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.     

Comparison of dose-response relationships for ethyl methanesulfonate and 1-ethyl-1-nitrosourea in Drosophila melanogaster spermatozoa

The relative importance of different sites of alkylation on DNA was determined by comparing two ethylating agents. 1-Ethyl-1-nitrosourea (ENU) ethylates DNA with a higher proportion of total adducts on ring oxygens than ethyl methanesulfonate, which ethylates with a higher proportion of total adducts on the N-7 of guanine. Research with somatic cells in culture and prokaryotes strongly suggests that O6-guanine (O6-G) is the principal genotoxic site. To determine the importance in germ-line mutagenesis of the O6-G site relative to the N-7 of guanine, dose-response curves were constructed for both ENU and EMS, where dose was measured as total adducts per deoxynucleotide (APdN) and response as sex-linked recessive lethals (SLRL) induced in Drosophila melanogaster spermatozoa. For both mutagens the dose response curve was linear and extrapolated to the origin. The dose-response curve for ENU was fit to an equation m = 6.2D, and the dose response curve for EMS, from this and previous experiments, was m = 3.2D where m = %SLRL and D = APdN X 10(-3). Therefore, ENU is 1.9 times more efficient per adduct in inducing SLRL mutations than EMS. In vitro studies showed that ENU induced 9.5% of its total adducts on O6-G while EMS induced 2.0% of its adducts on O6-G. If O6-G was the sole genotoxic site, then ENU should be 4.8 times more efficient per adduct than EMS. In contrast, if N-7 G was the sole genotoxic site, ENU would be only 0.19 as effective as EMS. It was concluded that while O6-G was the principal genotoxic site, N-7 G made a significant contribution to germ-line mutagenesis.     

Relationship between specific alkylated bases and mutations at two gene loci induced by ethylnitrosourea and diethyl sulfate in CHO cells

DNA adduct formation and induction of mutations at 2 gene loci, hypoxanthine-guanine-phosphoribosyltransferase (HPRT) and Na,K-ATPase, were determined simultaneously in Chinese hamster ovary (CHO) cells after treatment with 2 ethylating agents, ethylnitrosourea (ENU) or diethyl sulfate (DES). Doses of DES and ENU, which resulted in equal levels of O6-ethylguanine (O6-EtGua) and O4-ethylthymine (O4-EtThy) in the DNA, were found to induce very similar frequencies of 6-thioguanine-resistant (6-TGr) mutants. Formation of these DNA adducts might therefore be correlated with mutations induced at the HPRT locus. When, however, the same analysis was applied to ouabain-resistant (ouar) mutants, it was found that, at similar levels of O6-EtGua and O4-EtThy, DES induced many more ouar mutants than ENU. This result supports the notion that primary DNA lesions other than O6-EtGua and O4-EtThy are involved in the fixation of ENU- and DES-induced mutations at the Na,K-ATPase gene locus.     

Mutagenesis in Oocytes of DROSOPHILA MELANOGASTER. I. Scheduled Synthesis of Nuclear and Mitochondrial DNA and Unscheduled DNA Synthesis

As a model system for studying mutagenesis, the oocyte of Drosophila melanogaster has exhibited considerable complexity. Very few experiments have been conducted on the effect of exposing oocytes to chemical mutagens, presumably due to their lower mutational response relative to sperm and spermatids. This lower response may be due either to a change in probability of mutation induction per adduct due to a change in the type of DNA repair or to a lower dose of the mutagen to the female germ line. To study molecular dosimetry and DNA repair in the oocyte, the large number of intracellular constituents (mtDNA, RNA, nucleic acid precursors and large quantities of proteins and lipids) must be separated from nuclear DNA. In this paper we present results showing reliable separation of such molecules enabling us to detect scheduled nuclear and mitochondrial DNA synthesis. We also, by understanding the precise timing of such events, can detect unscheduled DNA synthesis (UDS) as a measure of DNA repair. Furthermore, by comparing the UDS results in a repair competent (Ore-R) vs. a repair deficient (mei-9^L1 ) strain, we have shown the oocyte capable of DNA repair after treatment with ethyl methanesulfonate (EMS). We conclude that the important determinant of mutation induction in oocytes after treatment with EMS is the time interval between DNA alkylation and DNA synthesis after fertilization, i.e., the interruption of continuous DNA repair.     

