Melphalan, a second chemical for which specific-locus mutation induction in the mouse is maximum in early spermatids.

Melphalan (MLP), a bifunctional alkylating agent structurally related to the highly mutagenic chemical chlorambucil (CHL), was found to induce high frequencies of specific-locus mutations in postspermatogonial germ cells of the mouse, and to be one of only a few chemicals that is also mutagenic in spermatogonial stem cells. Productivity patterns following MLP exposures resembled those that had been found for CHL. Mutation rates in successive male germ-cell stages were measured at three MLP-exposure levels in a total of 95,375 offspring. While the induced (experimental minus historical-control) mutation rate is relatively low in stem-cell spermatogonia (1.2 x 10(-5) per locus at a weighted-mean exposure of 7.3 mg/kg), it is about 5 times higher in poststem-cell stages overall, and peaks at 26.7 x 10(-5) per locus in early spermatids at a weighted-mean exposure of only 5.7 mg/kg. This "type-2 pattern" of mutation yield (Russell et al., 1990), i.e., peak sensitivity in early spermatids, has heretofore been found for only one other chemical, CHL. Mutation-rate data earlier reported for CHL (Russell et al., 1989) were augmented in the present study for comparison with MLP-induced rates. Because of the greater toxicity of MLP, average exposures used for this chemical were only about one-half of those for CHL. When MLP and CHL mutation rates are extrapolated to equimolar doses, they appear very similar for poststem-cell stages overall. However, in the case of CHL, a somewhat higher proportion of the mutations is induced in early spermatids than in the case of MLP.     

Study of the base analog 6-mercaptopurine in the mouse specific-locus test

The base analog 6-mercaptopurine (6MP) was studied in the mouse specific-locus test in various male germ-cell stages. The overall finding of 3 mutations in 65,376 offspring rules out (at the 5% significance level) an induced mutation rate greater than 1.22 times the historical control rate. For spermatogonial stem cells alone, the multiple ruled out is 3.7; and for postspermatogonial stages, it is 0.7. For late differentiating spermatogonia and preleptotene spermatocytes, stages that had earlier been found sensitive to dominant-lethal induction (a result confirmed in the present experiment), the results (0 mutations in 5214 offspring) do not rule out a positive effect; they indicate only that the induced rate is unlikely to be greater than 9.8 times the historical control rate. There is evidence that 6MP (or an active metabolite) reaches all germ-cell stages of concern. Because spermatogonial stem cells are not killed, the negative mutation mutation-rate results cannot be attributed to cell selection.     

The paternal genome in mouse zygotes is less sensitive to ENU mutagenesis than the maternal genome

The two parental genomes lie separate within the zygote and may be differentially affected by environmental influences. We have shown earlier (Russell et al., 1988) that the maternal genome within the mouse zygote is exquisitely sensitive to the induction of point mutations by N-ethyl-N-nitrosourea (ENU), and that the initial lesion probably occurs in one strand of the DNA. The present experiment measured specific-locus mutation induction in the paternal genome. Zygotes containing a multiple-recessive maternal genome (a; b; p cch; d se; s) and the corresponding wild-type alleles in the paternal one were exposed to 50 mg ENU/kg in vivo at one of two stages: the presumed times of sperm entry and early pronuclear stage. At weaning age, the resulting mice were examined for mutations at the marked loci as well as for other mutations producing externally visible phenotypes. At the marked loci, one possible mosaic (for b) was observed among 2113 classified offspring that had been treated with ENU as zygotes; this animal failed to transmit a mutation. By contrast, in the reciprocal cross (which tests the maternal genome) we had observed 8 specific-locus mutations (6 of them mosaics) among 1555 offspring that had received the same dose of ENU during sperm entry (and completion of oocyte meiosis II). In the present experiment, we also found one mutation at other loci (two at other loci in the reciprocal cross). The frequency of offspring with small white belly spots was significantly greater in the treated groups (3.5 and 1.9% at the earlier and later stage, respectively) than in the control (1.0%), the excess being almost entirely due to daughters. Genetic tests of a large number of such offspring failed to find a genetic cause. Instead, it appears that this phenotype may be influenced by factors in the intrauterine environment. It is concluded that shortly after sperm entry, the paternal genome of the zygote is less sensitive than the maternal one to the induction of mutations by ENU.     

