UV irradiation causes the loss of viable mitotic recombinants in Schizosaccharomyces pombe cells lacking the G(2)/M DNA damage checkpoint

Elevated mitotic recombination and cell cycle delays are two of the cellular responses to UV-induced DNA damage. Cell cycle delays in response to DNA damage are mediated via checkpoint proteins. Two distinct DNA damage checkpoints have been characterized in Schizosaccharomyces pombe: an intra-S-phase checkpoint slows replication and a G(2)/M checkpoint stops cells passing from G(2) into mitosis. In this study we have sought to determine whether UV damage-induced mitotic intrachromosomal recombination relies on damage-induced cell cycle delays. The spontaneous and UV-induced recombination phenotypes were determined for checkpoint mutants lacking the intra-S and/or the G(2)/M checkpoint. Spontaneous mitotic recombinants are thought to arise due to endogenous DNA damage and/or intrinsic stalling of replication forks. Cells lacking only the intra-S checkpoint exhibited no UV-induced increase in the frequency of recombinants above spontaneous levels. Mutants lacking the G(2)/M checkpoint exhibited a novel phenotype; following UV irradiation the recombinant frequency fell below the frequency of spontaneous recombinants. This implies that, as well as UV-induced recombinants, spontaneous recombinants are also lost in G(2)/M mutants after UV irradiation. Therefore, as well as lack of time for DNA repair, loss of spontaneous and damage-induced recombinants also contributes to cell death in UV-irradiated G(2)/M checkpoint mutants.     

Mutants of Cercospora kikuchii Altered in Cercosporin Synthesis and Pathogenicity

We have obtained spontaneous and UV-induced stable mutants, altered in the synthesis of cercosporin, of the fungal soybean pathogen Cercospora kikuchii. The mutants were isolated on the basis of colony color on minimal medium. The UV-induced mutants accumulated, at most, 2% of wild-type cercosporin levels on all media tested. In contrast, cercosporin accumulation by the spontaneous mutants was strongly medium regulated, occurring only on potato dextrose medium but at concentrations comparable to those produced by the wild-type strain. UV-induced mutants unable to synthesize cercosporin on any medium were unable to incite lesions when inoculated onto the soybean host. Cercosporin was reproducibly isolated from all inoculated leaves showing lesions. Although cercosporin involvement in disease has been indirectly suggested by many previous studies, this is the first report in which mutants blocked in cercosporin synthesis have been used to demonstrate that cercosporin is a crucial pathogenicity factor for this fungal genus.     

Characterization of Postreplication Repair in Mutagen-Sensitive Strains of DROSOPHILA MELANOGASTER

Mutants of Drosophila melanogaster, with suspected repair deficiencies, were analyzed for their capacity to repair damage induced by X-rays and UV radiation. Analysis was performed on cell cultures derived from embryos of homozygous mutant stocks. Postreplication repair following UV radiation has been analyzed in mutant stocks derived from a total of ten complementation groups. Cultures were irradiated, pulse-labeled, and incubated in the dark prior to analysis by alkaline sucrose gradient centrifugation. Kinetics of the molecular weight increase in newly synthesized DNA were assayed after cells had been incubated in the presence or absence of caffeine. Two separate pathways of postreplication repair have been tentatively identified by mutants derived from four complementation groups. The proposed caffeine sensitive pathway (CAS) is defined by mutants which also disrupt meiosis. The second pathway (CIS) is caffeine insensitive and is not yet associated with meiotic functions. All mutants deficient in postreplication repair are also sensitive to nitrogen mustard. The mutants investigated display a normal capacity to repair single-strand breaks induced in DNA by X-rays, although two may possess a reduced capacity to repair damage caused by localized incorporation of high specific activity thymidine-³H. The data have been employed to construct a model for repair of UV-induced damage in Drosophila DNA. Implications of the model for DNA repair in mammals are discussed.     

