Methylation of DNA and protamine by methyl methanesulfonate in the germ cells of male mice

The molecular dosimetry of methyl methanesulfonate (MMS) in the germ cells of male mice has been investigated. The mice were injected i.p. with 100 mg/kg of [3H]MMS and methylations per sperm head, per deoxynucleotide, and per unit of protamine were then determined over a 3-week period. The methylations per sperm head paralleled the dominant lethal frequency curve for MMS, reaching a maximum of between 22 and 26 million methylations per vas sperm head 8-11 days after treatment. Methylation of sperm DNA was greatest at 4 h (the earliest time point studied) after treatment, with 16.6 methylations/10(5) deoxynucleotides. DNA methylation gradually decreased during the subsequent 3-week period. The methylation of germ-cell DNA did not increase in the stages most sensitive to MMS (late spermatids leads to early spermatozoa) and was not correlated with the dominant lethal frequency curve for MMS. However, methylation of protamine did increase in the germ-cell stages most sensitive to MMS, and showed an excellent correlation with the incidence of dominant lethals produced by MMS in the different germ-cell stages. The pattern of alkylation produced by MMS in the developing germ-cell stages of the mouse is similar to that found for EMS. However, for equimolar exposures, MMS alkylates the germ cells 5-7 times more than does EMS. Hydrolyzed samples of protamine from [3H]MMS-exposed animals were subjected to thin-layer chromatography and amino acid analysis. Both procedures showed that most of the labeled material recovered from the hydrolysates co-chromatographed with authentic standards of S-methyl-L-cysteine. The amino acid analyses showed an average of approximately 80% of the labeled material eluting with S-methyl-L-cysteine. The mechanism of action of both MMS and EMS on the developing germ cells appears to be similar. The occurrence of S-methyl-L-cysteine as the major reaction product in sperm protamine after MMS exposure supports our initial model of how dominant lethals are induced in mouse germ cells by these chemicals: Alkylation of cysteine sulfhydryl groups contained in mouse-sperm protamine blocks normal disulfide-bond formation, preventing proper chromatin condensation in the sperm nucleus. Subsequent stresses produced in the chromatin structure eventually lead to chromosome breakage, with resultant dominant lethality.     

Mechanistic and methodological aspects of chemically-induced somatic mutation and recombination in Drosophila melanogaster

This study presents the analysis of chemically-induced somatic mutations and chromosomal damage in the eye imaginal discs of Drosophila larvae, assayed later as twin (TS) and single light (LS) mosaic spots in the adult eyes. Regarding the question as to what kind of DNA alterations contribute to somatic cell mutagenicity, the approach followed here has been to investigate the possible differences in response between male (hemizygous for an X) and female (homozygous) larvae, rod-X/rod-X versus ring-X/rod-X genotypes and inversion-heterozygotes versus genotypes not carrying an inversion. The systems chosen for this analysis were the white-coral/white (wco/w) and the white+/white (w+/w) eye mosaic system. The principle findings with 12 mutagens of different modes of action are as follows: (1) At least 98% of all TS and LS induced by cisplatin (DDP) in wco/w female larvae and about 95% of those by formaldehyde (FA) appear as the result of recombinogenic activity between the two homologous X-chromosomes. The corresponding estimates for MMS, EMS and ENU are 81%, 73% and 61%, respectively. (2) The long scS1L sc8R inversion, which also contains In(1)dl-49, suppresses induction of TS to 83-93%. There was also a sharp decline in the frequency of LS in inversion heterozygotes for DDP (91%), FA (86%), MMS (52%) and EMS (47%). (3) Ethylnitrosourea (ENU) was the mutagen for which introduction of the inverted chromosome reduced only slightly (23%) the frequency of LS, indicating that the majority of them were somatic mutations (and deletions) at the white locus. (4) In w/RX females heterozygous for a ring-X chromosome, the frequency of LS was only approximately one tenth of that of the control (w+/w) group, after exposure to MMS or DDP. The explanation is that exchange processes involving the ring frequently lead to genetic imbalance with subsequent cell killing.     