Monoclonal antibody-based, selective isolation of DNA fragments containing an alkylated base to be quantified in defined gene sequences.

We have established a sensitive, monoclonal antibody (Mab)-based procedure permitting the selective enrichment of sequences containing the miscoding alkylation product O6-ethylguanine (O6-EtGua) from mammalian DNA. H5 rat hepatoma cells were reacted with the N-nitroso carcinogen N-ethyl-N-nitrosourea in vitro, to give overall levels of greater than or equal to 25 O6-EtGua residues per diploid genome (corresponding to O6-EtGua/guanine molar ratios of greater than or equal to 10(-8). For analysis, enzymatically restricted DNA from these cells is incubated with an antibody specific for O6-ethyl-2'-deoxyguanosine, the resulting Mab-DNA complexes are separated from (O6-EtGua)-free fragments by filtration through a nitrocellulose (NC) membrane, and the DNA is recovered from the filter-bound complexes quantitatively. The efficiency of Mab binding to DNA fragments containing O6-EtGua is constant over a range of O6-EtGua/guanine molar ratios between 10(-5) and 10(-8). (O6-EtGua)-containing restriction fragments encompassing known gene sequences (e.g., the immunoglobulin E heavy chain gene of H5 rat hepatoma cells used as a model in this study) are subsequently amplified by PCR and quantified by slot-blot hybridisation. The content and distribution of a specific carcinogen-DNA adduct in defined sequences of genomic DNA can thus be analyzed as well as the kinetics of intragenomic (toposelective) repair of any DNA lesion for which a suitable Mab is available.     

Mutagenic effectiveness and efficiency of sodium azide versus ethyl methanesulfonate in maize: induction of somatic mutations at the yg2 locus by treatment of seeds differing in metabolic state and cell population.

This study was conducted to compare the effectiveness and efficiency of sodium azide tNaN3) and ethyl methanesulfonate (EMS) for inducing somatic mutations at the yg2 locus in maize seeds of two different metabolic states and cell populations. Dormant or presoaked (72 h at 20 degrees C) seeds heterozygous for yg2 locus were treated with different concentrations of either EMS or NaN3. The cell populations with respect to the percentage of cells in G1, S, G2, and M were also determined for seeds of the two metabolic states. Dormant seeds possessed a higher percentage of cells in G1 and the presoaked seeds a higher percentage of cells in S, G2, and M. The frequency of yg2 sectors in leaves 4 and 5 increased with increasing concentration of both mutagens in both dormant and presoaked seeds. Both mutagens were more effective and efficient in the presoaked seeds. NaN3 was more effective than EMS in terms of number of sectors induced per unit of dose. However, EMS was more efficient as determined by sectors induced per unit of seedling injury and clearly had the ability to induce much higher sector frequencies (more than 10 times greater) than NaN3. The low ability of NaN3 (compared to EMS) to induce mutant sectors may be related to the cells not being treated at the optimum time during the cell cycle, but it is more likely due to its low effectiveness for inducing chromosome aberrations.     

In vitro reactions of isopropyl methanesulfonate with DNA and with 2'-deoxyribonucleosides

Isopropyl methanesulfonate (IPMS), an SN1 alkylating agent, is a direct-acting mutagen in bacteria. We recently reported that s.c. and topical administration of IPMS to mice resulted in the rapid induction of thymic lymphomas. Thymic lymphoma induction was not observed following administration of the SN2 alkylating agents methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS). We have studied the reactions of IPMS with dAdo, dCyd, dGuo and dThd at pH 6.5 to 7.5 and 37 degrees C for 3 h. IPMS formed the following isopropyl (IP) adducts: 7-IP-Gua (4% yield), O6-IP-Gua (8%), O2-IP-Cyt (1%), O2-IP-dThd (2%), 3-IP-dThd (1%), and O4-IP-dThd (0.4%). Adducts were characterized from UV and mass spectra. IPMS was reacted in vitro with calf thymus DNA (pH 6.5 to 7.5, 37 degrees C, 3 h) and yielded (nmol/mg DNA): 7-IP-Gua (22) O6-IP-dGuo (11), O2-IP-Cyt (9), O2-IP-dThd (2), O4-IP-dThd (2), 3-IP-Ade (0.2) and 3-IP-dThd (0.2). The relatively greater alkylation of exocyclic oxygen atoms in DNA by IPMS compared to values for MMS and EMS reported by others, may play a role in the induction of thymic lymphomas in mice by IPMS and the lack of such activity by MMS and EMS.     

