we have shown that phenyl hydroquinone, a hepatic metabolite of the Ames test-negative carcinogen o-phenylphenol, efficiently induced aneuploidy in Saccharomyces cerevisiae. We further found that phenyl hydroquinone arrested the cell cycle at G(1) and G(2)/M. In this study, we demonstrate that phenyl hydroquinone can arrest the cell cycle at the G(2)/M transition as a result of stabilization of Swe1 (a Wee1 homolog), probably leading to inactivation of Cdc28 (a Cdk1/Cdc2 homolog). Furthermore, Hog1 (a p38 MAPK homolog) was robustly phosphorylated by phenyl hydroquinone, which can stabilize Swe1. On the other hand, Chk1 and Rad53 were not phosphorylated by phenyl hydroquinone, indicating that the Mec1/Tel1 DNA-damage checkpoint was not functional. Mutations of swe1 and hog1 abolished phenyl hydroquinone-induced arrest at the G(2)/M transition and the cells became resistant to phenyl hydroquinone lethality and aneuploidy development. These data suggest that a phenyl hydroquinone-induced G(2)/M transition checkpoint that is activated by the Hog1-Swe1 pathway plays a role in the development of aneuploidy.

Positive and negative roles of homologous recombination in the maintenance of genome stability in Saccharomyces cerevisiae.

In previous studies of the loss of heterozygosity (LOH), we analyzed a hemizygous URA3 marker on chromosome III in S. cerevisiae and showed that homologous recombination is involved in processes that lead to LOH in multiple ways, including allelic recombination, chromosome size alterations, and chromosome loss. To investigate the role of homologous recombination more precisely, we examined LOH events in rad50 Delta, rad51 Delta, rad52 Delta, rad50 Delta rad52 Delta, and rad51 Delta rad52 Delta mutants. As compared to Rad(+) cells, the frequency of LOH was significantly increased in all mutants, and most events were chromosome loss. Other LOH events were differentially affected in each mutant: the frequencies of all types of recombination were decreased in rad52 mutants and enhanced in rad50 mutants. The rad51 mutation increased the frequency of ectopic but not allelic recombination. Both the rad52 and rad51 mutations increased the frequency of intragenic point mutations approximately 25-fold, suggesting that alternative mutagenic pathways partially substitute for homologous recombination. Overall, these results indicate that all of the genes are required for chromosome maintenance and that they most likely function in homologous recombination between sister chromatids. In contrast, other recombination pathways can occur at a substantial level even in the absence of one of the genes and contribute to generating various chromosome rearrangements.

Involvement of RAD9-dependent damage checkpoint control in arrest of cell cycle, induction of cell death, and chromosome instability caused by defects in origin recognition complex in Saccharomyces cerevisiae.

Perturbation of origin firing in chromosome replication is a possible cause of spontaneous chromosome instability in multireplicon organisms. Here, we show that chromosomal abnormalities, including aneuploidy and chromosome rearrangement, were significantly increased in yeast diploid cells with defects in the origin recognition complex. The cell cycle of orc1-4/orc1-4 temperature-sensitive mutant was arrested at the G2/M boundary, after several rounds of cell division at the restrictive temperature. However, prolonged incubation of the mutant cells at 37 degrees C led to abrogation of G2 arrest, and simultaneously the cells started to lose viability. A sharp increase in chromosome instability followed the abrogation of G2 arrest. In orc1-4/orc1-4 rad9delta/rad9delta diploid cells grown at 37 degrees C, G2 arrest and induction of cell death were suppressed, while chromosome instability was synergistically augmented. These findings indicated that DNA lesions caused by a defect in Orc1p function trigger the RAD9-dependent checkpoint control, which ensures genomic integrity either by stopping the cell cycle progress until lesion repair, or by inducing cell death when the lesion is not properly repaired. At semirestrictive temperatures, orc2-1/orc2-1 diploid cells demonstrated G2 arrest and loss of cell viability, both of which require RAD9-dependent checkpoint control. However, chromosome instability was not induced in orc2-1/orc2-1 cells, even in the absence of the checkpoint control. These data suggest that once cells lose the damage checkpoint control, perturbation of origin firing can be tolerated by the cells. Furthermore, although a reduction in origin-firing capacity does not necessarily initiate chromosome instability, the Orc1p possesses a unique function, the loss of which induces instability in the chromosome.