Biological effect of low doses of alkylating agents in drosophila studies

The low dose (0.05-0.1 mM) influence of alkylating agents on germ cell survival and male fertility, the level of embryonic and postembryonic lethality as well as the sex-linked recessive lethal (SLRL) frequency induced by high alkylating agent doses was studied in Drosophila melanogaster. The pretreatment of adult males with low doses of methyl and ethyl methanesulfonate (MMS and EMS) did not change or even enhanced EMS cytotoxicity and mutagenicity in both mature sperm and premeiotic cells. On the contrary, the low EMS dose pretreatment of larvae protected them against higher mutagen doses increasing male fertility, decreasing embryonic and postembryonic lethality in F1, and leading to three-fold reduction in the SLRL frequency in F2. The adaptive response was dependent on the Drosophila developmental stage exposed to challenge mutagen doses, since the protection was maximal in larvae and practically absent when the high dose was administered to adult males. The adaptive response observed does not seem to be associated with DNA repair, but it is rather due to other protective mechanisms.     

Influence of anoxia and respiratory deficiency on the genotoxicity of some direct-acting alkylating agents in yeast.

We have studied the influence of anoxia and respiratory deficiency (RD) in yeast on the cytotoxic and recombinogenic effects of 5 direct-acting alkylating agents, namely N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), methylnitrosourea (MNU), ethylnitrosourea (ENU), methyl methanesulphonate (MMS) and ethyl methanesulphonate (EMS). We found that the effects of both conditions parallel each other for MMS, MNNG, MNU and ENU. Both anoxia and RD did not modify the effects of MMS to any significant extent. On the other hand, anoxic and respiratory-deficient cells were found to be more resistant than euoxic and respiratory-proficient cells respectively for MNNG, MNU and ENU. In the case of EMS, which is similar to MMS in its chemical reaction with DNA, the respiratory-deficient cells were found to be more sensitive than the respiratory-proficient ones. These studies indicate that the response of anoxic and respiratory-deficient cells cannot be predicted solely on the basis of the chemical reactivity pattern of the alkylating agents. The physiological state which exists under these conditions may exert considerable influence on the cellular response.     

Base alterations in yeast induced by alkylating agents with differing Swain-Scott substrate constants.

The base alterations induced by four alkylating agents, methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), N-nitroso-N-methylurea (MNU), and N-nitroso-N-ethylurea (ENU), have been determined at the URA3 locus in the yeast Saccharomyces cerevisiae. The mutagen treatment was carried out on yeast cells in the logarithmic phase of growth. The mutants were selected by their resistance to 7.3 mM-5-fluoroorotic acid at pH 3.8. DNA sequence analysis was carried out by the dideoxy chain termination method. The alkylating agents were selected for their widely differing Swain-Scott substrate constants (s values), which are as follows: MMS, s = 0.83; EMS, s = 0.67; MNU, s = 0.42; ENU, s = 0.26. A higher s value is correlated with a higher ratio of 7-alkylguanine to O6-alkylguanine in native DNA in vitro. 125 forward mutations from URA3----ura3 were sequenced with marked differences in the mutational spectra being observed as the s value changed. Five hotspots were recorded for the four alkylating agents. They were all G.C----A.T transition mutations. There was one common hotspot for all of them; there were two additional ones for the two ethylating agents (ENU and EMS) and two different ones for MNU. Four of the five hotspots have the 5'-GG-3' sequence with the 3'-guanine mutated. It was seen that MMS, which has the highest Swain-Scott substrate constant, yielded the widest array of mutational types. As the substrate constants decreased, the types of mutations became more and more restricted to the G.C----A.T transitions and the A.T----T.A transversions. The transitions are consistent with the concept that mutations arise from O6-alkylation of guanine and alkylation of thymine. The transversions are consistent with the notion of N1-alkylation of adenosine or adenylic acid.     

