An autoradiographic study of unscheduled DNA synthesis in the germ cells of male mice treated with X-rays and methyl methanesulfonate

Unscheduled DNA synthesis (UDS) in the germ cells of male mice after in vivo treatment with X-rays or methyl methanesulfonate (MMS) was assayed by use of a quantitative autoradiographic procedure. MMS induced UDS in meiotic through type III elongating spermatid stages, whereas X-rays induced UDS in meiotic through round spermatid stages. No UDS was detected in the most mature spermatid stages present in the testis with either MMS or X-rays. Taking into account differences in DNA content of the various germ-cell stages studied, we concluded that X-rays induced a maximum UDS response in spermatocytes at diakinesis--metaphase I. The level of UDS induced by MMS was about the same in all the stages capable of repair. Chromosome damage and UDS were measured simultaneously in the same spermatocytes at diakinesis 90 min after X-irradiation or MMS treatment. The level of UDS in most of the X-irradiated cells paralleled the extent of chromosome damage induced. A statistical analysis of these results revealed a positive correlation. As expected, MMS induced no chromosome aberrations above control levels. Therefore no correlation was determined between UDS and chromosome damage in this case. The distribution of UDS over the chromosomes treated at diakinesis with MMS or X-rays was studied. It was found that UDS occurred in clusters in the irradiated cells, whereas it was uniformly distributed in the MMS-treated cells.     

Studies on DNA repair in early spermatid stages of male mice after in vivo treatment with methyl-, ethyl-, propyl-, and isopropyl methanesulfonate.

In vivo DNA repair occurring in early spermatid stages of the mouse has been studied with four mutagens that are chemical homologs: MMS, EMS, PMS and IMS. Using the well-studied sequence of events that occurs during spermatogenesis and spermiogenesis in the mouse, aatids was measured by the unscheduled incorporation of [3H]dT into these germ cells which were recovered from the caudal epididymides 16 days after chemical treatment. Purification of the caudal sperm DNA at this time verified that the [3H]dT was incorporated into the DNA. For each chemical mutagen a study was made on the level of DNA repair occurring in early spermatids as a function of the administered, in vivo dose. Within experimental errors, all four chemicals produced a linear increase in DNA repair in early spermatids with increasing dose. Only the highest dose of MMS (100 mg/kg) produced a greater repair response than expected for a linear curve. At equimolar doses the most effective chemical in inducing DNA repair was MMS, followed by EMS, IMS and PMS. When testicular injections of [3H]dT were given at the same time as the intraperitoneal injections of the mutagens, the amount of unscheduled incorporation of [3H]dT into the DNA of early spermatids was maximized. Since [3H]dT has been shown to be available for incorporation into germ-cell DNA for only approximately 1 h after injection, all four mutagens must reach the DNA of early spermatids and begin producing "repairable" lesions within 1 h after treatment. The amount of DNA repair occurring at later times after chemical treatment of early spermatids was studied by testicular injections of [3H]dT 1/2, 1, 2 and 3 days after chemical treatment. Repair was still occurring in the early spermatids at 3 days post-treatment; this repair is most likely a manifestation of the finite rate of the repair process rather than resulting from newly alkylated DNA. For MMS and EMS there was a rapid decrease in the level of DNA repair in the first 1/2 day following treatment. This was followed by a much slower, exponential decrease in the level of repair out to 3 days post-treatment. The curves suggest that the amount of repair is proportional to the number of repairable lesions still present in the DNA. For PMS and IMS the level of repair decreases rapidly in the first 1/2 day after treatment and thereafter remains relatively constant through 3 days post-treatment. With all four mutagens, DNA repair in early spermatids was detectable at doses 5 to 10 times lower than those required to observe other genetic end points such as dominant lethals, translocations and specific-locus mutations in any germ-cell stage. The sensitivity of detection of in vivo DNA repair in the germ cells of male mice makes such a system a useful adjunct to other genetic tests for studying chemical mutagenesis in mammals.     

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.     

Unscheduled DNA synthesis induced in mouse spermatids after combined treatment with methyl methanesulfonate and X-rays.

