Methyl methane sulfonate-sensitive mutant of Escherichia coli deficient in an endonuclease specific for apurinic sites in deoxyribonucleic acid.

A methyl methane sulfonate (MMS)-sensitive mutant of Escherichia coli AB 1157 was obtained by N-methyl-N'-nitro-N-nitrosoguanidine treatment. The mutant strain, AB 3027, is defective both in endonuclease activity for apurinic sites in deoxyribonucleic acid (DNA) and in DNA polymerase I, as shown by direct enzyme assays. Derivative strains, which retained the deficiency in endonuclease activity for apurinic sties (approximately 10% of the wild-type enzyme level) but had normal DNA polymerase I activity, were obtained by P1-mediated transduction (strain NH5016) or by selection of revertants to decreased MMS sensitivity. These endonuclease-deficient strains are more MMS-sensitive than wild-type strains. Revertants of these deficients strains to normal MMS resistance were isolated. They had increased levels of the endonuclease activity but did not attain wild-type levels. The data suggest that endonuclease for apurinic sites is active in repair of lesions introduced in DNA as a consequence of MMS treatment. Two different endonucleases that specifically attack DNA containing apurinic sites arepresented in E coli K-12. A heat-labile activity, sensitive to inhibition by ethylenediaminetetraacetate, accounts for 90% of the total endonuclease activity for apurinic sties in crude cell extracts. The residual 10% is due to a more heat-resistant activity, refractory to ethylenediaminetetraacetate inhibition. The AB3027 and NH5016 strains have normal amounts of the latter endonuclease but no or very little of the former activity.     

Physiological Modifications in the Production and Repair of Methyl Methane Sulfonate-Induced Breaks in the Deoxyribonucleic Acid of Escherichia coli K-12

The medium in which Rec(+) strains of Escherichia coli K-12 are grown affected their sensitivity to treatment with methyl methane sulfonate (MMS). Rec(+) cells grown to the stationary phase in glucose-enriched nutrient broth (GNB) were more resistant to MMS than cells grown in nutrient broth (NB). The repair of MMS-induced breaks (or alkali-labile bonds) in the deoxyribonucleic acid (DNA) from E. coli K-12 strains AB1157, AB1886 uvrA6, and SR111 recA13 recB21 grown in GNB and NB media was examined by means of alkaline sucrose gradient centrifugation. It appeared that essentially all of the repair of breaks that occurred, as evidenced by an increase in "molecular weight," took place within 10 min after treatment with MMS under our conditions. Cell survival was highest in cells for which the size of the DNA after the post-treatment incubation was the largest. The largest DNA after post-treatment incubation was found in Rec(+) cells grown in GNB medium. The results suggest that these cells may have an enhanced capacity for repairing breaks in DNA.     

Nature of the Repair of Methyl Methanesulfonate-Induced Damage in Bacillus subtilis

A nuclease present in extracts of Bacillus subtilis inserts breaks in deoxyribonucleic acid (DNA) treated with the monofunctional alkylating agent, methyl methanesulfonate (MMS), but the nature of the sites within the alkylated macromolecule at which these breaks occur is not known. DNA extracted from B. subtilis cells that have recovered from MMS damage has lost its susceptibility to enzyme action. The recovery process is accompanied by some DNA breakdown and by the incorporation of thymidine. Some recovery from ultraviolet irradiation (UV) and MMS occurred in organisms starved for thymine or adenine, but UV recovery was stimulated by their addition. It is possible that MMS recovery proceeds by a process of excision and repair similar to, but not identical with, UV repair.     

The formation and repair of single-strand breaks in DNA of cultured mammalian cells treated with UV-light, methylating agents or 4-nitroquinoline-1-oxide.

The technique of sedimentation in alkaline sucrose was used to examine the formation and repair of single-strand (SS) breaks in cultured mammalian cells that were treated with methyl methanesulfonate (MMS), methyl nitrosourea (MNUA), 4-nitroquinoline-1-oxide (4NQO) or UV-light. The SS breaks induced by MMS and 4NQO were largely repaired by HeLa cells during a 5-h post-treatment incubation. The SS breaks induced by MNUA and UV-light were not repaired by HeLa cells. L-cells were not able to repair the SS breaks induced by any of the agents, which correlates with the deficiency of these cells for repair synthesis of DNA. The following conclusions are discussed. MNUA and UV-light produce modifications in DNA which are not repaired but are translated into SS breaks in alkali. MMS produces SS breaks intracellularly but these are not derived from a simple depurination of methylated purines. 4NQO produces a modification in DNA which is translated into an SS break in alkali but which can be removed by an intracellular process.     