Analysis of chromosomal rearrangements induced by postmeiotic mutagenesis with ethylnitrosourea in zebrafish

Mutations identified in zebrafish genetic screens allow the dissection of a wide array of problems in vertebrate biology. Most screens have examined mutations induced by treatment of spermatogonial (premeiotic) cells with the chemical mutagen N-ethyl-N-nitrosourea (ENU). Treatment of postmeiotic gametes with ENU induces specific-locus mutations at a higher rate than premeiotic regimens, suggesting that postmeiotic mutagenesis protocols could be useful in some screening strategies. Whereas there is extensive evidence that ENU induces point mutations in premeiotic cells, the range of mutations induced in postmeiotic zebrafish germ cells has been less thoroughly characterized. Here we report the identification and analysis of five mutations induced by postmeiotic ENU treatment. One mutation, snh(st1), is a translocation involving linkage group (LG) 11 and LG 14. The other four mutations, oep(st2), kny(st3), Df(LG 13)(st4), and cyc(st5), are deletions, ranging in size from less than 3 cM to greater than 20 cM. These results show that germ cell stage is an important determinant of the type of mutations induced. The induction of chromosomal rearrangements may account for the elevated frequency of specific-locus mutations observed after treatment of postmeiotic gametes with ENU.     

Induction of specific-locus and dominant lethal mutations in male mice by 1-methyl-1-nitrosourea (MNU)

1-Methyl-1-nitrosourea (MNU) induced specific-locus mutations in mice in all spermatogenic stages except spermatozoa. After intraperitoneal injection of 70 mg/kg body weight of MNU a high yield of specific-locus mutations was observed in spermatids (21.8 × 10⁻⁵ mutations per locus per gamete). The highest mutational yield was induced in differentiating spermatogonia. In 1954 offspring we observed 5 specific-locus mutants (44.8 × 10⁻ mutations per locus per gamete). In addition, 2 mosaics were recovered, which gave a combined mutation rate of 62.7 × 10⁻⁵. In A_s spermatogonia the mutation rate was 3.9 × 10⁻⁵. The same dose of 70 mg/kg of MNU induced dominant lethal mutations 5–48 days post treatment, mainly due to post-implantation loss in spermatids and spermatocytes. It is interesting to compare the induction pattern of mutations by MNU with methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS) and ethylnitrosourea (ENU). Based on the different spermatogenic response of the induction of specific-locus mutations we can characterize the 4 mutagens in the following way: EMS = MMS ≠ MNU ≠ ENU.     

In vitro developmental toxicity of five direct-acting alkylating agents in rodent embryos: structure-activity patterns

Five direct-acting alkylating agents were examined qualitatively and quantitatively for their ability to produce developmental toxicity in rodent postimplantation embryos. These agents were structurally related and were capable of donating either a methyl (methylnitrosourea, MNU; methylnitronitrosoguanidine, MNNG; methyl methanesulfonate, MMS) or ethyl (ethylnitrosourea, ENU; ethyl methanesulfonate, EMS) group to nucleophiles. These agents' reactivities were known to differ. In day 10 rat embryos in vitro a single, 2-hour exposure was shown to be sufficient to elicit dose-dependent increases in embryo lethality and malformations. Qualitatively, the patterns of embryo malformations reported in treated embryos paralleled those observed in in vivo studies, especially in regard to adverse effects on central nervous system and craniofacial systems. Quantitatively, the order of potency of these agents in vitro was: MNNG greater than MNU greater than ENU greater than MMS greater than EMS. In vivo studies reported a different order of potency. In vitro, methylating agents were consistently more potent than ethylating agents. Other chemical properties such as nucleophilic reactivity or half-life under physiological conditions could not explain observed potency relationships. Future investigation of other chemical properties of these agents such as specific alkylation and carbamylation reactivities may expand these initial structure-activity observations.     

Influence of anoxia and respiratory deficiency on the genotoxicity of some direct-acting alkylating agents in yeast

We have studied the influence of anoxia and respiratory deficiency (RD) in yeast on the cytotoxic and recombinogenic effects of 5 direct-acting alkylating agents, namely N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), methylnitrosourea (MNU), ethylnitrosourea (ENU), methyl methanesulphonate (MMS) and ethyl methanesulphonate (EMS). We found that the effects of both conditions parallel each other for MMS, MNNG, MNU and ENU. Both anoxia and RD did not modify the effects of MMS to any significant extent. On the other hand, anoxic and respiratory-deficient cells were found to be more resistant than euoxic and respiratory-proficient cells respectively for MNNG, MNU and ENU. In the case of EMS, which is similar to MMS in its chemical reaction with DNA, the respiratory-deficient cells were found to be more sensitive than the respiratory-proficient ones. These studies indicate that the response of anoxic and respiratory deficient cells cannot be predicted solely on the basis of the chemical reactivity pattern of the alkylating agents. The physiological state which exists under these conditions may exert considerable influence on the cellular response.     

