Heritable translocation test on random-bred mice after prolonged triethylenemelamine treatment.

Heritable translocation and dominant lethal tests were conducted with random-bred Swiss albino male mice. The animals were provided drinking water containing triethylenemelamine (TEM) for 4 weeks, and were then mated for 3 successive weeks for analysis of dominant lethality and production of F1 progeny. Potential translocation carriers among F1 males were selected after two breedings and confirmed by cytogenetic analysis. Translocation heterozygotes were obtained in offspring of the TEM-treated groups, but not in the control groups. In F1 males produced from the first week of mating, the frequencies of translocations were 0, 1.78 6.2 and 10.0% for the control group and groups receiving TEM at 0.0125, 0.025 and 0.050 mg/kg/day, respectively, and in those produced from the third week of mating, the values were 0 and 2.1%, respectively, for the control group and the group receiving TEM at 0.050 mg/kg/day. F1 males from the second week of mating were not studied for the induction of heritable translocations. TEM-induced dominant lethality and heritable translocations were most prominent in the first week of mating after 4 weeks of treatment. In addition, heritable translocations appeared to be a more sensitive endpoint than dominant lethal mutations for the measurement of mutagenic effects of TEM.     

Effects of Dose on the Induction of Dominant-Lethal Mutations and Heritable Translocations with Ethyl Methanesulfonate in Male Mice

Genetic damage by ethyl methanesulfonate (EMS) in male mice was measured at doses ranging from 50 to 300 mg/kg with dominant-lethal mutations and reciprocal translocations as endpoints. No appreciable increase in dominant-lethal mutations was detected following a dose of 100 mg/kg. Dominant lethals induced by EMS were convincingly detected only after a dose of 150 mg/kg, but in the translocation experiment an increase in the genetic effect was detectable at the 50 mg/kg dose. It is likely that dominant lethals had also been induced at the 50 and 100 mg/kg doses, but were not detected due to the relative insensitivity of the dominant..lethal procedure. Thus, for detection of low levels of EMS-induced chromosome breakage, translocations are a much more reliable endpoint than are dominant-lethal mutations. A procedure for large-scale screening of induced translocations is described.—The dominant-lethal dose-response curve, plotted on the basis of living embryos as a percentage of the control value, is clearly not linear as it is markedly concave downward. Similarly, the translocation dose-response curve showed a more rapid increase in the number of translocations with dose than would be expected on the basis of dose-square kinetics. It is clear for both of these endpoints that the effectiveness of EMS in inducing chromosome breakage is proportionately much lower at low doses.     

Heritable translocation test and dominant-lethal assay in mice with methyl methanesulfonate.

A dominant-lethal test and a heritable translocation test were performed with methyl methanesulphonate (MMS) at 40 mg/kg by treating the sensitive periods of post-meiotic spermatogenesis i.e. spermatozoa and spermatids. In the dominant-lethal test 25 to 60% dominant-lethal mutations were obtained depending on the mating intervals. In the heritable translocation test 11% sterile and partially sterile F1 males were observed in 250 offspring of the MMS group. All of the 14 partially sterile and 6 of the 14 sterile F1 males were demonstrated to be translocation carriers. Fertility of the partial steriles was about 40% of normal fertility. The translocation frequencies in the primary spermatocytes of the partially sterile F1 males varied between 2 and 99%. Transmission of partial sterility and translocations was confirmed in the F2 generation. There were no partially sterile or sterile males among the 245 controls.     

Induction of specific-locus and dominant lethal mutations in male mice in the low dose range by methyl methanesulfonate (MMS)

Methyl methanesulfonate (MMS) induces specific-locus and dominant lethal mutations in spermatozoa and spermatids of mice. A dose of 15 mg/kg b.w. of MMS induces 9% dominant lethal mutations in the most sensitive germ-cell stages, corresponding to the mating intervals 5-8 and 9-12 days post treatment. A dose of 150 mg/kg b.w. of MMS in the same mating intervals induces 100% dominant lethal mutations. The sensitivity pattern for the induction of dominant lethal and specific-locus mutations is the same. In the mating interval 5-8 days a dose of 20 mg/kg b.w. of MMS induced 3.8 x 10(-5) mutations per locus per gamete. The yield of specific-locus and dominant lethal mutations in the low dose range increases proportionally with the dose. A dose given in 2, 4 or 5 fractions yields the same frequency of mutations as a single injection of the total dose. The additivity of small doses proves that the pre-mutational lesions are not or only partially repaired in these stages and that MMS is not or only partially detoxified. In addition, the frequency of dominant lethal and specific-locus mutations depends on the germ-cell stage.     