Repair of MMS-induced DNA double-strand breaks in haploid cells of Saccharomyces cerevisiae, which requires the presence of a duplicate genome.

Summary The formation and repair of double-strand breaks induced in DNA by MMS was studied in haploid wild type and MMS-sensitive rad6 mutant strains of Saccharomyces cerevisiae with the use of the neutral and alkaline sucrose sedimentation technique. A similar decrease in average molecular weight of double-stranded DNA from 5–6x10⁸ to 1–0.7x10⁸ daltons was observed following treatment with 0.5% MMS in wild type and mutant strains. Incubation of cells after MMS treatment in a fresh drug-free growing medium resulted in repair of double-strand breaks in the wild type strain, but only in the exponential phase of growth. No repair of double-strand breaks was found when cells of the wild type strain were synchronized in G-1 phase by treatment with factor, although DNA single-strand breaks were still efficiently repaired. Mutant rad6 which has a very low ability to repair MMS-induced single-strand breaks, did not repair double-strand breaks regardless of the phase of growth.These results suggest that (1) repair of double-strand breaks requires the ability for single-strand breaks repair, (2) rejoining of double-strand breaks requires the availability of two homologous DNA molecules, this strongly supports the recombinational model of DNA repair.     

Isolation and characterization of second chromosome mutagen-sensitive mutations in Drosophila melanogaster

We have undertaken the study of a collection of 32 Drosophila melanogaster mus strains selected on the basis of developmental sensitivity to the DNA-damaging agents, methyl methanesulfonate (MMS), N-acetyl-2-aminofluorene (AAF), nitrogen mustard (HN2), and gamma-radiation. In total, 18 of these strains are sensitive to MMS. In turn, 14 of these exhibit unconditional MMS sensitivity (one of the latter mutants is lethal at 29 degrees C), whereas the other 4 are sensitive to MMS only at higher temperatures. Detailed analysis of the 7 strongest MMS-sensitive strains reveals that they identify 4 new second chromosome mus loci. Two mus loci are each represented by two alleles. One mutant (mus205B1) is allelic to a previously characterized mus locus. Different MMS-sensitive mutants display patterns of mutagen cross-sensitivity (to AAF, HN2, benzo[a]pyrene (BP), and gamma-rays) that parallel the range of responses seen in previously recovered X-linked and autosomal mus loci. In general, mutations that are strongly sensitive to MMS are also sensitive to one or both of the procarcinogens, AAF and BP, as opposed to HN2 and gamma-radiation. In contrast, the moderately MMS-sensitive mutations are sensitive to HN2 and gamma-rays, but not to AAF or BP. Of the 14 mus strains that are not sensitive to MMS, 5 are sensitive to AAF, another 5 are sensitive to HN2, and the remaining 4 are sensitive to gamma-rays.     

The effect of dietary folic acid deficiency on the cytotoxic and mutagenic responses to methyl methanesulfonate in wild-type and in 3-methyladenine DNA glycosylase-deficient Aag null mice

Folic acid deficiency (FA-) augments DNA damage caused by alkylating agents. The role of DNA repair in modulating this damage was investigated in mice. Weanling wild-type or 3-methyladenine glycosylase (Aag) null mice were maintained on a FA- diet or the same diet supplemented with folic acid (FA+) for 4 weeks. They were then treated with methyl methanesulfonate (MMS), 100mg/kg i.p. Six weeks later, spleen cells were collected for assays of non-selected and 6-thioguanine (TG) selected cloning efficiency to measure the mutant frequency at the Hprt locus. In wild-type mice, there was no significant effect of either MMS treatment or folate dietary content on splenocyte non-selected cloning efficiency. In contrast, non-selected cloning efficiency was significantly higher in MMS-treated Aag null mice than in saline treated controls (diet-gene interaction variable, p=0.04). The non-selected cloning efficiency was significantly higher in the FA+ diet than in the FA- diet group after MMS treatment of Aag null mice. Mutant frequency after MMS treatment was significantly higher in FA- wild-type and Aag null mice and in FA+ Aag null mice, but not in FA+ wild-type mice. For the Aag null mice, mutant frequency was higher in the FA+ mice than in the FA- mice after either saline or MMS treatment. These studies indicate that in wild-type mice treated with MMS, dietary folate content (FA+ or FA-) had no effect on cytotoxicity, but FA- diet increased DNA mutation frequency compared to FA+ diet. In Aag null mice, FA- diet increased the cytotoxic effects of alkylating agents but decreased the risk of DNA mutation.     