O-alkylation in DNA does not correlate with the formation of chromosome breakage events in D. melanogaster

Postmeiotic cell stages of repair-proficient ring-X (RX) males were treated with methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), diethylnitrosamine (DEN) or ethylnitrosourea (ENU) and then mated to either repair-defective (mei-9L1) or to repair-competent females (mei-9+). Absence of the mei-9+ function resulted in a hypermutability effect to all alkylating agents (AAs) when they were assayed for their ability to induce chromosomal aberrations (chromosome loss; CL), irrespective of marked differences in distribution of DNA adducts brought about by these AAs. This picture is different from that described previously for the induction of point mutations (Vogel et al., 1985a). There, evidence was presented indicating that reduction in DNA excision repair does not affect point mutation induction (recessive lethals) by those AAs most efficient in ring-oxygen alkylation such as ENU, DEN, N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG), and isopropyl methanesulfonate (iPMS): the order of hypermutability of AAs with mei-9L relative to mei-9+ was MMS greater than MNU greater than DMN = EMS greater than iPMS = ENU = DEN = ENNG. When the percentage of lethal mutations induced in mei-9L1 females were plotted against those determined for mei-9+ females, straight lines of following slopes were obtained: MMS = 7.6, MNU = 5.4, DMN = 2.4, EMS = 2.4, and iPMS = ENU = DEN = ENNG = 1. Those findings, together with the recent observation that AAs do not split into two groups when assayed for their ability to cause CL, point to the involvement of different DNA alkylation products in ENU- and DEN-induced chromosome loss vs. that of point mutations. It is concluded that with ENU and DEN chromosomal loss results from N-alkylation products whereas point mutations (SLRL) are the consequence of interactions with oxygen-sites in DNA. Thus, as a consequence of a very dominating role of O-ethylguanine (and possibly O4-alkylation of thymine), N-alkylation in DNA does not contribute measurably to mutation induction in the case of ENU-type mutagens while O-alkylation, very clearly, does not show a positive correlation with the formation of chromosome breakage events in Drosophila. Conversely, it appeared that with MMS-type mutagens (MMS; dimethyl sulfate, DMS; trimethyl phosphate, TMP), alkylation products such as 7-methylguanine and 3-methyladenine, if unrepaired or misrepaired, are potentially mutagenic lesions causing both mutations and chromosomal aberrations.     

Efficient Recovery of Enu-Induced Mutations from the Zebrafish Germline

We studied the efficiency with which two chemical mutagens, ethyl methanesulfonate (EMS) and N-ethyl-N-nitrosourea (ENU) can induce mutations at different stages of spermatogenesis in zebrafish (Brachydanio rerio). Both EMS and ENU induced mutations at high rates in post-meiotic germ cells, as indicated by the incidence of F(1) progeny mosaic for the albino mutation. For pre-meiotic germ cells, however, only ENU was found to be an effective mutagen, as indicated by the frequencies of non-mosaic mutant progeny at four different pigmentation loci. Several mutagenic regimens that varied in either the number of treatments or the concentration of ENU were studied to achieve an optimal ratio between the mutagenicity and toxicity. For the two most mutagenic regimens: 4 X 1 hr in 3 mM ENU and 6 X 1 hr in 3 mM ENU, the minimum estimate of frequencies of independent mutations per locus per gamete was 0.9-1.3 X 10(-3). We demonstrate that embryonic lethal mutations induced with ENU were transmitted to offspring and that they could be recovered in an F(2) screen. An average frequency of specific-locus mutations of 1.1 X 10(-3) corresponded to approximately 1.7 embryonic lethal mutations per single mutagenized genome. The high rates of mutations achievable with ENU allow for rapid identification of large numbers of genes involved in a variety of aspects of zebrafish development.     