Mitotic Recombination in Yeast: Isolation and Characterization of Mutants with Enhanced Spontaneous Mitotic Gene Conversion Rates

Semi-dominant mutants displaying greatly elevated (up to 200-fold above control) levels of spontaneous mitotic recombination have been isolated in a disomic haploid strain of yeast heteroallelic at the arg4 locus. They are designated by the symbol MIC. The mutants variously exhibit associated sensitivity to UV and ionizing radiation and to methyl methanesulfonate, enhanced UV-induced mitotic recombination, and enhanced spontaneous forward mutation rates. Possible enzyme defects and involvement in repair and editing of DNA are discussed. The mutants are expected to simplify the analysis of recombination pathways in yeast.     

Effects of inhibitors of DNA synthesis on spontaneous and ultraviolet light-induced sister-chromatid exchanges in Chinese hamster cells

Effects of inhibitors of DNA synthesis on spontaneous and ultraviolet light (UV)-induced sister-chromatid exchanges (SCE) were examined in a Chinese hamster cell line, V79 B-1. The inhibitors used were hydroxyurea (HU), 1-beta-D-arabinofuranosylcytosine (ara-C), aphidicolin (APC), 2',3'-dideoxythymidine triphosphate (ddTTP), neocarzinostatin (NCS), novobiocin (NB) and cycloheximide (CHX). HU, ara-C, and APC increased spontaneous SCE frequency, and had a synergistic effect on UV-induced SCE frequency. DdTTP, NCS and NB failed to show any statistically significant effect on either spontaneous or UV-induced SCE frequencies, though NCS and NB did slightly increase both spontaneous and UV-induced SCE frequencies. On the contrary, CHX decreased spontaneous SCE frequency, and more drastically, also UV-induced SCE frequency. These results are interpreted with respect to the replicating fork of DNA, a structure postulated to be involved in the formation of spontaneous and UV-induced SCE. A new model for SCE formation is proposed.     

HSM2 (HMO1) gene participates in mutagenesis control in yeast Saccharomyces cerevisiae

We have previously reported about a new Saccharomyces cerevisiae mutation, hsm2-1, that results in increase of both spontaneous and UV-induced mutation frequencies but does not alter UV-sensitivity. Now HSM2 gene has been genetically and physically mapped and identified as a gene previously characterized as HMO1, a yeast homologue of human high mobility group genes HMG1/2. We found that hsm2 mutant is slightly deficient in plasmid-borne mismatch repair. We tested UV-induced mutagenesis in double mutants carrying hsm2-1 mutation and a mutation in a gene of principal damaged DNA repair pathways (rad2 and rev3) or in a mismatch repair gene (pms1 and recently characterized in our laboratory hsm3). The frequency of UV-induced mutations in hsm2 rev3 was not altered in comparison with single rev3 mutant. In contrast, the interaction of hsm2-1 with rad2 and pms1 was characterized by an increased frequency of UV-induced mutations in comparison with single rad2 and pms1 mutants. The UV-induced mutation frequency in double hsm2 hsm3 mutant was lower than in the single hsm2 and hsm3 mutants. The role of the HSM2 gene product in control of mutagenesis is discussed.     

Antimutagenesis by factors affecting DNA repair in bacteria

The term 'antimutagen' was originally used to describe an agent that reduces the apparent yield of spontaneous and/or induced mutations, regardless of the mechanisms involved. The 'antimutagens' include 'desmutagens' and 'bio-antimutagens'. In this article, our attention was focused on the bio-antimutagens affecting DNA repair in bacteria. Cobaltous chloride reduced the frequency of mutations in Escherichia coli induced by MNNG. The possibility that metal compound inhibits the growth of mutagen-treated cells was examined. The results clearly showed that the antimutagen surely reduces the mutation rate. The target of cobaltous chloride was found to be cellular factors including Rec A. Vanillin and cinnamaldehyde had strong antimutagenic activities against UV, 4NQO and AF-2. They stimulated Rec A-dependent recombination repair functions in the mutagen-treated cells. Among plant materials, tannins possess antimutagenic activity against UV-induced mutations in E. coli. It has been found that tannic acid stimulates the excision repair encoded by the uvrA gene thereby reducing the yield of mutants. Substances which are antimutagenic in bacterial systems also had antimutagenic activity in cultured mammalian cell systems. Vanillin reduced the frequency of mutagen-induced chromosomal aberrations.     