The repair of methyl methanesulphonate-induced lesions in the DNA of a murine lymphoma cell

The introduction of single-strand breaks into the DNA of a murine lymphoma (L5178Y) cell treated in vivo with methyl methanesulphonate (MMS) and the behaviour of these breaks on post-treatment incubation were studied. A large proportion of single-strand breaks present after MMS treatment could be repaired as shown by sedimentation in alkaline sucrose. Two inhibitors of DNA synthesis, hydroxyurea and cytosine arabinoside affected the repair process differently-hydroxyurea had only a small effect while cytosine arabinoside blocked repair and at some doses allowed further degradation of the DNA. It was also found that the level of ‘repair replication’ in the presence of cytosine arabinoside was lower than that found in the presence of hydroxyurea.     

Methyl methanesulfonate (MMS) produces heat-labile DNA damage but no detectable in vivo DNA double-strand breaks

Homologous recombination (HR) deficient cells are sensitive to methyl methanesulfonate (MMS). HR is usually involved in the repair of DNA double-strand breaks (DSBs) in Saccharomyces cerevisiae implying that MMS somehow induces DSBs in vivo. Indeed there is evidence, based on pulsed-field gel electrophoresis (PFGE), that MMS causes DNA fragmentation. However, the mechanism through which MMS induces DSBs has not been demonstrated. Here, we show that DNA fragmentation following MMS treatment, and detected by PFGE is not the consequence of production of cellular DSBs. Instead, DSBs seen following MMS treatment are produced during sample preparation where heat-labile methylated DNA is converted into DSBs. Furthermore, we show that the repair of MMS-induced heat-labile damage requires the base excision repair protein XRCC1, and is independent of HR in both S.cerevisiae and mammalian cells. We speculate that the reason for recombination-deficient cells being sensitive to MMS is due to the role of HR in repair of MMS-induced stalled replication forks, rather than for repair of cellular DSBs or heat-labile damage.     

Monofunctional alkylating agent-induced S-phase-dependent DNA damage

Alkylating agents are S-phase-dependent clastogenic agents: Chromosome aberrations are not observed unless the treated cells have first undergone a replicative DNA synthesis. While DNA gaps resulting from misreplication of the alkylated template are believed to underlie aberration formation, the specific alkylated DNA lesions that produce these DNA gaps are not known. To quantitate the DNA strand break induction that results from replication of an alkylated DNA template and attempt to identify those alkylated lesions which underlie DNA strand breakage. [14C]thymidine-labeled Chinese hamster ovary (CHO) cells were treated with either N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) or methyl methanesulfonate (MMS) in G1 and then allowed to progress through S phase in the presence of [3H]thymidine. When analyzed at the subsequent mitosis, DNA strand breaks were found in the nonalkylated ([3H]thymidine-labeled) DNA strand. This did not appear to be the consequence of any recombinational or endonuclease-mediated event and was more likely due to DNA gaps produced by incomplete replication off the alkylated template. A portion of these breaks probably result from a failure to replicate past 3-methyladenine. Differences between MNNG and MMS in the frequency of S-phase-dependent breaks they produce relative to the overall alkylation damage suggest that the O6-methylguanine lesion might also be involved in S-phase-dependent DNA strand breakage.     

Changes of 8-OH-dG levels in DNA and its base excision repair activity in rat lungs after inhalation exposure to hexavalent chromium