Unscheduled DNA synthesis (UDS), which is considered to be DNA repair, has been studied in early- to mid-spermatid stages of the mouse after combined treatments with X-rays and methyl methanesulfonate (MMS). UDS in spermatids was detected by giving testicular injections of [methyl-3H]thymidine ([3H]dThd) and making use of the fact that no scheduled DNA synthesis occurs in the germ cells after the last S period in primary spermatocytes. X-rays and MMS are each able to induce UDS in mouse spermatids. However, there was a statistically significant reduction in the amount of UDS observed when X-ray exposures of from 200 to 600 R were given 4 h before an i.p. injection of 75 mg/kg of MMS and concurrent testicular injections of [3H]dThd. This reduction in UDS is more than can be explained by the completion of repair of X-ray-induced DNA lesions. We suggest that the reduction in UDS is the result of an X-ray-produced impairment of a least a part of the repair mechanism involved in correcting MMS-induced DNA lesions. When the time interval between a 600-R X-ray exposure and MMS treatment was between 3 and 20 h (latest time interval s;udied) there was a statistically significant reduction of UDS in the spermatids. No significant decrease in UDS response occurred when the time interval between radiation exposure and MMS treatment was less than approximately 3 h.     

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.     

In vivo genotoxicity of nitrates and nitrites in germ cells of male mice. II. Unscheduled DNA synthesis and sperm abnormality after treatment of spermatids

Effects of both sodium nitrate (doses of 600 and 1200 mg/kg/day for 3 days) and sodium nitrite (doses of 60 and 120 mg/kg/day for 3 days) on spermatids of mice were investigated by measuring unscheduled DNA synthesis (UDS) 17 days after the end of treatment, and sperm-head abnormality 11 and 17 days after the end of treatment. Neither chemical induced the UDS response in early to mid spermatids (17 days). The only positive result in the sperm-head abnormality test was obtained for the dose of 120 mg/kg/day of sodium nitrite both at 11 and 17 days after treatment. The results presented are in accordance with those of our earlier experiments with the same chemicals, suggesting their nonmutagenic action on the tested germ-cell stages of male mice.     

Somatic cell mutagenicity in Drosophila melanogaster in comparison with genetic damage in early germ-cell stages

With the intention of assessing the general performance, sensitivity and the underlying mechanisms of somatic cell mutagenicity assays in Drosophila, a study was undertaken to compare the effectiveness of 5 procarcinogens and 4 direct-acting agents in the white/white-coral eye mosaic assay (SMART) with their activity in early (premeiotic) male and female germ-cell stages, after exposure of Drosophila larvae. The outcome indicated a lack of agreement in the results from recessive lethal assays (SLRL) in comparison with the somatic mutation and recombination test (SMART). The procarcinogens 2-naphthylamine (NA), 3-methylcholanthrene (MC), 9,10-dimethylanthracene (DA) and 7,12-dimethylbenz[a]anthracene (DMBA), and the direct-acting mutagens bleomycin (BM), methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS), were quite efficient in producing somatic recombination and mutations in white/white-coral larvae, as opposed to only weak effects in early germ-cell stages. 2-Acetylaminofluorene (2AAF) showed marginal effects in both germ cells and somatic tissue after exposure of female larvae, but was inactive in testis. The discrepancy in mutational response between somatic cells and premeiotic germ cells is most impressive for MMS and BM. There is sufficient evidence for attributing a good sized proportion of the encountered variation to efficient error-free DNA repair of premutational damage and to segregational elimination during meiosis of deleterious mutations: (1) The efficient point mutagen ENU was the but one agent producing high levels of viable genetic alterations in early germ cells and in somatic cells. A similar behaviour was previously described for diethylnitrosamine, which ethylates DNA in the same fashion as ENU. (2) In early germ-cell stages of mei-9L1 male larvae, MMS induced multiple mutations (putative clusters) at a low dose differing by a factor 20-40 from those needed to produce an equivalent response in repair-competent strains. This is consistent with the concept of an active excision repair in premeiotic cells. (3) In the case of EMS, next to DNA repair, germinal selection seems to restrict the realization of EMS-induced genetic damage in premeiotic cells. (4) Bleomycin-induced chromosome aberrations caused high mortality rates in males (hemizygous for an X-chromosome) but not in females. MMS and BM, agents known to show preference for chromosome aberration induction, produced 3-6-fold higher rates of somatic mutational events (SME) in female genotypes as compared with the other sex.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Activity of germ-cell mutagens and nonmutagens in the rat spermatocyte UDS assay