Analysis of repair processes by the determination of the induction of cell killing and mutations in two repair-deficient Chinese hamster ovary cell lines

Two UV sensitive DNA-repair-deficient mutants of Chinese hamster ovary cells (43-3B and 27-1) have been characterized. The sensitivity of these mutants to a broad spectrum of DNA-damaging agents: UV254nm, 4-nitroquinoline-1-oxide (4NQO), X-rays, bleomycin, ethylnitrosourea (ENU), ethyl methanesulphonate (EMS), methyl methanesulphonate (MMS) and mitomycin C (MMC) has been determined. Both mutants were not sensitive to X-rays and bleomycin. 43-3B was found to be sensitive to 4NQO, MMC and slightly sensitive to alkylating agents. 27-1 was sensitive only to alkylating agents. The results suggest the existence of two repair pathways for UV-induced cytotoxicity: one pathway which is also used for the removal of 4NQO and MMC adducts and a second pathway which is also used for the removal of alkyl adducts. Parallel to the toxicity, the induction of mutations at the HPRT and Na+/K+-ATPase loci was determined. The increased cytotoxicity to UV, MMC and 4NQO in 43-3B cells and the increased cytotoxicity to UV in 27-1 cells correlated with increased mutability. It was observed that the increase in mutation induction at the HPRT locus was higher than that at the Na+/K+-ATPase locus. As only point mutations give rise to viable mutants at the Na+/K+-ATPase locus the lower mutability at this locus suggests that defective excision repair increases the chance for deletions. Despite an increased cytotoxicity to ENU in 27-1 cells the mutation induction by ENU was the same in 27-1 and wild-type cells at both loci, which suggests that the mutations are mainly induced by directly miscoding adducts (e.g. O-6 alkylguanine), which cannot be removed by CHO cells. As EMS and MMS treatment of 27-1 cells caused an increase in mutation induction at the HPRT locus and a decrease at the Na+/K+-ATPase locus it indicates that these agents induce a substantial fraction of other mutagenic lesions, which can be repaired by wild-type cells. This suggests that O-6 alkylation is not the only mutagenic lesion after treatment with alkylating agents.     

Function and organization of the G region of bacteriophage Mu; Host specificity determined by gene splicing

Chinese hamster ovary (CHO) cells were exposed to [³H]ethyl nitrosourea (ENU) or [³H]ethyl methanesulfonate (EMS) and the following DNA ethylation products were quantitated: 3- and 7-ethyladenine, O²-ethylcytosine, 3-, 7- and O⁶-ethylguanine, O²- and O⁴-ethyldeoxythymidine and the representative ethylated phosphodiester, deoxythymidylyl (3′–5′)ethyl-deoxythymidine. When mutations at the hypoxanthine-guanine phosphoribosyl transferase (HGPRT) locus induced by these same treaments were compared with the observed ethylation products, mutations were found to correlate best with 3- and O⁶-ethylguanine. EMS induced approximately twice as many sister-chromatid exchanges (SCEs) as ENU at doses yielding equal mutation frequencies. When SCEs were indirectly compared with DNA ethylation products, 3-ethyladenine and ethylated phosphodiesters related best to SCE formation. Because mutation and SCE induction appear, at least in part, to be related to different DNA adducts, SCE induction by simple ethylating agents may not be a quantitative indicator of potentially mutagenic DNA damage.     