Chemical dosimetry of ethyl nitrosourea in the mouse testis

[3H-Et]Nitrosourea was administered to male (101 X C3H) mice by i.p. injection at exposure levels of 10 mg/kg or 100 mg/kg. At intervals from 1 h to 6 days following treatment, the ratio of O6-ethylguanine to N7-ethylguanine in testis DNA averaged 1.13 following the 100 mg/kg exposure and 0.72 following the 10 mg/kg exposure. The amount of O6-ethylguanine recovered after the 100 mg/kg exposure was 40% greater than predicted from a linear extrapolation of the amount of O6-ethylguanine recovered after the 10 mg/kg exposure. We suggest that the high (100 mg/kg) exposure to ethyl nitrosourea results in depletion of the O6-alkylguanine acceptor protein within the testis and permits O6-ethylguanine to persist at higher levels than would be predicted from lower exposure data. W.L. Russell et al. (1982), W.L. Russell (1984) have found that specific-locus mutation frequencies induced in mouse spermatogonial stem cells are 5.8-fold greater after a single 100 mg/kg exposure to ethyl nitrosourea than after 10 weekly exposures to 10 mg/kg. The finding that the corresponding ratio for O6-ethylguanine formed in the testis is only 1.4 may be interpreted in a number of possible ways. If O6-ethylguanine is an important lesion for producing specific-locus mutations, then its formation in the stem cells must be at least 4-fold greater than that for the whole testis as the ENU exposure goes from 10 to 100 mg/kg: alternatively, the rate of repair of this lesion by the stem cells must decrease at least 4-fold relative to the average testicular cell. Other explanations for the difference in mutation response of the stem cells to acute vs. chronic ethyl nitrosourea-exposures include the possibility that other DNA lesions may be responsible for many of the mutations or that two hits on the DNA may be required to produce an effect.     

Dominant cataract and recessive specific-locus mutations detected in offspring of procarbazine-treated male mice

The induction of dominant cataract mutations by procarbazine was studied concomitantly with the induction of specific-locus mutations in treated male mice. The most effective dose in the specific-locus test, 600 mg/kg of procarbazine, and a fractionated dose of 5 X 200 mg/kg were used. The frequencies of dominant cataract mutations were higher, but not significantly different from the historical control. The ratio between the number of recovered specific-locus and dominant cataract mutations was in accordance with that found in our experiments with gamma-rays (Ehling et al., 1982; Kratochvilova, 1981) or in experiments with ethylnitrosourea (Favor, 1986). A total of 3 dominant cataract mutations were recovered in the offspring of procarbazine-treated spermatogonial stem cells. Two mutations had complete penetrance while the third exhibited a reduced penetrance of approximately 70%. The viability and fertility of the heterozygotes of all 3 mutations were not affected. Only 1 mutation was shown to be viable as a homozygote.     

The frequency of dominant cataract and recessive specific-locus mutations and mutation mosaics in F1 mice derived from post-spermatogonial treatment with ethylnitrosourea

The frequency of dominant cataract and recessive specific-locus mutations and mutation mosaics was determined in F1 mice derived from post-spermatogonial germ-cell stage treatment with 2 X 80, 160 or 250 mg/kg ethylnitrosourea. A total of 5 dominant cataract mutations, 3 dominant cataract mutation mosaics, 1 specific-locus mutation and 9 specific-locus mutation mosaics were recovered in 15,542 screened F1 offspring. Results indicate that ethylnitrosourea treatment increases the mutation rate of dominant cataract and recessive specific-locus alleles in post-spermatogonial germ-cell stages of the mouse and that the mutations occur mainly as mosaics. Genetic confirmation of newly induced mutations occurring as mosaics is more problematical for induced recessive alleles than for induced dominant alleles and should be considered when evaluating such mutagenicity results.     