The ability of 13 chemicals of known germ-cell mutagenicity to induce unscheduled DNA synthesis (UDS) in rat spermatocytes was examined. At selected times following i.p. injection of test compounds, spermatocytes were isolated from Fischer 344 rats by enzymatic digestion of the seminiferous tubules and cultured for 24 h in the presence of [3H]thymidine. 7 compounds, methyl methanesulfonate, triethylenemelamine, cyclophosphamide, methylnitrosourea, ethylnitrosourea, procarbazine, and dibromochloropropane produced positive UDS responses in spermatocytes. These chemicals are also positive for specific locus mutations, heritable translocations, or dominant lethal mutations when administered to male rodents. Mitomycin C, which produces DNA interstrand crosslinks and induces heritable mutations and translocations in male germ cells, failed to stimulate UDS in rat spermatocytes. Germ-cell nonmutagens N-methyl-N'-nitro-N-nitrosoguanidine, dimethylnitrosamine, 4-nitroquinoline 1-oxide, and ethylene dibromide were negative in the rat spermatocyte UDS assay. Correlation of these results with those of other assays for heritable mutations in germ cells indicates that the in vivo/in vitro spermatocyte DNA repair assay is useful in predicting the mutagenic potential of chemicals in male germ cells.     

Induction of specific-locus and dominant-lethal mutations by cyclophosphamide and combined cyclophosphamide-radiation treatment in male mice

Cyclophosphamide is the most widely used antineoplastic agent. It is also used to condition patients for bone-marrow transplantations. Because of the general interest of this compound we initiated a systematic study of the induction of dominant-lethal and specific-locus mutations in male mice. In addition, we investigated the induction of specific-locus mutations by the combined treatment of cyclophosphamide and ionizing radiation.A dose of 40 mg/kg bw of cyclophosphamide caused dominant-lethal mutations in male mice only in the 1st and 2nd week after treatment. A dose of 120 mg/kg induced dominant-lethal mutations in the mating intervals 1–21 days posttreatment. No dominant lethal mutations were observed after the 3rd week. The same differential spermatogenic response was observed for the induction of specific-locus mutations. Cyclophosphamide induced recessive mutations exclusively in spermatozoa and spermatids. No mutations were recovered from treated spermatocytes and spermatogonia. In contrast to cyclophosphamide, radiation induces specific-locus mutations in all germ-cell stages.The pretreatment with cyclophosphamide 24 h before radiation enhanced the frequency of specific-locus mutations in spermatogonia. The distribution of the observed mutations among the 7 loci and their viability supports the hypothesis that these mutations were induced by radiation rather than by cyclophosphamide. The compound causes an immediate inhibition of DNA and RNA synthesis in spermatogonia. The inhibition very likely interferes with the repair process. The disturbance of the repair process is probably the cause of the synergistic effect for the induction of specific-locus mutations in spermatogonia of mice after pretreatment with cyclophosphamide 24 h before irradiation.     

Differential cell mutability during oogenesis and exposure to ethyleneimine and ethylmethane sulfonate in different Drosophila melanogaster lines

The rate of recessive sex-linked lethal mutations (RLM) was estimated by brood pattern method at different stages of oogenesis, initially, in the wild-type R-86 strain of Drosophila melanogaster after treatment with EI and EMS. The former which is known to induce dominant lethals in mature oocytes of the 14th stage with a high frequency was equally effective in inducing RLM in oocytes of different age and in oogonia. EMS which does not induce dominant lethals when used as vapour was shown to increase RLM frequency in mature fraction of oocytes (the 14A stage only). Similar type of different mutability was found in mutagen-sensitive strain mus-201G1 and in the control 3-4 strain having the same genetical background as mus mutation. Female germ cells of mus-201G1 strain appeared to have a higher mutability in the case of EI, though no differences in mutability between these strains after EMS treatment were registered. The data are discussed in view of the specificity of primer damages occurring as a result of comparable mutagens action and participation of different repair systems in elimination of these damages.     