The co-genotoxic effects of cadmium are well recognized and it is assumed that most of these effects are due to the inhibition of DNA repair. We used the comet assay to analyze the effect of low, non-toxic concentrations of CdCl2 on DNA damage and repair-induced in Chinese hamster ovary (CHO) cells by UV-radiation, by methyl methanesulfonate (MMS) and by N-methyl-N-nitrosourea (MNU). The UV-induced DNA lesions revealed by the comet assay are single-strand breaks which are the intermediates formed during nucleotide excision repair (NER). In cells exposed to UV-irradiation alone the formation of DNA strand breaks was rapid, followed by a fast rejoining phase during the first 60 min after irradiation. In UV-irradiated cells pre-exposed to CdCl2, the formation of DNA strand breaks was significantly slower, indicating that cadmium inhibited DNA damage recognition and/or excision. Methyl methanesulfonate and N-methyl-N-nitrosourea directly alkylate nitrogen and oxygen atoms of DNA bases. The lesions revealed by the comet assay are mainly breaks at apurinic/apyrimidinic (AP) sites and breaks formed as intermediates during base excision repair (BER). In MMS treated cells the initial level of DNA strand breaks did not change during the first hour of recovery; thereafter repair was detected. In cells pre-exposed to CdCl2 the MMS-induced DNA strand breaks accumulated during the first 2h of recovery, indicating that AP sites and/or DNA strand breaks were formed but that further steps of BER were blocked. In MNU treated cells the maximal level of DNA strand breaks was detected immediately after the treatment and the breaks were repaired rapidly. In CdCl2 pre-treated cells the formation of MNU-induced DNA single-strand breaks was not affected, while the repair was slower, indicating inhibition of polymerization and/or the ligation step of BER. Cadmium thus affects the repair of UV-, MMS- and MNU-induced DNA damage, providing further evidence, that inhibition of DNA repair is an important mechanism of cadmium induced mutagenicity and carcinogenicity.     

MMS1 protects against replication-dependent DNA damage in Saccharomyces cerevisiae

A series of yeast mutants were isolated that are sensitive to killing by the monofunctional DNA-alkylating agent methyl methanesulfonate (MMS) but not by UV or X-radiation. We have cloned and characterized one of the corresponding genes, MMS1, and show that the mms1 Delta mutant is dramatically sensitive to killing by MMS and mildly sensitive to UV radiation. mms1 Delta mutants display an elevated level of spontaneous DNA damage and genomic instability. Furthermore, the mms1 Delta cells are sensitive to killing by conditions that induce replication-dependent double-strand breaks, such as treatment with camptothecin, and incubation of a cdc2-2 strain at the restrictive temperature. rad52 Delta is epistatic to mms1 Delta for MMS and camptothecin sensitivity, indicating that Mms1 acts in concert with Rad52. However, unlike mutants of the RAD52 group, mms1 Delta cells are not sensitive to gamma-rays, which induce double-strand breaks independently of DNA replication. Together these results suggest a role for an Mms1-dependent, Rad52-mediated, pathway in protecting cells against replication-dependent DNA damage.     

Sensitivity to bleomycin and hydrogen peroxide of DNA repair-defective mutants in Neurospora crassa

Mutations were induced in Neurospora which cause increased sensitivity to MMS (methyl methane-sulfonate) and other mutagens. Genetic analysis of such mus demonstrated that some of them defined new DNA repair genes (mus-21, and mus-27 to mus-30), while others represented new alleles in previously known genes. To characterize them further, and especially to identify rec- types which have not yet been found in this species, many MMS-sensitive strains were tested for cross-sensitivities to bleomycin (BLM) and to hydrogen peroxide (H2O2) to which some rec- of other species are hypersensitive. In Neurospora, many of the MMS-sensitive mutants were found to be cross-sensitive to BLM and frequently these were also hypersensitive to ionizing radiation. Bleomycin sensitivity was demonstrated for all alleles of 10 different genes, 4 of them new ones, with mus-27 being the most sensitive of the latter (resembling uvs-6; Koga and Schroeder, 1987, Mutation Res., 183, 139). In contrast, very few of the MMS-sensitive mutants were hypersensitive to H2O2 and, in general, results of H2O2 tests were variable and differences between strains small. However, consistent deviations from wild type were observed in a few cases (most clearly for mus-9 and mus-11) when results from treatments of germinating conidia were compared with those of non-growing ones.     

Comet assay with nuclear extract incubation

Alkaline comet assay is a simple sensitive method for detecting DNA strand breaks. However, at the time of cell lysis, only a fraction of the entire DNA damage appears as DNA strand breaks, while some DNA strand breaks may have been rejoined and some DNA lesions may still remain unexcised. We showed that nuclear extract (NE) prepared from human cells could excise the DNA adducts induced by UVC, X-ray, and methyl methanesulfonate (MMS). Thus, the comet assay with NE incubation allows a closer estimation of total DNA damage. Among the human urothelial carcinoma cell lines we tested, the NE of NTUB1 cells showed higher activity in excising the DNA adducts induced by UVC, but with a lower activity in excising the DNA adducts induced by MMS than the NE of BFTC905 cells. Moreover, under the same dose of X-ray irradiation, a larger difference in total DNA damage between two cell lines was revealed in comet assay incubated with NE than without NE. Therefore, the comet assay with NE incubation may be useful in the research of cancer risk, drug resistance, and DNA repair proteins.     