Distribution of methyl and ethyl adducts following alkylation with monofunctional alkylating agents

Alkylating agents, because of their ability to react directly with DNA either in vitro or in vivo, or following metabolic activation as in the case of the dialkylnitrosamines, have been used extensively in studying the mechanisms of mutagenicity and carcinogenicity. Their occurrence is widespread in the environment and human exposure from natural and pollutant sources is universal. Since most of these chemicals show varying degrees of both carcinogenicity and mutagenicity, and exhibit compound-specific binding patterns, they provide an excellent model for studying molecular dosimetry. Molecular dosimetry defines dose as the number of adducts bound per macromolecule and relates the binding of these adducts to the human mutagenic or carcinogenic response. This review complies DNA alkylation data for both methylating and ethylating agents in a variety of systems and discusses the role these alkylation products plays in molecular mutagenesis.     

Enhancing effects of cytosine arabinoside on ethyl methanesulfonate-induced 6-thioguanine resistance mutations in Chinese hamster V79 cells

We studied the synergistic enhancement effects of two chemicals which are different in their mechanism of action on DNA in cells. The test chemicals used were ethyl methanesulfonate (EMS) as an alkylating agent and cytosine arabinoside (Ara-C) as an analogue of cytidine. For determination of mutagenesis we measured the induction of resistance to 6-thioguanine (6-TG) in Chinese hamster V79 cells. EMS had a strong mutagenic effect on V79 cells, but for Ara-C the results were less clear. In this study, Ara-C had no detectable effect in inducing mutation up to a concentration of 5 X 10(-4) M. The mutation frequency of combined treatment with EMS and Ara-C was significantly higher than that obtained with EMS alone. These results indicate that Ara-C had an enhancing effect on mutations induced by EMS.     

Dosimetry studies on the ethylation of mouse sperm DNA after in vivo exposure to (3H)ethyl metanesulfonate

Methods for determining the chemical dose of ethyl methanesulfonate (EMS) to the DNA of mouse spermatozoa in the vasa deferentia and epididymides have been developed. These include procedures for the removal of contaminating protamine, which, like DNA, possesses nucleophilic sites that can be ethylated by EMS. At least 99% of all sperm protamine (at a 95% confidence level), as well as any other cellular contaminants, is removed during purification of the DNA. The purified DNA recovered from spermatozoa gives no indication of a preferential recovery of either (G+C)-rich or (A+T)-rich regions of the mouse genome: the [¹⁴C]dT/[³H]dC ratios for whole sperm and sperm DNA were the same for each animal tested.The spermatozoa of males used in the dosimetry studies were labeled with [¹⁴C]thymidine, and then the animals were given various [³H]EMS doses intraperitoneally. A constant exposure time of 4 h was used. The ratios of ³H and ¹⁴C activities in whole sperm and purified sperm DNA were used to measure the percentage of the total sperm ethylation occurring in the DNA. The maximum percentage found was about 18% in the dose range of 100–400 mg/kg. Values for the ethylations per nucleotide (E/N) ranged from ～ 10^?7 at 3.3 mg/kg up to ～ 10^?4 at 400 mg/kg, and the data indicated that E/N increased with the 1.5 power of the dose. E/N was also measured in testicular DNA, and the values obtained were close to those found for spermatozoan DNA.The results of such chemical dosimetry studies will be far-reaching in the interpretation of molecular events responsible for genetic alterations. As an example, dominant lethal studies by others, using EMS in the dose range considered in the present paper, have shown little or no effect until two or more days after injection of the mutagen into male mice. Since many sperm DNA ethylations are found after a 4-h exposure to EMS it appears that most of these DNA ethylations are not genetically important, at least in the production of dominant lethals, and that perhaps genetic damage occurs only at rarely ethylated DNA sites.     

Dose-rate effects of ethyl methanesulfonate on survival and mutation induction in cultured Chinese hamster cells

The dose-rate effects of ethyl methanesulfonate (EMS) on the survival and induction of mutations in Chinese hamster Don cells were investigated. The most effective time of exposure to EMS for reducing the surviving fraction of cells was 4 h, shorter and longer exposure times being less effective. The threshold or minimal concentration of EMS giving a surviving fraction of 0.5 was 0.05 mg/ml. The minimal effective time of exposure to EMS for cell death was 1 h. Corrected survival curves showed that longer exposure times at lower dose rates of EMS had less cytotoxic effect than shorter exposure times at higher dose rates.After exposure of Don cells to various doses of EMS for various times, the frequencies of mutations resistant to 6-thioguanine (6TG) were measured. An exposure time of 4 h produced a lower mutation frequency than shorter or longer exposure times that resulted in the same surviving fraction of cells. An exposure time of 20 h produced the highest induced mutation frequency.This system using cultured Chinese hamster cells should be useful as a sensitive procedure for detecting the mutagenic actions of chemicals.     