Elevated Rad53 kinase activity influences formation and interhomolog repair of meiotic DNA double-strand breaks in budding yeast

Meiotic cells generate physiological programmed DNA double-strand breaks (DSBs) to initiate meiotic recombination. Interhomolog repair of the programmed DSBs by meiotic recombination is vital to ensure accurate chromosome segregation at meiosis I to produce normal gametes. In budding yeast, the DNA damage checkpoint kinase Rad53 is activated by DSBs which accidentally occur as DNA lesions in mitosis and meiosis; however, meiotic programmed DSBs which occur at ∼160 loci per genome fail to activate the kinase. Thus, Rad53 activation appears to be silenced in response to meiotic programmed DSBs. In this study, to address the biological significance of Rad53’s insensitivity to meiotic DSBs, we examined the effects of Rad53 overexpression on meiotic processes. The overexpression led to partial activation of Rad53, uncovering that the negative impacts of Rad53 kinase activation on meiotic progression, and formation and interhomolog repair of meiotic programmed DSBs.     

Mutagen-sensitive mutants in Drosophila melanogaster: effects on premutational damage.

Drosophila melanogaster males from a Basc stock were mutagenized with either X-rays, ethyl methanesulfonate (EMS), or nitrogen mustard (HN2). Groups of identically treated males were crossed to different types of female. Sex-linked recessive lethals were scored as a genetic end point. The females used were homozygous for X-chromosomal mutations (mus(1)101D1, mus(1)104D1, mei-9 or mei-41D5) which lead to defective DNA repair and which increase the mutagen sensitivity of larvae. Females from a white stock with normal DNA repair capacities served as controls. The premutational lesions induced in mature sperm are only processed after insemination by the maternal enzyme systems present in the oocytes. Differences in the efficiency of the processing of lesions can lead to maternal effects on the frequency of mutations recovered from mutagenized sperm. It was found that, with the exception of mus(1)104D1, all mutants analysed significantly modify the mutation fixation of one or more types of premutational lesions. The most drastic effect is found with the mus(1)101D1 stock in which HN2-induced DNA cross-links do not lead to sex-linked recessive lethals. It is assumed that mus(1)101D1 is defective in an early step of DNA cross-link repair. Our first set of data clearly demonstrates that the study of maternal effects in Drosophila is an efficient tool to analyse the in vivo function of repair mutations on chemically induced mutagenesis.     

Induction of LacZ mutations in Muta Mouse can distinguish carcinogenic from non-carcinogenic analogues of diaminotoluenes and nitronaphthalenes

2,4-Diaminotoluene (2,4-DAT) is a liver carcinogen in rats and mice whereas 2,6-DAT is not. Both are genotoxic in vitro. Tests for mutations in transgenic mice, unscheduled DNA synthesis (UDS), DNA damage and enhancement of initiated foci in vivo have shown some discrimination between these two analogues, but only after oral administration. 1- and 2-nitronaphthalene (1- and 2-NNT) are also both genotoxic in vitro, although, unlike 2,4- and 2,6-DAT, they do not require metabolic activation. There is some evidence that 2-NNT may be able to induce liver and bladder tumours, and there is some evidence that 1-NNT is not carcinogenic to rats or mice, but none of the data are convincing. When tested for induction of LacZ mutations in Muta Mouse after topical exposure (human occupational exposure route) at their maximum tolerated doses, 2,4-DAT induced a positive response in liver and a marginal response in kidney, whereas 2,6-DAT was negative. 2-NNT also induced a positive mutagenic response in liver, and a marginal response in bladder, whereas 1-NNT was negative. Neither 2,4- nor 2,6-DAT induced mutations at the site of application (skin) as might be expected for chemicals requiring activation by liver enzymes. 2-NNT, which is a direct-acting mutagen in vitro, gave a marginal response for induced mutation at the site of application, but 1-NNT was negative. This study shows that investigation of induction of LacZ mutations after topical application in vivo can provide useful data to help discriminate potentially carcinogenic from non-carcinogenic chemicals that are mutagenic in vitro. Robust carcinogenicity data are needed to determine whether 2-NNT can induce tumours in the liver and bladder.     