Lethal and mutation frequency responses of Spiroplasma citri cells to UV irradiation

The effect of UV irradiation on viability and mutant colony frequency in the Mollicute Spiroplasma citri was investigated at 3 phases of growth. The first UV-induced mutants obtained in Mollicutes were selected: xylitol-resistant (XylR) and arsenic acid-resistant mutants (ArsR). Lethal and mutation frequency responses of S. citri cells increase with the age of the cell cultures. In all UV-irradiated populations, light exposure slightly increases the number of survivors and decreases the induced mutation frequency; liquid holding conditions increase the number of both survivors and mutant colonies. This suggests that, in UV-irradiated S. citri cells maintained under liquid holding conditions, there is no dark reactivation but induction of an error-prone repair system of the SOS type. In S. citri, the error-free light and dark repair systems are inefficient. Results allow the development of a method to select UV-induced mutations usable as markers in genetic studies of Spiroplasma cells.     

Ultraviolet Mutagenesis Studies of [psi], a Cytoplasmic Determinant of SACCHAROMYCES CEREVISIAE

UV mutagenesis was used to probe the molecular nature of [psi], a non-mitochondrial cytoplasmic determinant of Saccharomyces cerevisiae involved in the control of nonsense suppression. The UV-induced mutation from [psi⁺] to [psi^-] showed characteristics of forward nuclear gene mutation in terms of frequency, induction kinetics, occurrence of whole and sectored mutant clones and the effect of the stage in the growth cycle on mutation frequency. The involvement of pyrimidine dimers in the premutational lesion giving the [psi^-] mutation was demonstrated by photoreactivation. UV-induced damage to the [psi] genetic determinant was shown to be repaired by nuclear-coded repair enzymes that are responsible for the repair of nuclear DNA damage. UV-induced damage to mitochondrial DNA appeared to be, at least partly, under the control of different repair processes. The evidence obtained suggests that the [psi] determinant is DNA.     

UV-mutagenesis in Bacillus subtilis. VII. Induction of auxotrophic mutants]

An experimental testing of material from thin-layered, transparent in passing light, colonies which appear with some frequency after plating Bacillus subtilis cells on agar medium with limited enrichment, has shown that such colonies are formed by auxotrophic mutants. The growth requirements for many of them has been identified. The most of mutants can be reversed to original phenotype by UV-irradiation. The frequency of auxotrophs increases after UV-irradiation of suspension of original cells. The sensitivity of auxotrophic mutants to inactivating action of UV-light is near to that of original cells, hence the increase of the frequency of mutants with dose is a result of induction, but not of selection of preexisting spontaneous auxotrophic mutants. The frequency of induced auxotrophs, in contrast to that of suppressor revertants, badly give way to declining in the time of temporary inhibition of postradiation growth. In the case of Bac, subtilis, the system of induced auxotrophic mutants on the medium with limited enrichment is rather comfortable in use and can be recommended for studying UV-induced mutagenesis in structural genes as well as for testing mutagenic activities.     