The relationship between reaction kinetics and mutagenic action of monofunctional alkylating agents in higher eukaryotic systems. IV. The effects of the excision-defective mei-9L1 and mus(2)201D1 mutants on alkylation-induced genetic damage in Drosophila

Repair-defective mutants of Drosophila melanogaster which identify two major DNA excision repair loci have been examined for their effects on alkylation-induced mutagenesis using the sex-linked recessive lethal assay as a measure of genotoxic endpoint. The alkylating agents (AAs) chosen for comparative analysis were selected on the basis of their reaction kinetics with DNA and included MMS, EMS, MNU, DMN, ENU, DEN and ENNG. Repair-proficient males were treated with the AAs and mated with either excision-defective mei-9L1 or mus(2)201D1 females or appropriate excision-proficient control females. The results of the present work suggest that a qualitative and quantitative relationship exists between the nature and the extent of chemical modification of DNA and the induction of of genetic alterations. The presence of either excision-defective mutant can enhance the frequency of mutation (hypermutability) and this hypermutability can be correlated with the Swain-Scott constant S of specific AAs such that as the SN1 character of the DNA alkylation reaction increases, the difference in response between repair-deficient and repair-proficient females decreases. The order of hypermutability of AAs with mei-9L1 relative to mei-9+ is 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 are plotted against those determined for control females, straight lines of different slopes are obtained. These mei-9L1/mei-9+ indices are: MMS = 7.6, MNU = 5.4, DMN = 2.4, EMS = 2.4 and iPMS = ENU = DEN = ENNG = 1. An identical order of hypermutability with similar indices is obtained for the mus(2)201 mutants: MMS(7.3) greater than MNU (5.4) greater than EMS(2.0) greater than ENU(1.1). Thus, absence of excision repair function has a significant effect on mutation production by AAs efficient in alkylating N-atoms in DNA but no measurable influence on mutation production by AAs most efficient in alkylating O-atoms in DNA. The possible nature of these DNA adducts has been discussed in relation to repair of alkylated DNA. In another series of experiments, the effect on alkylation mutagenesis of mei-9L1 was studied in males, by comparing mutation induction in mei-9L1 males vs. activity in Berlin K (control). Although these experiments suggested the existence of DNA repair in postmeiotic cells during spermatogenesis, no quantitative comparisons could be made.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction and expression of mutations in mammalian cells in the absence of DNA synthesis and cell division

The induction of mutations by the alkylating agent ethyl methanesulfonate (EMS) was determined with Chinese hamster ovary cells maintained in serum-free medium to arrest DNA synthesis and cell division. The arrested cultures were treated with EMS and maintained in serum-free medium for various time intervals post-treatment before serum containing medium was added to initiate DNA synthesis and cell division. The concentration-dependent increase in 6-thioguanine-resistant mutants in the arrested cultures was similar to that found with exponentially dividing cultures when serum was added to the arrested cultures immediately after the EMS treatment; the time course of phenotypic expression was also similar with both cultures. In addition, maintenance of the arrested cultures in serum-free medium for up to 18 days post-treatment resulted in no change in the mutant frequency. This suggests that the mutagenic damage is not removed in these arrested cultures. Furthermore, maintenance of the arrested state for increasing time intervals before serum addition results in decreases in the time necessary for maximum phenotypic expression. Cultures maintained in serum-free medium for 16 days after mutation treatment show complete expression of the mutations with no need for subculture. This last result suggests that the mutagenic damage induced by EMS in Chinese hamster ovary cells is not removed and that this damage results in both the induction and expression of mutation in the absence of DNA replication.     

