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Escherichia coli K-12 strains completely lacking catalase activity due to mutations in katG, katE, and katF genes were constructed in order to assess the role of hydrogen peroxide in mutagenesis. Mutagenesis was monitored by selecting forward mutations to L-arabinose resistance. Lethality was measured at experimental conditions equivalent to those of the mutant yield by using a mixed culture of pairs of isogenic strains distinguished by their differential nutritional requirements. Deficiency in katG, katE, and katF genes leads to an enhanced spontaneous mutation rate as well as an enhanced sensitivity to both the lethal and mutagenic effects of hydrogen peroxide or an H2O2-generating mixture of compounds, such as coffee. To compare further the responses of the catalase-deficient bacteria to those of catalase-proficient counterparts, other genotoxins were analyzed. Both catalase-deficient and catalase-proficient strains were equally mutated by MMS, 4-NQO, and ultraviolet light. It is concluded that the bacterial strains and the mutagenicity tests described in the paper represent a useful tool to study the role of H2O2 in mutagenesis.
Environ Mol Mutagen 1990
PMID:Mutagenesis in Escherichia coli lacking catalase. 219 82

It has been shown by genetic complementation analysis that a mitomycin C-sensitive mutant (V-H4) of Chinese hamster V79 cells is the first rodent equivalent of Fanconi anemia (FA) group A. The V-H4 mutant shows many typical characteristics of cells derived from FA patients. V-H4 cells exhibit increased sensitivity towards cross-linking agents as MMC (approximately 30-fold), cis-DDP (approximately 10-fold), DEB (approximately 10-fold), and PUVA (approximately 1.6-fold), but an only slightly increased sensitivity to monofunctional alkylating agents (EMS and MMS) and actinomycin D. V-H4 cells are also moderately sensitive to adriamycin (1.6-fold), and not sensitive to H2O2. The levels of chromosomal aberrations induced by MMC and cis-DDP treatment are higher (4- to 6-fold) in V-H4 cells than in the wild-type V79 cells. Genetic complementation analysis with other Chinese hamster mutants hypersensitive to MMC (irs1, irs1SF, UV20 and UV41) indicates clearly that V-H4 belongs to a different, new complementation group. This unique mutant is very stable and can serve as a vehicle to isolate the complementing FA-A gene from normal human DNA.
Somat Cell Mol Genet 1990 Nov
PMID:The Chinese hamster V79 cell mutant V-H4 is phenotypically like Fanconi anemia cells. 226 31

A group of five cDNA clones, representing the gadd genes, were recently isolated from Chinese hamster ovary (CHO) cells as genes induced upon growth arrest and after DNA damage (Fornace, A. J., Jr., Nebert, D. W., Hollander, M. C., Luethy, J. D., Papathanasiou, M., Fargnoli, J., and Holbrook, N. J. (1989) Mol. Cell. Biol. 9, 4196-4203). We have isolated and characterized one of these genes, gadd153. The gene spans five kilobases and contains four exons. The 5'-flanking region of the gene, within 420 base pairs of the transcription initiation site, contains a number of cis elements associated with transcriptional regulation in other genes. These include a Hogness box, ATAAAA, an inverted GCCAAT box; seven SP1 transcription factor binding sites, and an AP-1 site. This region is rich in G + C content (greater than 70%) and contains an unusually long stretch of alternating CpG residues. The 800-base pair region immediately upstream of the transcription start site can drive expression of the bacterial chloramphenicol acetyltransferase (CAT) gene, but only in its endogenous orientation, in three different cell lines: HeLa, CHO, and Jurkat. The gadd153 promoter is strongly activated by methyl methanesulfonate, hydrogen peroxide, and UV irradiation, but not by growth arrest signals. This suggests that separate and very different regulatory pathways are involved in the induction of the gadd153 gene by growth cessation and DNA damage.
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PMID:Isolation and characterization of the hamster gadd153 gene. Activation of promoter activity by agents that damage DNA. 239 62

RNR2 encodes the small subunit of ribonucleotide reductase, the enzyme that catalyzes the first step in the pathway for the production of deoxyribonucleotides needed for DNA synthesis. RNR2 is a member of a group of genes whose activities are cell cycle regulated and that are transcriptionally induced in response to the stress of DNA damage. An RNR2-lacZ fusion was used to further characterize the regulation of RNR2 and the pathway responsible for its response to DNA damage. beta-Galactosidase activity in yeast strains containing the RNR2-lacZ fusion was inducible in response to DNA-damaging agents (UV light, 4-nitroquinoline-1-oxide [4-NQO], and methyl methanesulfonate [MMS]) and agents that block DNA replication (hydroxyurea [HU] and methotrexate) but not heat shock. When MATa cells were arrested in G1 by alpha-factor, RNR2 mRNA was still inducible by DNA damage, indicating that the observed induction can occur outside of S phase. In addition, RNR2 induction was not blocked by the presence of cycloheximide and is therefore likely to be independent of protein synthesis. A mutation, rnr2-314, was found to confer hypersensitivity to HU and increased sensitivity to MMS. In rnr2-314 mutant strains, the DNA damage stress response was found to be partially constitutive as well as hypersensitive to induction by HU but not MMS. The induction properties of RNR2 were examined in a rad4-2 mutant background; in this genetic background, RNR2 was hypersensitive to induction by 4-NQO but not MMS. Induction of the RNR2-lacZ fusion in a RAD(+) strain in response to 4-NQO was not enhanced by the presence of an equal number of rad4-2 cells that lacked the fusion, implying that the DNA damage stress response in cell autonomous.
Mol Cell Biol 1989 Nov
PMID:DNA damage induction of ribonucleotide reductase. 251 80