Mutagenesis by Cytostatic Alkylating Agents in Yeast Strains of Differing Repair Capacities

Reversion of two nulcear ochre nonsense alleles and cell inactivation induced by mono-, bi-, and tri-functional alkylating agents and by UV has been investigated in stationary-phase haploid cells of yeast strains with differing capacities for DNA repair. The ability to survive alkylation damage is correlated with UV repair capacity, a UV-resistant and UV-mutable strain (RAD REV) being least and a UV-sensitive and UV-nonmutable strain (radi rev3) most sensitive. Mutagenicity of alkylating agents is highest in the former and is abolished in the latter strain. Deficiency in excision repair (rad1 rad2) or in the RAD18 function does not lead to enhanced mutability. Mutagenesis by the various agents is characterized by a common pattern of induction of locus-specific revertants and suppressor mutants. Induction kinetics are mostly linear, but UV-induced reversion in the RAD REV strain follows higher-than-linear (probably "quadratic") kinetics. The alkylating agent cyclophosphamide, usually considered inactive without metabolic conversion, reduces colony-forming ability and induces revertants in a manner similar but not identical to the other chemicals tested. These findings are taken to support the concept of mutagenesis by misrepair after alkylation, which albeit sharing common features with the mechanism of UV-induced reversion, can be distinguished therefrom.     

Variability of cultures of Pullularia pullulans with different ploidy levels

As the level of ploidy rises in Pullularia pullulans, this causes an increase in the frequency of spontaneous and UV-induced auxotrophic mutants as well as mutants with a modified respiration activity while the frequency of morphological mutants decreases. The latter can arise as a result of recessive and dominant mutations. A higher frequency of morphological mutants in the haploid may be result of recessive mutations. It is likely that the frequency of dominant mutations increases in cultures with a higher level of ploidy since, as the difference between the frequency of UV-induced mutants and the frequency of spontaneous morphological mutants increases.     

IL-18 reduces ultraviolet radiation-induced DNA damage and thereby affects photoimmunosuppression

UV-induced DNA damage has been recognized as the major molecular trigger for photoimmunosuppression. IL-12 prevents UV-induced immunosuppression via its recently discovered capacity to reduce DNA damage presumably via induction of DNA repair. Because IL-18 shares some biological activities with IL-12 we studied the effect of IL-18 on UV-induced DNA damage and immunosuppression. IL-18 reduced UV-induced apoptosis of keratinocytes and supported long-term cell survival on UV exposure. Injection of IL-18 into mice that were exposed to UV radiation significantly lowered the number of apoptotic keratinocytes. Accordingly, radiation immunohistochemistry revealed reduced amounts of DNA damage in epidermal cells upon injection of IL-18. These effects were not observed in DNA repair-deficient (XpaKO) mice, indicating that IL-18 like IL-12 reduces DNA damage via DNA repair. UV-mediated suppression of the induction of contact hypersensitivity, which is known to be primarily triggered by DNA damage, was prevented upon injection of IL-18 before UV exposure in wild-type but not in XpaKO mice. In contrast to IL-12, IL-18 was not able either in wild-type or in XpaKO mice to break UV-induced immunotolerance that is mediated via regulatory T cells rather than in a DNA damage-dependent fashion. This result indicates that IL-12 is still unique in its capacity to restore immune responses because of its effect on regulatory T cells. Together, these data identify IL-18 as a further cytokine that exhibits the capacity to affect DNA repair. Though being primarily a proinflammatory cytokine through this capacity, IL-18 can also foster an immune response that is suppressed by UV radiation.     

Molecular characterization of methyl methanesulphonate (MMS)-induced HPRT mutations in V79 cells