Heritable translocations induced by dermal exposure of male mice to acrylamide

Acrylamide (AA) is an important industrial chemical used mainly in the production of polymers. It can be absorbed through the skin. AA was shown to be a germ cell clastogen that entails a genetic risk for exposed workers. The genetic risk calculation was based on mouse heritable translocation test data obtained after acute intraperitoneal (ip) exposure (Adler et al., 1994). To obtain a correction factor between ip and dermal exposure, dominant lethal and heritable translocation tests were carried out with dermal exposure of male mice to AA. In the dominant lethal test, male (102/El x C3H/El)F1 mice were exposed by dermal application to the shaved backs of 50 mg/kg AA per day on five consecutive days or to five daily ip injections of 50 mg/kg AA. One day after the end of exposure, the males were mated to untreated females of the same hybrid stock for four days and females were changed every four days for a total of five matings. Dominant lethal effects were found during matings 1-3. For ip exposure, these values were 81.7, 85.7 and 45.4%, respectively; for dermal exposure the corresponding values were 22.1, 30.6 and 16.5%, respectively. In the heritable translocation assay, male C3H/El mice were treated with five dermal exposures of 50 mg/kg AA and mated 1.5-8.5 days after the end of exposure to untreated female 102/El mice. Pregnant females were allowed to come to term and all offspring were raised to maturity. Translocation carriers among the F1 progeny were selected by a sequential fertility testing and cytogenetic analysis including G-band karyotyping and M-FISH. A total of 475 offspring were screened and 41 translocation carriers were identified. The observed translocation frequency after dermal exposure was 8.6% as compared to 21.9% after similar ip exposure (Adler, 1990). The calculated ratio of ip vs. dermal exposure of 0.39 can be applied to obtain a more realistic calculation of genetic risk for dermally exposed workers.     

Delayed Formation of Chromosome Aberrations in Mouse Pachytene Spermatocytes Treated with Triethylenemelamine (Tem)

Induction of chromosome aberrations in pachytene spermatocytes of mice by 2 mg/kg TEM was compared with induction by 400 R X rays. These doses induced comparably high dominant lethal effects in pachytene spermatocytes of mice. Cytological analysis at diakinesis–metaphase I stage showed that whereas 76.4% of the cells treated with X rays at pachytene stage had aberrations, the frequencies observed in two TEM experiments were only 0.8 and 2.2%. On the other hand, 5% of the progeny from TEM-treated pachytene spermatocytes were found to be translocation heterozygotes. This is the first report on the recovery of heritable translocations from treated spermatocytes of mice. The aberration frequencies observed for TEM in diakinesis–metaphase I were much too low to account for all the lethal mutations and heritable translocations. Thus, the formation of the bulk of aberrations induced by TEM in pachytene spermatocytes was delayed—a marked contrast to the more immediate formation of X-ray-induced aberrations. It is postulated that the formation of the bulk of TEM-induced aberrations in pachytene spermatocytes and in certain postmeiotic stages occurs sometime during spermiogenesis, and not through the operation of postfertilization pronuclear DNA synthesis.     