Escherichia coli recF mutants are hypermutable when treated with methyl methanesulfonate (G. C. Walker, Mol. Gen. Genet. 152:93-103, 1977). In this study, methylation hypermutability of recF mutant strains was examined, and it was found that recF+ is required for normal induction of the adaptive response to alkylation damage. Although this regulatory effect of recF mutations results in reduced levels of enzymes that specifically repair methyl lesions in DNA, it only partially explains the hypermutability. Further examination showed that methylation hypermutability of recF mutant strains required a functional umuDC operon, a component of the SOS response. These results lead to the hypothesis that methylation hypermutability results from the effects of recF mutations on the induction of both the SOS response and the adaptive response.
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PMID:Altered induction of the adaptive response to alkylation damage in Escherichia coli recF mutants. 253 70

Methyl methanesulfonate (MMS) induced mutagenesis is known to be largely dependent on functional umuCD and recA genes. By phenotypic analysis of Arg+ (argE3, ochre) revertants according to their reversion of the mutations his-4 (ochre) and thr-1 (amber), we attempted to deduce the specificity and/or sites of MMS-induced mutations. It is shown that: (1) MMS-induced, umuC-dependent Arg+ revertants (which prevail in bacteria proficient in mismatch repair) result from a different mutational pathway from umuC-independent ones. UmuC-dependent Arg+ revertants belong to class 2 (Arg+His+Thr-), and umuC-independent ones to class 1 (Arg+His-Thr-). (2) The mismatch repair system very efficiently prevents mutations induced by MMS. We found that in the mutS strain, deficient in mismatch repair, class 1 Arg+ revertants are the most numerous, whereas class 2 Arg+ revertants occur at similar levels in MMS-treated mutS and mutS+ strains. Therefore the mismatch repair system very efficiently prevents formation of umuC-independent Arg+ revertants, but exerts negligible or no effect on umuC-dependent Arg+ revertants. (iii) Both mutS umuC and mutS recA strains, are highly mutable by MMS.
Mol Gen Genet 1989 Mar
PMID:Alternative pathways of methyl methanesulfonate-induced mutagenesis in Escherichia coli. 254 3

Pretreatment of a cloned rat embryo fibroblast (CREF) cell line with methyl methanesulfonate (MMS) prior to infection with a specific host-range and cold-sensitive type 5 adenovirus mutant (H5hr1), results in a unique carcinogen enhancement of transformation (CET) phenotype (Carcinogenesis 8:967, 1987). By using low-density clonal assays and in situ hybridization techniques with 32P-labeled type 5 adenovirus (Ad5) probes, we demonstrated that 5-10 d following infection the proportion of CREF colonies containing H5hr1 DNA and RNA is increased two- to threefold as a result of pretreatment with MMS. Twenty-five days following infection of CREF cells, Ad5 DNA assays showed that both solvent and MMS-pretreated CREF colonies no longer contained detectable levels of viral DNA or RNA. Analysis of free viral DNA by the Hirt procedure suggested that more free viral DNA persisted in MMS-pretreated H5hr1-infected CREF cells than in solvent-pretreated H5hr1-infected CREF cells. The relative amount of free viral DNA in both types of cultures was directly related to the multiplicity of H5hr1 infection and decreased with time following infection. As observed using in situ hybridization techniques, by 25 d after infection no free viral DNA was detected in either MMS- or solvent-pretreated H5hr1-infected CREF cells. By using a protein synthesis inhibitor (cycloheximide) and an RNA transcription inhibitor (actinomycin D), it was further demonstrated that the ability of MMS to induce a unique CET in CREF cells following infection with H5hr1 was dependent on the synthesis of new protein and RNA. In contrast, inhibition of protein and RNA synthesis did not alter the de novo rate of H5hr1 transformation of CREF cells. Temporal kinetic studies indicated that the ability of MMS to enhance H5hr1 transformation of CREF cells and to increase the percentage of CREF colonies containing Ad5 genetic information is regulated in a strict temporal manner. The results of the present investigation suggest that the ability of MMS to enhance H5hr1 transformation of CREF cells is dependent on the induction of new protein(s) in CREF cells, and enhancement is associated with an increase in the proportion of cells in the infected CREF cell population that initially contain Ad5 DNA/RNA.
Mol Carcinog 1989
PMID:Early events in methyl methanesulfonate enhancement of adenovirus transformation of cloned rat embryo fibroblast cells. 260 63