Characterization of MMS-sensitive mutants of Neurospora crassa

Several MMS-sensitive mutants of Neurospora crassa were compared with the wild-type strain for their relative sensitivities to UV, X-ray, and histidine. They were also compared for the frequency of spontaneous mutation at the loci which confer resistance to p-fluorophenylalanine. The mutants were also examined for possible defects in meiotic behavior in homozygous crosses and for any change in the inducible DNA salvage pathways (as indicated by their ability to utilize DNA as the sole phosphate source in the growth medium). On the basis of these characterizations, the present MMS-sensitive mutants of Neurospora can be placed into three groups. The first group includes three mutants, mus-(SC3), mus-(SC13), and mus-(SC28). These are slow growers, insensitive to histidine with no apparent meiotic defects and may have reduced frequency of spontaneous mutation. In addition, their mycelial growth is sensitive to MMS but the conidial viability following MMS, UV or X-ray treatment appears normal or only slightly more sensitive than the wild-type. The second group includes only one mutant, mus-(SC15); its mycelial growth is very sensitive to MMS but the conidial survival following treatment with MMS or UV appears normal; however, the conidial survival following exposure to X-ray is significantly reduced. This mutant shows an increase (more than 10-fold) frequency of spontaneous mutation, but behaves normal like the wild-type with respect to fertility, growth rate and insensitivity to histidine. The third group includes mutants mus-(SC10), mus-(SC25), and mus-(SC29). These mutants are very sensitive to UV, X-rays and MMS and to histadine but have normal growth rates on minimal medium. Mutant mus-(SC10), but not mus-(SC25) and mus-(SC29), has an increased (11 ×) frequency of spontaneous mutation. On the basis of data presented, the MMS sensitivity of the first group of mutants cannot be ascertained to arise from a defect in the DNA repair pathways; instead, it may stem from altered cell permeability or other pleotropic effects of the mus mutations. However, it can be suggested that the second and third group of mus mutants may indeed result from a defect in the DNA repair pathways controlled by the mus genes; this conclusion is based on their cross-sensitivity to a number of DNA-damaging agents such as MMS, UV and/or X-ray, high frequencies of spontaneous mutation (mutator effects) and defects in meiotic behavior.     

The Isolation of Mms- and Histidine-Sensitive Mutants in NEUROSPORA CRASSA

A simple method of replica plating has been used to isolate mutants of Neurospora crassa that have increased sensitivity to methyl methanesulfonate (MMS) and/or to histidine. Twelve mutants with increased sensitivity to MMS and one mutant with increased sensitivity to histidine showed Mendelian segregation of the mutant phenotypes. Three mutants were mapped to loci not previously associated with MMS sensitivity. Two others were allelic to the UV- and MMS-sensitive mutant, mei-3. Survival curves indicate that conidia (mutant or wild-type) survive on much higher concentrations of MMS at 25° than at 37°. In contrast, mycelial growth is more resistant to MMS at 37°. The possibility of qualitatively different repair processes at these two temperatures is discussed.     

Deoxyribonucleic Acid Damage by Monofunctional Mitomycins and Its Repair in Escherichia coli

Exposure of Escherichia coli to the antibiotic mitomycin C (MTC) at a concentration of 0.5 mug/ml caused cross-linkage between complementary strands of deoxyribonucleic acid (DNA). Derivatives of mitomycin, 7-methoxymitosene (7-MMT) and decarbamoyl mitomycin C (DCMTC), at a level as high as 20 mug/ml formed no cross-links between DNA strands. Ultraviolet light-sensitive mutants of E. coli K-12 bearing uvrA, uvrB, uvrC, or recA mutations were more sensitive to the lethal action of 7-MMT and of DCMTC than was the wild-type strain. Treatment of wild-type cells with these antibiotics resulted in the production of single-strand breaks in DNA, which were repaired upon incubation in a growth medium. Such breaks in DNA were not produced in the uvrA and the uvrB mutants. In the uvrC mutant, single-strand breaks were produced by 7-MMT or by DCMTC, but these breaks were not repaired upon incubation. These results are discussed in connection with the mechanism for removal of pyrimidine dimers in ultraviolet-irradiated bacteria.     