The use of alkaline elution procedures to measure DNA damage in spermiogenic stages of mice exposed to methyl methanesulfonate

The ability of methyl methanesulfonate (MMS) to induce DNA breakage in spermiogenic stages of the mouse was studied using an alkaline elution technique. At daily intervals over a 3-week period following i.p. injection of 50 mg MMS/kg, mature spermatozoa were recovered from treated (3H-labeled) and control (14C-labeled) animals, lysed together on polycarbonate filters, and eluted with a high pH (12.2) buffer. Elution of germ-cell DNA from MMS-treated animals was found to increase in stages in which genetic damage from MMS is greatest. In general, the pattern of DNA elution from treated, spermiogenic stages paralleled the pattern of sensitivity to dominant lethals, specific-locus mutations and heritable translocations found by other investigators. It also paralleled the pattern of sperm-head methylation and protamine methylation measured in an earlier study (Sega and Owens, 1983). At 9 days post treatment (sperm sampled were in mid-to late-spermatid stages at the time of MMS exposure) the elution of sperm DNA did not change significantly over a pH range of 11.6-12.8, suggesting that, at the time of assay, DNA breaks were already present in the sperm. Because of the parallelism found between increased sperm DNA elution and increased genetic damage after mutagen treatment, alkaline elution may prove useful in monitoring potential genetic damage in human sperm.     

Mutagenic effect of chemical compounds on laboratory mice]

Mutagenic effect of thioTEPA applied at a dose of 1.25 mg/kg was studied in late spermatids of C57BL/L male mice. The mutagen induced dominant lethal mutations in germ cells (39%) and symmetric translocations in 33.5% of F1 male offspring. The common frequency of sperms with chromosome mutations was 60%, that is ten times as much as the mutagenic effect in bone marrow cells. 39% of embryos at 3.5 days of development died or delayed their development at 2--22 blastomers stages. Structure chromosome aberrations were found in the cells of such embryos. The scheme of genetical screening of chemical compounds in laboratory mice, based on the data obtained early and in the present experiment, is proposed.     

Relative Rates at Which Dominant-Lethal Mutations and Heritable Translocations Are Induced by Alkylating Chemicals in Postmeiotic Male Germ Cells of Mice

There is a close relationship between the rates at which dominant lethal mutations and heritable translocations are induced by ethyl methanesulfonate (EMS) or triethylenemelamine (TEM) in male postmeiotic germ cells. This relationship does not hold for isopropyl methanesulfonate (IMS), which induced only negligible frequencies of heritable translocations at doses that induced high levels of dominant lethal mutations. Nor does IMS behave like EMS and TEM in the degree to which eggs of different stocks of females repair premutational lesions that are carried in the sperm-large differences between stocks for IMS treatment and small differences for EMS or TEM treatment. These dissimilarities between IMS and the other two alkylating chemicals are postulated to be attributable to differences in the types of lesions present at the time of repair activity and to whether or not chromosomal aberrations are already fixed prior to postfertilization pronuclear DNA synthesis.     

Studies on chemically induced dominant lethality. I. The cytogenetic basis of MMS-induced dominant lethality in post-meiotic male germ cells.

Young adult male mice were injected intravenously with doses of methyl methanesulfonate(MMS) ranging from 25 to 100 mg/kg body weight. These males were serially mated to superovulated females from day 1 post injection to day 23 post injection. The morning after mating (about 4-6 h post-copulation) the females were sacrificed and ova flushed from the ampulla. The ova were cultured, in the presence of colchicine, for 26 h and metaphase preparations made of the first cleavage division. Chromosome analysis was done and the types, and extent, of chromosome aberrations correlated to previously published dominant lethal data at the same MMS doses and time intervals. The types of aberrations seen were predominantly double fragments (presumably isochromatid deletions), chromatid interchanges, and some chromatid deletions, as well as shattering effect on the male complement at the highest dose and the time of peak sensitivity to dominant lethal induction. When the frequency of cells containing a cytologically visible aberration is compared to the total dominant lethal data an excellent correlation is obtained. Furthermore, the frequency of highly damaged cells, agrees very well with estimated frequencies of preimplantation loss. These data strongly suggest that chromosome aberrations seen at the first cleavage stage are the basis of MMS-induced dominant lethality.     