Procaryotic and eucaryotic cells possess mechanisms for arresting cell division in response to DNA damage. Eucaryotic cells arrest division in the G2 stage of the cell cycle, and various observations suggest that this arrest is necessary to ensure the completion of repair of damaged DNA before the entry of cells into mitosis. Here, we provide evidence that the Saccharomyces cerevisiae RAD9 gene, mutations of which confer sensitivity to DNA-damaging agents, is necessary for the cell cycle arrest phenomenon. Our studies with the rad9 delta mutation show that RAD9 plays a role in the cell cycle arrest of methyl methanesulfonate-treated cells and is absolutely required for the cell cycle arrest in the temperature-sensitive cdc9 mutant, which is defective in DNA ligase. At the restrictive temperature, cell cycle progression of cdc9 cells is blocked sometime after the DNA chain elongation step, whereas cdc9 rad9 delta cells do not arrest at this point and undergo one or two additional divisions. Upon transfer from the restrictive to the permissive temperature, a larger proportion of the cdc9 cells than of the cdc9 rad9 delta cells forms viable colonies, indicating that RAD9-mediated cell cycle arrest allows for proper ligation of DNA breaks before the entry of cells into mitosis. The rad9 delta mutation does not affect the frequency of spontaneous or UV-induced mutation and recombination, suggesting that RAD9 is not directly involved in mutagenic or recombinational repair processes. The RAD9 gene encodes a transcript of approximately 4.2 kilobases and a protein of 1,309 amino acids of Mr 148,412. We suggest that RAD9 may be involved in regulating the expression of genes required for the transition from G2 to mitosis.
Mol Cell Biol 1989 May
PMID:Cloning and sequence analysis of the Saccharomyces cerevisiae RAD9 gene and further evidence that its product is required for cell cycle arrest induced by DNA damage. 266 61

The small subunit of ribonucleotide reductase in Saccharomyces cerevisiae (RNR2) was induced 3- to 20-fold by a variety of DNA-damaging agents. Induction of the RNR2 transcript by at least one of these agents, methyl methanesulfonate, did not require protein synthesis. To identify sequences involved in the regulation of RNR2, we introduced deletions upstream of the transcription start site. Sequences required for induction were contained within a 200-base-pair region that could confer methyl methanesulfonate inducibility on the heterologous CYC1 promoter. This region contained a repression sequence and at least two positive activation sites. One of these activation sites bound RAP1, a protein known to associate with mating-type silencers and the upstream activation sequences of a number of genes. The behavior of deletions of the repression sequence suggests that induction of RNR2 may occur, at least in part, through relief of repression.
Mol Cell Biol 1989 Dec
PMID:Upstream regulatory sequences of the yeast RNR2 gene include a repression sequence and an activation site that binds the RAP1 protein. 268 60

Adherent peritoneal exudate cells rich in macrophages were harvested from Cornell K-strain chickens 42 hr after i.p. stimulation with Sephadex G-50. Glass-adherent monolayers were obtained on coverslips and subjected to in vitro exposure to methyl methanesulfonate (MMS) at various doses for 1 hr. Solvent (0.17% ethanol final concentration) and sham (RPMI 1640 growth media) exposures were also performed. At selected times after exposure, the macrophages were analyzed for cell viability, adherence, DNA damage, and functional activity. Although MMS doses of 5 x 10(-3) M and 1 x 10(-3) M concentrations resulted in significant cytoxicity, 2 x 10(-4) M had no significant cytotoxic effect. However, this exposure resulted in DNA damage as measured by alkaline elution. Concomitant with the DNA damage was a significant decrease in the phagocytic activity of macrophages. Repair of MMS-induced DNA lesions in macrophages was indicated by a normal DNA alkaline elution profile 10 hr postrecovery. Functional activity of cells also returned to normal levels. In contrast, the incidence of Fc receptor-positive cells detected by rosetting increased immediately after MMS exposure, and phagocytosis of opsonized SRBCs was not affected by 2 x 10(-4) M MMS treatment. Similarly, MMS treatment did not alter the acid phosphatase activity of macrophages. However, bactericidal ability of MMS-treated macrophages for unopsonized Escherichia coli was significantly depressed. These results suggest that the avian macrophage is a useful target cell for examining possible relationships between genotoxic and immunotoxic effects of environmental mutagens.
Environ Mol Mutagen 1989
PMID:Toxic effects of methyl methanesulfonate (MMS) on activated macrophages from chickens. 270 55

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