Elevated incidence of loss of heterozygosity (LOH) in an sgs1 mutant of Saccharomyces cerevisiae: roles of yeast RecQ helicase in suppression of aneuploidy, interchromosomal rearrangement, and the simultaneous incidence of both events during mitotic growth.

The SGS1 gene of Saccharomyces cerevisiae is a member of the RecQ helicase family, which includes the human BLM, WRN and RECQL4 genes responsible for Bloom and Werner's syndrome and Rothmund-Thomson syndrome, respectively. Cells defective in any of these genes exhibit a higher incidence of genome instability. We previously demonstrated that various genetic alterations were detectable as events leading to loss of heterozygosity (LOH) in S. cerevisiae diploid cells, utilizing a hemizygous URA3 marker placed at the center of the right arm of chromosome III. Analyses of chromosome structure in LOH clones by pulse field gel electrophoresis (PFGE) and PCR, coupled with a genetic method, allow identification of genetic alterations leading to the LOH. Such alterations include chromosome loss, chromosomal rearrangements at various locations and intragenic mutation. In this work, we have investigated the LOH events occurring in cells lacking the SGS1 gene. The frequencies of all types of LOH events, excluding intragenic mutation, were increased in sgs1 null mutants as compared to the wild-type cells. Loss of chromosome III and chromosomal rearrangements were increased 13- and 17-fold, respectively. Further classification of the chromosomal rearrangements confirmed that two kinds of events were especially increased in the sgs1 mutants: (1) ectopic recombination between chromosomes, that is, unequal crossing over and translocation (46-fold); and (2) allelic crossing over associated with chromosome loss (40-fold). These findings raise the possibility that the Sgs1 protein is involved in the processing of recombination intermediates as well as in the prevention of recombination repair during chromosome DNA replication. On the other hand, intrachromosomal deletions between MAT and HMR were increased only slightly (2.9-fold) in the sgs1 mutants. These results clearly indicate that defects in the SGS1 gene function lead to an elevated incidence of LOH in multiple ways, including chromosome loss and interchromosomal rearrangements, but not intrachromosomal deletion.

Structural analysis of aberrant chromosomes that occur spontaneously in diploid Saccharomyces cerevisiae: retrotransposon Ty1 plays a crucial role in chromosomal rearrangements.

The structural analysis of aberrant chromosomes is important for our understanding of the molecular mechanisms underlying chromosomal rearrangements. We have identified a number of diploid Saccharomyces cerevisiae clones that have undergone loss of heterozygosity (LOH) leading to functional inactivation of the hemizygous URA3 marker placed on the right arm of chromosome III. Aberrant-sized chromosomes derived from chromosome III were detected in approximately 8% of LOH clones. Here, we have analyzed the structure of the aberrant chromosomes in 45 LOH clones with a PCR-based method that determines the ploidy of a series of loci on chromosome III. The alterations included various deletions and amplifications. Sequencing of the junctions revealed that all the breakpoints had been made within repeat sequences in the yeast genome, namely, MAT-HMR, which resulted in intrachromosomal deletion, and retrotransposon Ty1 elements, which were involved in various translocations. Although the translocations involved different breakpoints on different chromosomes, all breakpoints were exclusively within Ty1 elements. Some of the resulting Ty1 elements left at the breakpoints had a complex construction that indicated the involvement of other Ty1 elements not present at the parental breakpoints. These indicate that Ty1 elements are crucially involved in the generation of chromosomal rearrangements in diploid yeast cells.