Combined mutagenicity of methyl methanesulfonate and ethyl methanesulfonate in Chinese hamster V79 cells.

The combined effects of methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS) on the induction of 6-thioguanine (6TG)-resistant mutants and chromosome aberrations were examined in Chinese hamster V79 cells. Cells were simultaneously treated with EMS at a concentration of D20 and MMS at various concentrations for 3, 6 or 9 h. In other experiments cells were simultaneously treated with MMS at a concentration of D20 and EMS at various concentrations for 3, 6 or 9 h. The mathematical analysis of the combined effects of both chemicals for cell killing (cytotoxicity) and 6TG-resistant mutations indicates that synergistic interactions were observed for both cell killing and mutations induced by MMS and EMS. The frequency of chromosome aberrations induced by simultaneous treatment with MMS at a concentration of D20 and EMS at various concentrations for 3 h was additive. However, the frequency of chromosome aberrations induced by EMS at a concentration of D20 and MMS at various concentrations for 3 h was not significantly different from those induced by MMS alone.     

Molecular Analysis of Mutations Induced in the Vermilion Gene of Drosophila Melanogaster by Methyl Methanesulfonate

The nature of DNA sequence changes induced by methyl methanesulfonate (MMS) at the vermilion locus of Drosophila melanogaster was determined after exposure of postmeiotic male germ cell stages. MMS is a carcinogen with strong preference for base nitrogen alkylation (s = 0.86). The spectrum of 40 intralocus mutations was dominated by AT----GC transitions (23%), AT----TA transversions (54%) and deletions (14%). The small deletions were preferentially found among mutants isolated in the F1 (8/18), whereas the AT----GC transitions exclusively occurred in the F2 (6/22). The MMS-induced transversions and deletions are presumably caused by N-methyl DNA adducts, which may release apurinic intermediates, known to be a time-related process. Furthermore, MMS produces multilocus deletions, i.e., at least 30% of the F1 mutants analyzed were of this type. A comparison of the mutational spectra of MMS with that produced by ethylnitrosourea (ENU), also in the vermilion locus of Drosophila, reveals major differences: predominantly transition mutations (61% GC----AT and 18% AT----GC) were found in both the F1 and F2 spectrum induced by ENU. It is concluded that the mutational spectrum of MMS is dominated by nitrogen DNA adducts, whereas with ENU DNA sequence changes mainly arose from modified oxygen in DNA.     