A comparison of the genotoxicity of ethylnitrosourea and ethyl methanesulfonate in lacZ transgenic mice (Muta™Mouse)

We compared the induction of gene mutations and chromosomal aberrations by ethylating agents in lacZ transgenic mice (Muta™Mouse). Chromosomal aberrations were detected by the peripheral blood micronucleus assay. Gene mutations were detected in the lacZ transgene. A small amount of blood was sampled from a tail vessel during the expression time for fixation of gene mutations in vivo; this enabled us to detect and compare clastogenicity and gene mutations in the identical mouse. Single intraperitoneal injections of ENU (50–200 mg/kg) and EMS (100–400 mg/kg) strongly induced micronucleated reticulocytes (MN) detectable in peripheral blood 48 h after treatment. The maximum MN frequencies induced were 6.6% and 3.3% for ENU (100 mg/kg) and EMS (400 mg/kg), respectively (the control value was 0.3%). lacZ mutant frequency (MF) was analyzed in bone marrow and liver 7 days after treatment. Spontaneous MFs were 2.0–4.6x10⁻⁶. MF in bone marrow was increased by ENU to 3.4x10⁻⁵ at 200 mg/kg and induced by EMS to 1.8x10⁻⁵ at 400 mg/kg. In liver, however, both chemicals at their highest doses induced only slight increases in MF. The induction of both micronuclei and lacZ mutations in bone marrow by both ENU and EMS correlated better with O⁶-ethylguanine adducts than with N7-ethylguanine adducts. The mutants (19 for ENU and 12 for EMS) were subjected to DNA sequence analysis. Among EMS-induced mutations, 75% were GC to AT transitions, which were probably caused by O⁶-ethylguanine. Among ENU-induced mutations, in contrast, 40% occurred as AT base pair substitutions (6 AT to TA transversions and 2 AT to GC transitions) (no such mutations were induced by EMS). These results, together with the known reactivity of ENU to thymine suggest that thymine adducts play a significant role in the ENU mutagenesis.     

Induction of dominant lethals with ethyl methane-sulfonate in male germ cells of mulberry silkwork, Bombyx mori l.

Sensitivity of male germ cells in the mulberry silkworm, Bombyx mori L., to ethyl methanesulfonate (EMS) was determined by treating newly emerged 5th- instar larvae, and 2-day- and 7-day-old pupae with 3 concentrations, 0.05, 0.1 and 0.15%, of the mutagen. The frequency of dominant-lethal mutations induced by EMS treatment was used as the parameter for the study. Spermatids and spermatozoa were markedly sensitive to EMS. Statistical analysis confirmed that differences in respect of percentage of egg hatch among the 3 different treatments as well as the interactions between the 3 factors, e.g. stages, hatchability and EMS treatment, were highly significant.     

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.     

Nitropyrene-induced DNA repair in Clara cells and alveolar type-II cells isolated from rabbit lung

DNA excision repair, as measured by unscheduled DNA synthesis (UDS), was examined in different cell types of rabbit lung exposed to nitropolycyclic aromatic hydrocarbons (NO-PAH) in vitro. Dose-related increases in UDS were observed. 1,6-Dinitropyrene (1,6-DNP) and 1,8-dinitropyrene (1,8-DNP) induced UDS more effectively in alveolar type-II cells compared with Clara cells. On the other hand, 1-nitropyrene (1-NP) caused a weak UDS response in Clara cells but no DNA repair in alveolar type-II cells.     

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.