Transmission of X-ray-induced reciprocal translocations in normal male mice and in male mice with a reduced sperm count due to translocation homozygosity

Normal (+/+) and translocation T(1; 11.13S)70H homozygous (T/T) male mice received 2 X 2.5 Gy X-rays with a 24-h interval. After 120 days, the frequency of late diplotene-metaphase I spermatocytes with translocation multivalents was 14.1% for +/+ and 13.7% for T/T males, respectively, in one group of animals of each type. The difference is not significant. A second group was allowed to sire progeny for 60 days with 2 normal females per week. Reciprocal translocations detectable at diakinesis/metaphase I were observed in 2.5% of the 395 male progeny from the irradiated +/+ fathers, and in 2.9% of the 489 male progeny from the irradiated T/T fathers. This leads to a pooled estimated transmission of 0.81 +/- 0.19. Translocations induced in the long 11.13 metacentric chromosome were not transmitted with a different frequency. The rate of heritable induced translocations in this study was 5.4 X 10(-5)/rad/gamete. On the basis of the data of Generoso et al. (1984) for the frequency of the heritable spontaneous translocations in male mice, it is concluded that, because of their low doubling dose (3.3-4.6 rad), the spontaneous translocations are probably of postmeiotic origin.     

Isolation of Chinese hamster cells hyposensitive to ethyl methanesulfonate and their characterization in induction and antagonization of sister-chromatid exchanges

Dominant lethal tests were performed on female mice injected intraperitoneally with cyclophosphamide (200 mg/kg) or with mitomycin C (0.2 or 5 mg/kg) at the preovulatory stage of oogenesis. Complementary experiments were undertaken to clarify the results obtained. Embryo culture showed that sterility found after treatment with cyclophosphamide or with the high dose of mitomycin C was the reflection of true dominant lethal effects. Mortality after cyclophosphamide treatment occurred predominantly at the 2- and 3-cell stages, while it was reported in all preimplantation stages after treatment with the high dose of mitomycin C. Embryos treated with the low dose of mitomycin C developed normally to the blastocyst stage, confirming the absence of preimplantation effects found with this dose in the dominant lethal test. Cytogenetic analysis of female pronuclei at the first cleavage division were performed after mating treated females with males homozygous for one Robertsonian translocation. This method allowed one to distinguish easily the female pronuclei from the male ones, which exhibited one translocated 'marker' chromosome. After treatment with cyclophosphamide, most female pronuclei showed multiple chromatid exchanges or shattering of the entire genome. After treatment with the high dose of mitomycin C, various types of premature chromosome condensation were found, and they were often accompanied by important interchromosome associations. After treatment with the low dose of mitomycin C, no structural chromosome aberrations were found, and the number of numerical anomalies was not significantly different from that found in control embryos. These last results suggest that the increase in rate of postimplantation loss obtained in the dominant lethal test with the low dose of mitomycin C was not due to clastogenic effects of this compound in the female germ cells, but rather to indirect effects on the maternal organism.     

The effect of cystamine on the outcome of dominant lethal mutations and reciprocal translocations in sex cells of mice subjected to gamma-irradiation in different doses]

Protective effect of cystamine (150 mg/kg) against genetic damages induced by gamma-irradiation in germ cells of male mice of CBA strain (at doses of 100, 300, 600 r) was studied. The application of cystamine decreased the frequency of dominant lethal mutations induced by radiation in sperms, spermatids and spermatocytes. The degree of the protective effect of cystamine depended on a radiation dose. The protective effect of cystamine was the highest at the radiation dose of 300 r. It was negligible at the radiation dose of 100 r and was completely absent at the dose of 600 r. Cystamine did not affect the rate of induced reciprocal translocations in the spermatogonia at all the radiation doses used.     

Mutagenic action of cadmium on the sex cells of male mice

Possible mutagenic effect of cadmium chloride was studied by determining the frequency of dominant lethal mutations induced in germ cells of male mice. Water solution of CdCl2 was injected intraperitoneally to male mice at doses of 1.0, 2.0 and 4.0 mg/kg. The results obtained did not reveal any mutagenic effect of this compound. The dose of 4.0 mg/kg CdCl2 resulted in the death of spermatocytes and spermatogonia and the sterility of male mice. Cadmium chloride at a dose of 2.0 mg/kg did not affect the frequency of dominant lethal mutation induced by gamma-rays 60Co at a dose of 450 r in germ cells of male mice.     