DNA damage and repair in somatic and germ cells in vivo

Alkylation-induced germ cell mutagenesis in the mouse versus Drosophila is compared based on data from forward mutation assays (specific-locus tests in the mouse and in Drosophila and multiple-locus assays in the latter species) but not including assays for structural chromosome aberrations. To facilitate comparisons between mouse and Drosophila, forward mutation test results have been grouped into three categories. Representatives of the first category are MMS (methyl methanesulfonate) and EO (ethylene oxide), alkylating agents with a high s value which predominantly react with ring nitrogens in DNA. ENU (N-ethyl-N-nitrosourea), MNU (N-methyl-N-nitrosourea), PRC (procarbazine), DEN (N-nitrosodiethylamine), and DMN (N-nitrosodimethylamine) belong to the second category. These agents have in common a considerable ability for modification at oxygens in DNA. Cross-linking agents (melphalan, chlorambucil, hexamethylphosphoramide) from the third category.The most unexpected, but encouraging outcome of this study is the identification of common features for three vastly different experimental indicators of genotoxicity: hereditary damage in Drosophila males, genetic damage in male mice, and tumors (TD₅₀ estimates) in rodents. Based on the above three category classification scheme the following tentative conclusions are drawn. Monofunctional agents belonging to category 1, typified by MMS and EO, display genotoxic effects in male germ cell stages that have passed meiotic division. This phenomenon seems to be the consequence of a repair deficiency during spermiogenesis for a period of 3–4 days in Drosophila and 14 days in the mouse. We suggest that the reason for the high resistance of premeiotic stages, and the generally high TD₅₀ estimates observed for this class in rodents, is the efficient error-free repair of N-alkylation damage. If we accept this hypothesis, then the increased carcinogenic potential in rodents, seen when comparing category 2 (ENU-type mutagens) to category 1 (MMS-type mutagens), along with the ability of category 2 genotoxins to induce genetic damage in premeiotic stages, must presumably be due to their enhanced ability for alkylations at oxygens in DNA; it is this property that actually distinguishes the two groups from each other. In contrast to category 1, examination of class 2 genotoxins (ENU and DEN) in premeiotic cells of Drosophila gave no indication for a significant role of germinal selection, and also removal by DNA repair was less dramatic compared to MMS. Thus category 2 mutagens are expected to display activity in a wide range of both post- and premeiotic germ cell stages. A number of these agents have been demonstrated to be among the most potent carcinogens in rodents. In terms of both hereditary damage and the initiation of cancers (low TD₅₀), cross-linking agents (category 3) comprise a considerable genotoxic hazard. Doubling doses for the mouse SLT have been determined for four cross-linking agents not requiring metabolic conversion and in all four cases the doubling doses for these agents were lower than those for MMS, DES and EMS. In support of this conclusion, two of 10 genotoxic agents, for which data on chromosomal aberrations were available for both somatic cells and germ cells in mice, were cross-linking agents and again the doubling dose estimates are lower than for monofunctional agents. Four cross-linking agents induced mutations in stem cell spermatogonia indicating that this type of agent can be active in a wide range of germ cell stages.Quite in contrast to what is generally observed in unicellular systems and in mammalian cells in culture, both cross-linking agents and MMS-type mutagens (high s value) predominantly produce deletion mutations in postmeiotic male germ cell stages. This is the uniform picture found for both Drosophila and the mouse. It is concluded that in vitro systems, in contrast to Drosophila germ cells, fail to predict this very intriguing feature of mouse germ line mutagenesis. In addition to their potential for induction of deletions and other rearrangements, cross-linking agents are among the most efficient inducers of mitotic recombination in Drosophila. Thus there are several mechanisms by which cross-linking agents may cause loss of heterozygosity for long stretches of DNA sequences, leading to expression of recessive genes. Since a substantial portion of agents used in the chemotherapy of cancers have cross-linking potential, the potential hazards of hereditary damage and cancers associated with this class of genotoxins should, in our opinion, receive more attention than they have in the past.     

Influence of mus201 and mus308 mutations of Drosophila melanogaster on the genotoxicity of model chemicals in somatic cells in vivo measured with the comet assay

To check the possibilities of the recently developed comet assay, to be used in mechanistic studies in Drosophila melanogaster, neuroblast cells of third instar larvae are used to analyse in vivo, the effect of two repair deficient mutations: mus201, deficient on nucleotide excision repair, and mus308, deficient in a mechanism of damage bypass, on the genotoxicity of methyl methanesulphonate (MMS), ethyl methanesulphonate (EMS) and N-ethyl-N-nitrosourea (ENU). The obtained results reveal: (1) MMS-induced breaks are most probably consequence of N-alkylation damage mediated abasic (AP) site breakage; (2) MMS and at least part of the EMS induced damage leading to DNA strand breaks are efficiently repaired by the nucleotide excision repair mechanism; (3) ENU and part of EMS induced damage need a functional Mus308 protein to be processed, otherwise they can lead to DNA strand breaks. In addition, the results of this work confirm the validity of neuroblast cells to conduct the comet assay, and the usefulness of this assay in in vivo mechanistic studies related to DNA repair in D. melanogaster.     

Effect of the yellow locus on sensitivity of drosophila sex cells to chemical mutagens