Spontaneous and methyl methanesulphonate-induced HPRT-deficient mutants were analysed for changes in the hprt gene structure using multiplex polymerase chain reaction. The PCR amplification pattern of 21 MMS-induced mutations revealed one total deletion of the hprt coding exons and one small deletion within exon 5, while 19 mutants showed the V79 wild-type pattern. Molecular analysis of 30 spontaneous mutations revealed no mutants with amplification patterns which differed from those of wild-type cells. We further analysed MMS-induced mutants in a different V79 cell line with a high (40%) spontaneous deletion frequency. MMS caused a dose-dependent increase in the mutant frequency but the incidence of deletions was reduced to 6% at 2 × 10⁻⁴ M and to 13% at 5 × 10⁻⁴ M indicating that mainly point mutations were induced. The repair inhibitor cytosine arabinoside (araC) enhanced mutation induction by MMS but did not change the proportion of deletions in the mutation spectrum. The results indicate that different V79 cell lines spontaneously produce different amounts of deletion mutations. The frequency of MMS-induced deletions does not depend on the frequency of spontaneous deletions in a given cell line. The MMS-induced mutation spectrum seems to be unchanged even at high concentrations with a strong cytotoxic effect. Deletions are not increased as a consequence of araC-inhibited repair of MMS-inducd lesions.     

The geptrong pharmaceutical product increases efficiency of postreplication repair of permutation intermediates in yeast Saccharomyces cerevisiae

Geptrong is a medication from pure defermentated honey. In medical practice, it is used as hepatoprotector. Genotoxicity analysis revealed antimutagenic activity of the preparation. The spontaneous mutation rate at the ADE4-ADE8 and CAN1 loci was several times lower in case that the yeast cells were plated on the geptrong-containing medium, and the mutation rate was scored using the method of ordered plating. If spontaneous mutation rate was measured by means of the fluctuation method of median, no antimutagenic activity was detected. Geptrong had no effect on the yeast cell survival. At the same time, it substantially decreased the frequency of direct mutations at the ADE4-ADE8 locus, induced by UV-and gamma-radiation, and ethylmetansulfonate. The effect of the geptrong antimutagenic activity on the level of UV-induced mutagenesis in the yeast strains defective for the repair systems rad2, rad51, rad54, rad59, msh2, and hsm3 was examined. Antimutagenic activity was detected in the wild type, as well as in the rad2, rad54, rad59, and hsm3 strains, while rad51, pms1, and msh2 mutants lacked this activity. Based on these data, it is suggested that antimutagenic effect of geptrong is associated with activated repair of mismatches, appeared during the postreplicative recombination repair.     

Repair of UV-induced damage in wild-type and mutant strains of Schizophyllum commune

The basidiomycete fungus Schizophyllum commune was found to have both photo-repair and dark-repair systems for UV-induced damage. Three UV-sensitive mutants were isolated and characterized for ability to repair UV-induced damage in light and dark, and for cross-sensitivity to caffeine and methyl methanesulfonate. Two of the mutants were damaged, to different extents, in their capacity for excision repair; one of these mutants was also probably damaged in post-replication repair. The third mutant was damaged only in post-replication repair.     

Sequence specificity of point mutations induced during passage of a UV-irradiated shuttle vector plasmid in monkey cells.

A simian virus 40-based shuttle vector was used to characterize UV-induced mutations generated in mammalian cells. The small size and placement of the mutagenesis marker (the supF suppressor tRNA gene from Escherichia coli) within the vector substantially reduced the frequency of spontaneous mutations normally observed after transfection of mammalian cells with plasmid DNA; hence, UV-induced mutations were easily identified above the spontaneous background. UV-induced mutations characterized by DNA sequencing were found primarily to be base substitutions; about 56% of these were single-base changes, and 17% were tandem double-base changes. About 24% of the UV-induced mutants carried multiple mutations clustered within the 160-base-pair region sequenced. The majority (61%) of base changes were the G . C----A . T transitions; the other transition (A . T----G . C) and all four transversions occurred at about equal frequencies. Hot spots for UV mutagenesis did not correspond to hot spots for UV-induced photoproduct formation (determined by a DNA synthesis arrest assay); in particular, sites of TT dimers were underrepresented among the UV-induced mutations. These observations suggest to us that the DNA polymerase(s) responsible for mutation induction exhibits a localized loss of fidelity in DNA synthesis on UV-damaged templates such that it synthesizes past UV photoproducts, preferentially inserting adenine, and sometimes misincorporates bases at undamaged sites nearby.     