Polymorphisms of phase II xenobiotic-metabolizing and DNA repair genes and in vitro N-ethyl-N-nitrosourea-induced O6-ethylguanine levels in human lymphocytes

This study tested the hypothesis that genetic variants of phase II detoxification enzymes and DNA repair proteins affect individual response to DNA damage from alkylating agents. In 171 healthy individuals, an immunoslot blot assay was used to measure O6-ethylguanosine (O6-EtGua) adduct levels in peripheral blood lymphocytes treated with N-ethyl-N-nitrosourea (ENU) in vitro. The genotypes of GSTM1, GSTT1, GSTP1 I(105)V and A(114)V, MGMT L(84)F and I(143)V, XPD D(312)N and K(751)Q, and XRCC3 T(241)M were determined. Demographic and exposure information was collected by in-person interview. Student's t-test, analysis of (co)variance, and multiple linear regression models were used in statistical analyses. The mean and median (range) O6-EtGua levels were 94.6 and 84.8 (3.2-508.1)fmol/g DNA, respectively. The adduct level was significantly lower in people who smoked >or=25 years than that in never-smokers (square-root transformed mean values 8.20 versus 9.37, P=0.03). Multiple linear regression models revealed that GSTT1 (beta=-2.36, P=0.009) polymorphism was a significant predictor of the level of adducts in 82 never-smokers, whereas the number of years smoked (beta=-0.08, P=0.005) and XRCC3 T(241)M (beta=2.22, P=0.007) in 89 ever-smokers. The association between GSTP1 I(105)V, MGMT I(143)V, and XPD D(312)N with the level of adducts was not conclusive. Each polymorphism could explain 2-10% of the variation of the adduct level. These observations suggest that GSTT1 null and XRCC3 T(241)M polymorphism may have some functional significance in modulating the level of ENU-induced DNA damage and these effects are smoking-dependent. Results from this exploratory study need to be confirmed in other experimental systems.     

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.     

Ethylation pf DNA and protamine by ethyl methanesulfonate in the germ cells of male mice and the relevancy of these molecular targets to the induction of dominant lethals

The molecular dosimetry of ethyl methanesulfonate (EMS) in the germ cells of male mice has been investigated. The mice were injected i.p. with 200 mg/kg of [³H]EMS and the ethylations per sperm head, per deoxynucleotide, and per unit of protamine were then determined over a 2-week period. The ethylations per sperm head closely paralleled the dominant-lethal frequency curve for EMS, reaching a maximum of 5 to 6.5 million ethylations per vas sperm head at 8 to 10 days after treatment. Ethylation of sperm DNA was greatest at 4 h after treatment, with 5.7 ethylations/10⁵ deoxynucleotides, and gradually decreased to 2.2 ethylations/10⁵ deoxynucleotides at 15 days after treatment. The ethylation of sperm DNA did not increase in the germ-cell stages most sensitive to EMS, ans was not correlated with the dominant-lethal frequency curve for EMS. However, ethylation of sperm protamine did increase in the germ-cell stages most sensitive to EMS, and showed an excellent correlation with the incidence of dominant lethals produced by EMS in the germ cells.A model is presented to explain, at a molecular level, how dominant lethals may be induced in mouse germ cells by EMS. Ethylation by cysteine sulfhydryl groups contained in mouse-sperm protamine could block normal disulfidebond formation, preventing proper chromatin condensation in the sperm nucleus. Stresses in the chromatin structure could then eventually lead to chromosome breakage, with resultant dominant lethality.     

Induction of specific-locus mutations in male mice by ethyl methanesulfonate (EMS)

Using a sequential mating procedure, the induction of specific-locus mutations by ethyl methanesulfonate (EMS) was reinvestigated in male mice. Doses of 175 mg/kg b.w. and 250 mg/kg b.w. of EMS induce gene mutations in the mating intervals 5-8 and 9-12 days post treatment. However, only the frequency of dominant lethal mutations increases with the dose, not the frequency of specific-locus mutations. This observation implies that with a higher dose of EMS a larger fraction of mutagenized spermatozoa and spermatids are selectively eliminated, leading to underestimation of the specific-locus mutation yield at high doses. EMS does not induce specific-locus mutations in spermatogonia.