The effect of the yellow (y) locus on germ cell sensitivity to the alkylating agent ethyl methanesulfonate (EMS) has been studied in Drosophila. Since DNA repair is one of the most important factors that control cell sensitivity to mutagens, the approaches used in our experiments aimed at evaluating the relationship between germ-cell mutability and activity of DNA repair. Germ-cell mutability and repair activity were assessed using several parameters, the most important of which was the frequency of the recessive sex-linked lethal mutations (RSLLM). In one series of experiments, the adult males of various genotypes (Berlin wild; y; y ct v; y mei-9a) were treated by mutagenic agents and then crossed to Basc females. Comparative analysis of germ-cell mutability as dependent on genotype and the stage of spermatogenesis showed that the yellow mutation significantly enhanced the premeiotic cell sensitivity to EMS, presumably, due to the effect on DNA repair. In the second series of experiments, the effect of the maternal DNA repair was studied and, accordingly, mutagen-treated Basc males were crossed to females of various genotypes including y and y mei-9a ones. The crosses involving y females yielded F1 progeny with high spontaneous lethality, whereas in F2, the frequency of spontaneous mutations was twice higher. The germ cell response to EMS depended also on female genotype: the effect of yellow resulted in increased embryonic and postembryonic lethality, whereas the RSLLM frequency decreased insignificantly. The latter result may be explained by elimination of some mutations due to 50% mortality of the progeny. The results obtained using the above two approaches suggest that the yellow locus has a pleiotropic effect on the DNA repair systems in both males and females of Drosophila.     

DNA adduct formation in mouse testis by ethylating agents: a comparison with germ-cell mutagenesis

DNA adduct formation in various organs of mice was determined after i.p. injection with the ethylating agents N-ethyl-N-nitrosourea (ENU), ethyl methanesulfonate (EMS), and diethyl sulfate (DES). The potency of the 3 chemicals to react either at the O6 position of guanine or at the N-7 position of guanine was related to their potency to induce mutations in the specific-locus assay of the mouse. ENU, which produces relatively high levels of O-alkylations (O6-ethylguanine), is primarily mutagenic in spermatogonia of the mouse, whereas EMS and DES, which produce relatively high levels of N-alkylations (7-ethylguanine) in DNA, are much more mutagenic in post-meiotic stages of male germ cells. The relationship between exposure to ENU and the dose, determined as O6-ethylguanine per nucleotide in testicular DNA, is non-linear. However, the relationship between dose and mutation induction in spermatogonia by ENU appears to be linear, which is expected if O6-ethylguanine is the major mutagenic lesion. The relatively high mutagenic potency of EMS and DES in the late stages of spermatogenesis is probably due to the accumulation of apurinic sites which generate mutations after fertilization. A comparison of mutation induction by ENU in spermatogonia and mutation induction in cultured mammalian cells indicates that about 10 O6-ethylguanine residues were necessary in the coding region of a gene to generate a mutation.     

Modulation of genotoxicity in Drosophila.

The extensive knowledge of the genetics of Drosophila melanogaster and the long experimental experience with this organism have made it of unique usefulness in mutation research and genetic toxicology. The development of somatic mutation and recombination tests (SMART) has provided sensitive, rapid and cheap assays for investigations of mutagenic and recombinogenic properties of chemicals. The present paper deals with the SMART wing spot assay, developed by Graf et al. (1984). The use of two genetic markers, multiple wing hair (mwh) and flare (flr) in the third chromosome, makes it possible to discern localized recombinogenic effects on the two intervals--the major, euchromatic, part of the chromosome, and the mostly heterochromatic centromere region. The distribution of induced mitotic recombination varied between test chemicals. Ethylene oxide caused a specific increase of twin spots, indicating a localized induction of somatic recombination in the centromere region. The wing spot assay has turned out to be suitable for combined treatment with chemicals in order to study antimutagenic and other modulating effects by mutagenic and recombinogenic chemicals. Examples of the use of this assay for such a purpose are presented in this paper. The inhibitor of poly ADP-ribosylation, 3-aminobenzamide (3AB), caused a pronounced increase of wing spots, induced by alkylating agents. The data indicate that this interaction between alkylating agents and 3AB is solely due to an effect on somatic recombination but not on point mutations. The inhibitor of topoisomerases, novobiocin, which presumably acts on the chromatin configuration, had different modulating effects on spots induced by methyl methanesulfonate (MMS) and ethylnitrosourea (ENU). Novobiocin essentially acted as an antirecombinogenic agent in cotreatment experiments with MMS and as antimutagenic agent with ENU. Attempts to interfere with mutagenic and recombinogenic effects of the radical-generating agents bleomycin, menadione and paraquat, by agents acting on the defence mechanisms against oxygen radicals, were essentially unsuccessful.     