The Saccharomyces cerevisiae RAD9, RAD17, RAD24 and MEC3 genes are required for tolerating irreparable,ultraviolet-induced DNA damage.

In wild-type Saccharomyces cerevisiae, a checkpoint slows the rate of progression of an ongoing S phase in response to exposure to a DNA-alkylating agent. Mutations that eliminate S phase regulation also confer sensitivity to alkylating agents, leading us to suggest that, by regulating the S phase rate, cells are either better able to repair or better able to replicate damaged DNA. In this study, we determine the effects of mutations that impair S phase regulation on the ability of excision repair-defective cells to replicate irreparably UV-damaged DNA. We assay survival after UV irradiation, as well as the genetic consequences of replicating a damaged template, namely mutation and sister chromatid exchange induction. We find that RAD9, RAD17, RAD24, and MEC3 are required for UV-induced (although not spontaneous) mutagenesis, and that RAD9 and RAD17 (but not REV3, RAD24, and MEC3) are required for maximal induction of replication-dependent sister chromatid exchange. Therefore, checkpoint genes not only control cell cycle progression in response to damage, but also play a role in accommodating DNA damage during replication.     

Inhibition of repair of UV-damaged DNA by caffeine and mutation induction in Chinese hamster cells

The effect of caffeine on UV-irradiated Chinese hamster cells in vitro was studied on the cellular and molecular levels. Caffeine (1 mM) was shown to decrease the colony-forming ability and the frequencies of spontaneous and UV-induced mutations in Chinese hamster cells. The effect of caffeine in reducing the frequency of UV-induced mutations was demonstrated only if caffeine was present in the culture medium during the first post-irradiation cell division. Using alkaline sucrose gradient centrifugation, both parental and newly synthesized DNA in UV-irradiated and unirradiated cells were studied in the presence and absence of caffeine. Caffeine affected the sedimentation profile of DNA synthesized in UV-irradiated cells but not in unirradiated cells. Caffeine had no apparent effect on the incorporation of [³H]-thymidine into DNA of control or UV-irradiated cells, nor on the small amount of excision of UV-induced pyrimidine dimers. These results may be interpreted by a hypothesis that caffeine inhibits a certain S-phase specific, post-replication, dark-repair mechanism. The hamster and perhaps other rodent cells exposed to low doses of UV are capable of DNA replication, by-passing the non-excised pyrimidine dimers. This postulated repair process probably involves de novo DNA synthesis to seal the gaps in the nascent strand. This repair may be also responsible for the enzymatic production of mutations.     

Deletion of the SRS2 gene suppresses elevated recombination and DNA damage sensitivity in rad5 and rad18 mutants of Saccharomyces cerevisiae.

The Saccharomyces cerevisiae genes RAD5, RAD18, and SRS2 are proposed to act in post-replicational repair of DNA damage. We have investigated the genetic interactions between mutations in these genes with respect to cell survival and ectopic gene conversion following treatment of logarithmic and early stationary cells with UV- and gamma-rays. We find that the genetic interaction between the rad5 and rad18 mutations depends on DNA damage type and position in the cell cycle at the time of treatment. Inactivation of SRS2 suppresses damage sensitivity both in rad5 and rad18 mutants, but only when treated in logarithmic phase. When irradiated in stationary phase, the srs2 mutation enhances the sensitivity of rad5 mutants, whereas it has no effect on rad18 mutants. Irrespective of the growth phase, the srs2 mutation reduces the frequency of damage-induced ectopic gene conversion in rad5 and rad18 mutants. In addition, we find that srs2 mutants exhibit reduced spontaneous and UV-induced sister chromatid recombination (SCR), whereas rad5 and rad18 mutants are proficient for SCR. We propose a model in which the Srs2 protein has pro-recombinogenic or anti-recombinogenic activity, depending on the context of the DNA damage.