Cytogenetic and dominant lethal studies on captan.

Possible mutagenic activity of captan was investigated by in vitro and in vivo cytogenetic studies and by the dominant lethal study in mice. In vitro cytogenetic study with cultured human diploid cells revealed a significant increase in the frequency of cells showing stickiness and a severe mitotic inhibition at concentrations of 3.0 and 4.0 microgram of captan per ml. although no chromosomal aberrations were observed. In in vivo cytogenetic study, no chromosomal aberrations were induced in the bone marrow cells of rats treated orally with captan at a single dose of 500, 1000 or 2000 mg/kg or at five consecutive doses of 200, 400 or 800 mg/kg/day. Dominant lethal study also failed to show any mutation induction after treatment of male mice with daily oral dose of 200 or 600 mg of captan per kg bw for five days.     

Induction of specific-locus and dominant lethal mutations in male mice by busulfan

The chemotherapeutic agent busulfan was tested for the induction of dominant lethal and specific-locus mutations in male mice. A dose of 5 mg/kg b.w. of busulfan induces dominant lethal mutations in spermatozoa. A dose of 20 mg/kg b.w. induces dominant lethal mutations in spermatozoa and spermatids. A total of 83,196 offspring were scored in the specific-locus experiments. Busulfan-induced specific-locus mutations were recovered in spermatozoa and spermatids, but not in spermatogonia. The sensitivity patterns for the induction of dominant lethal and specific-locus mutations by busulfan in germ cells of male mice are similar but not identical.     

Cytogenetic effects of X-rays and fission neutrons in female mice

The induction by X-rays of chromosomal damage in oocytes was studied, while the genetic consequences of X- and neutron-induced damage in female mice were looked for by testing offspring for dominant lethality and semi-sterility. None out of 386 sons of hybrid females given 300 rad X-rays showed evidence of semi-sterility or translocation heterozygosity, but 9 out of 294 daughters were diagnosed as semi-sterile. At least 3 and probably 4 of these (1.4%) carried reciprocal translocations, 2 of which caused male sterility. Complete or partial loss of the X-chromosome may have been responsible for some of the other sermi-steriles. Examination of oocytes at metaphase-I during the first and third weeks after X-irradiation with 100 or 400 rad revealed both multivalents (some of the ring quadrivalent type) and fragments (mainly double). These were thought to arise mainly from chromatid intercchanges (both symmetrical and asymmetrical) and isochromatid intrachanges respectively. Since neither the proportion of asymmetrical interchanges nor the amount of hidden damage was known it was not thought possible to predict the magnitude of F₁ effects from metaphase-I findings. The aberration frequency in oocytes rose with dose and (at the 400 rad level only) with time after irradiation, reaching a maximum of 10% multivalents and 22% fragments in the third week after 400 rad. The frequency of univalents showed no consistent trend, but chiasma counts decreased in the first week after 400 rad. The increase in levels of chromosomal damage with dose and time after irradiation was reflected in dominant lethal frequencies after the same radiation-conception intervals and doses of 0–400 rad. Induced post-implantation lethality was over twice as high in the third week after 200–400 rad than in the first. Pre-implantation loss also greatly increased in the third week after 300 or 400 rad; this was associated with increased non-fertilization of ova. No evidence for the induction of translocations in oogonia or resting oocytes by fast neutron irradiation was obtained, although there was evidence for X-chromosomal loss after 200 rad to oocytes. The relative biological effectiveness (RBE) for fission neutrons vs. X-rays with respect to dominant lethal induction in oocytes was found to vary with dose, but seamed to be around 1 at lower levels.     