Differential sensitivity of DNA replication and repair in permeable Escherichia coli exposed to various monofunctional methylating or ethylating agents.

Escherichia coli cells made permeable to deoxynucleoside triphosphates by brief treatment with toluene (permeablized) were used to measure the effect of the following chemical alkylating agents on either DNA replication or DNA repair synthesis: methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), N-methyl-N-nitrosourea (MNU), N-ethyl-N-nitrosourea (ENU), N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and N-ethyl-N′-nitro-N-nitrosoguanidine (ENNG). Replication of DNA in this pseudo-in vivo system was completely inhibited 10–15 min after exposure to MMS at concentrations of 5 mM or higher or to MNU or MNNG at concentrations of 1 mM or higher. The ethyl derivatives of the alkylating agents were less inhibitory than their corresponding methyl derivatives, and inhibition of DNA replication occurred in the following order: EMS < ENNG < ENU. Maximum inhibition of DNA replication by all of the alkylating agents tested except EMS occurred at a concentration of 20 mM or lower. The extent of replication in cells exposed to EMS continued to decrease with concentrations of EMS up to 100 mM (the highest concentration tested).The experiments in which the inhibition of DNA replication by MMS, MNU, or MNNG was measured were repeated under similar assay conditions except that a density label was included and the DNA was banded in CsCl gradients. The bulk of the newly synthesized DNA from the untreated cells was found to be of the replicative (semi-conservative) type. The amount of replicative DNA decreased with increasing concentration of methylating agent in a manner similar to that observed in the incorporation experiments.Polymerase I (Pol I)-directed DNA repair synthesis induced by X-irradiation of permeablized cells was assayed under conditions that blocked the activity of DNA polymerases II and III. Exposure of cells to MNNG or ENNG at a concentration of 20 mM resulted in reductions in Pol I activity of 40 and 30%, respectively, compared with untreated controls. ENU was slightly inhibitory to Pol I activity, while MMS, EMS, and MNU all caused some enhancement of Pol I activity.These data show that DNA replication in a pseudo-in vivo bacterial system is particularly sensitive to the actions of known chemical mutagens, whereas DNA repair carried out by the Pol I repair enzyme is much less sensitive and in some cases apparently unaffected by such treatment. Possible mechanisms for this differential effect on DNA metabolism and its correlation with current theories of chemically induced mutagenesis and carcinogenesis are discussed.     

Preventive action of thioethers towards in vitro DNA binding and mutagenesis in E. coli K12 by alkylating agents

Thioethers are effective scavengers of electrophilic metabolites derived from the hepatocarcinogen N-hydroxy-2-acetylaminofluorene (van den Goorbergh et al., 1987). In this study 2 of these thioethers, 4-(methylthio)benzoic acid (MTB) and its methylester, methyl 4-(methylthio)benzoate (MMTB), have been tested for their ability to prevent in vitro DNA binding and mutation induction in E. coli K12 by the direct alkylating agents ethylnitrosourea (ENU), methylnitrosourea (MNU), ethyl methanesulfonate (EMS) and methyl methanesulfonate (MMS). In addition to MTB and MMTB, the thioether L-methionine (Met), and the thiols glutathione (GSH) and L-cysteine (Cys) were included for reasons of comparison. MTB was able to (partially) prevent DNA binding and mutation induction by ENU. However, this thioether was ineffective with EMS. DNA binding and mutagenesis by EMS were (partially) prevented by GSH and Cys, while these thiols could not prevent DNA binding and mutation induction by ENU. MMTB was unable to prevent mutation induction by these ethylating agents. With the methylating agents, similar effects of MTB were observed: MTB effectively prevented mutation induction by MNU while it was much less effective towards MMS. GSH and Cys were comparably effective as antimutagenic agents towards both methylating agents. Met was unable to prevent either DNA binding or mutation induction by these agents. Taken together, the results show that aromatic thioethers are able to trap genotoxic electrophiles derived from the nitrosoureas ENU and MNU, and may therefore act as potential anticarcinogens towards these agents, which are only poorly detoxified by GSH.