Mutagen sensitivity of Drosophila melanogaster. I. Isolation and preliminary characterization of a methyl methanesulphonate-sensitive strain

Sensitivity to the monofunctional alkylating agent methyl methanesulfonate (MMS) has been tested as a selection technique to isolate mutant strains which can provide insights into the genetic control of DNA replication, DNA repair and recombination in the complex eucaryote, Drosophila melanogaster. The successful isolation of an X-linked MMS-sensitive strain, mut^s, has suggested that mutagen sensitivity is a feasible methodology for the selection of mutant strains of Drosophila which will be useful in the genetic and biochemical analysis of these cellular functions. Preliminary characterization of this mutant strain indicates that: (A) it is extremely sensitive to killing by MMS; (B) it is more mutable by MMS than the parent wildtype strain; and (C) it appears to possess mutator gene activity.     

Poly(ADP-ribose) synthesis and inhibition of DNA synthesis in Chinese hamster cells treated with methylating agents and thymidine

A possible role of poly(ADP-ribose) synthesis in modulating the response of V79 cells to DNA damage induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and methyl methanesulfonate (MMS) was investigated. Inhibition of [3H]thymidine (dThd) incorporation into DNA and lowering of NAD+ levels in intact cells were employed as parameters of DNA-synthesis inhibition and poly(ADP-ribose) synthesis, respectively. Dose responses of these parameters were studied in cells 2 and 24 h after treatment with the methylating agents in medium with or without dThd. The initial inhibition of DNA synthesis was uniformly associated with stimulation of poly(ADP-ribose) synthesis whether the cells were treated with MNNG or MMS, incubated with or without 20 microM dThd which did not inhibit poly(ADP-ribose) synthesis, or incubated with 3 mM dThd which did inhibit the latter synthesis. By contrast, the DNA-synthesis inhibition detected 24 h after treatment with MNNG was not associated with poly(ADP-ribose) synthesis. These data suggest that (i) the mechanism of this later inhibition of DNA synthesis is different from that of the initial inhibition, (ii) DNA-synthesis inhibition does not stimulate poly(ADP-ribose) synthesis, and (iii) single-strand breaks, resulting from N-methylation of the DNA, stimulate poly(ADP-ribose) synthesis, which may produce the initial inhibition of DNA synthesis. The initial inhibition of DNA synthesis was not uniformly associated with mutagenesis and dThd facilitation of MNNG-induced cytotoxicity and mutagenesis. This indicates that O-methylation of DNA does not stimulate poly(ADP-ribose) synthesis. Our data suggest that, in V79 cells treated with methylating agents, poly(ADP-ribose) synthesis is stimulated by single-strand breaks, inhibits DNA synthesis, and thereby serves to allow time for repair of the DNA prior to replication.     

DNA repair and sensitivity of mouse embryo fibroblasts to methyl methanesulphonate and N-methyl-N'-nitro-N-nitrosoguanidine

DNA repair synthesis and cytotoxicity were evaluated in early passage mouse embryo fibroblasts from five inbred strains (B10, CBA, C3H/A, DBA/2, BALB/c) and in BALB/3T3 IL-2 cells after the cultures had been treated for 3 h with methyl methanesulphonate (MMS) or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). In the presence of hydroxyurea, the incorporation of tritiated thymidine into the MMS- or MNNG-treated cells derived from B10, CBA, C3H/A or DBA/2 mice, was, at the concentrations used, significantly higher than into controls untreated with the mutagens. Under analogous experimental conditions there was no detectable DNA repair synthesis in two kinds of cells derived from BALB/c mice. MNNG was more cytotoxic to the cells derived from BALB/c mice than to those of the four remaining strains. The sensitivity of all kinds of early passage mouse fibroblasts to MMS was similar at each MMS concentration tested. Cloning efficiency of BALB/3T3 IL-2 cells exposed to MMS at the concentration of 10(-3) or 10(-4) M did not differ from that of untreated controls. The latter cells treated with MNNG at the concentration of 10(-4) or 2 X 10(-4) M did not develop colonies.