Effect of safranal, a constituent of Crocus sativus (saffron), on methyl methanesulfonate (MMS)-induced DNA damage in mouse organs: an alkaline single-cell gel electrophoresis (comet) assay

The influence of safranal, a constituent of Crocus sativus L. stigmas, on methyl methanesulfonate (MMS)-induced DNA damage was examined using alkaline single-cell gel electrophoresis (SCGE), or comet, assay in multiple organs of mice (liver, lung, kidney, and spleen). NMRI mice were divided into five groups, each of which contained five mice. The animals in different groups were received the following chemicals: physiological saline (10 mL/kg, ip), safranal (363.75 mg/kg, ip), MMS (120 mg/kg, ip), safranal (72.75 mg/kg, ip) 45 min prior to MMS administration, and safranal (363.75 mg/kg, ip) 45 min prior to MMS administration. Mice were sacrificed about 3 h after the administration of direct mutagen MMS, safranal, or saline, and the alkaline comet assay was used to evaluate the influence of safranal on DNA damage in different mouse organs. Increase in DNA migration was varied between 9.08 times (for spleen) and 22.12 times (for liver) in nuclei of different organs of MMS-treated mice, as compared with those of saline-treated animals (p < 0.001). In control groups, no significant difference was found in the DNA migration between safranal- and saline-pretreated mice. The MMS-induced DNA migration in safranal-pretreated mice (363.75 mg/kg) was reduced between 4.54-fold (kidney) and 7.31-fold (liver) as compared with those of MMS-treated animals alone (p < 0.001). This suppression of DNA damage by safranal was found to be depended on the dose, and pretreatment with safranal (72.75 mg/kg) only reduced DNA damage by 25.29%, 21.58%, 31.32%, and 25.88% in liver, lung, kidney, and spleen, respectively (p < 0.001 as compared with saline-treated group). The results of the present study showed that safranal clearly repressed the genotoxic potency of MMS, as measured by the comet assay, in different mouse organs, but the mechanism of this protection needs to be more investigated using different in vitro system assays and different experimental designs.     

In vivo genotoxicity of nitrates and nitrites in germ cells of male mice. I. Evidence for gonadal exposure and lack of heritable effects

Effects of nitrate (doses of 600 and 1200 mg/kg/day during 14 days) and sodium nitrite (60 and 120 mg/kg/day during 14 days) on germ cells of male mice were investigated. The mode of application was stomach intubation. The germ cell stages analysed were spermatids (for the heritable effects) and differentiating and stem-cell spermatogonia (for direct effects).A lack of heritable translocations, sperm abnormalities, as well as morphological changes, such as changes in eyes, coat colour, testes and body weight, was demonstrated in F₁ males originating from treated P males. Significant effects in treated males were found with respect to: (1) sex-chromosomal univalency in the diakinesis-methaphase I stage after the treatment of stem spermatogonia (both doses of sodium nitrate and the higher dose of sodium nitrite), (2) sperm-head abnormalities after treatment of differentiating spermatogonia (the higher dose of sodium nitrate and both doses of sodium nitrite), and (3) fertility after treatment of spermatids (the higher dose of sodium nitrite). Nonmutagenic effects and possible carcinogenic potential of the tested doses are discussed.     

Increment kinetics of recessive lethal mutations and dominant lethals in offspring of Drosophila melanogaster on storage of methyl-methanesulfonate-treated sperm in females

The frequencies of sex-linked recessive lethal mutations in F1 males after feeding adult male Drosophila melanogaster with 0.25 and 0.5 mM methyl methanesulfonate (MMS) orally for 24 h increased approximately linearly with storage of the treated spermatozoa in females, whereas the number of hits of dominant lethals in the sperm after feeding 0.3 and 0.5 mM MMS increased approximately with the square of the storage time. Chromosome losses and mosaics in F1 males also increased with the dose of MMS to males, but their yields were too low to be analyzed quantitatively, only indicating a slight increase of chromosome loses and a slight decrease of mosaics with the time of storage of sperm. Maternal non-disjunctions (or chromosome losses), detected in F1 males, decreased with the dose of MMS to spermatozoa and their yield decreased with the time of storage of sperm of both MMS-treated and the control groups. A unitary model is proposed to explain the effect of storage on the dominant lethals and recessive lethal mutations.