Tests for urethane induction of germ-cell mutations and germ-cell killing in the mouse

Urethane, a chemical that has given varied results in mutagenesis assays, was tested in the mouse specific-locus test, and its effect on germ-cell survival was explored. Altogether 32,828 offspring were observed from successive weekly matings of males exposed to the maximum tolerated i.p. dose of 1750 mg urethane/kg. The combined data rule out (at the 5% significance level) an induced mutation rate greater than 1.7 times the historical control rate. For spermatogonial stem cells alone, the multiple ruled out is 3.2, and for poststem-cell stages, 3.5. Litter sizes from successive conceptions made in any of the first 7 weeks give no indication of induced dominant lethality, confirming results of past dominant-lethal assays. That urethane (or an active metabolite) reaches germ cells is indicated by SCE induction in spermatogonia demonstrated by other investigators. Cytotoxic effects in spermatogonia are suggested by our finding of a slight reduction in numbers of certain types of spermatogonia in seminiferous tubule cross-sections and of a borderline decrease in the number of litters conceived during the 8th and 9th posttreatment weeks. The negative results for induction of gene mutations as well as clastogenic damage are at variance with Nomura's reports of dominant effects (F1 cancers and malformations) produced by urethane.     

X-ray-induced specific-locus mutation rate in newborn male mice

The specific-locus mutation frequency resulting from 300 R of acute X-irradiation has been determined for the germ cells present in newborn male mice. The frequency is 13.7·10^?8 mutations/locus/R, which is statistically significantly lower than that of 29.1·10^?8 mutations/locus/R found earlier for the same loci in spermatogonia of the adult male by W. L. Russell. The mutation rate for newborn males does not differ significantly from the induced specific-locus frequency reported for fetal males by T. C. Carteret al.The incidence of clusters of specific-locus mutations found following the irradiation of the newborn males was statistically significantly higher than the cluster incidence reported by W. L. Russell for similar irradiation of adult males. This presumably indicates the survival of relatively fewer reproductive cells following irradiation of the day-o testis.Although there are suggestions that the distribution of mutations among the loci following irradiation of the newborn males may be different from that of the irradiated adults, no statistically significant differences are demonstrated.It is quite possible that the testis of the newborn mouse may be comparable to the relatively undifferentiated human testis which persists for approx. 10 years. Until the present research was undertaken, no attempt had been made to determine the specific-locus mutation frequency resulting from X-irradiation of newborn male mice. Although some important questions still remain concerning the explanation for the lower mutational response of the newborn mouse testis, from the hazard standpoint it is reassuring that the mutation frequency of the newborn male is statistically significantly lower than that of the adult.     

Specific-locus mutation rates in the mouse following inhalation of ethylene oxide, and application of the results to estimation of human genetic risk

Male (101 × C3H)F₁ mice were exposed in an inhalation chamber to ethylene oxide (EtO) in air at a concentration of (generally) 255 ppm. After accumulating total exposures of 101 000 or 150 000 ppm.h in 16–23 weeks, the males were mated to T-stock females for a standard specific-locus mutation-rate study in which 71 387 offspring were observed. The spermatogonial stem-cell mutation rate at each exposure level, as well as the combined result, does not differ significantly from the historical control frequency. At the lower and higher exposure levels, the results rule out (at the 5% significance level) an induced frequency that is, respectively, 0.97 and 6.33 times the spontaneous rate; the combined results rule out a multiple of 1.64.

The relationship between mouse spermatogonial stem-cell mutation rates and EtO-induced testis ethylations was compared with the relationship between Drosophila post-stem-cell mutation rates and sperm ethylations (Lee, 1980). The comparison does not rule out equal mutability per ethylation; but it cannot prove parallelism. An assessment of the mouse-Drosophila relationship will require a more efficient alkylator than EtO and the use of comparable germ-cell stages.

More meaningful conclusions may be drawn by utilizing the data for direct estimation of human risk by expressing the induced mutation frequency that is ruled out (at the 5% significance level) as a multiple of control rate and extrapolating to human exposure levels. The probable absence of major stem-cell killing (and thus, possibly, cell selection) by EtO indicates that such extrapolation probably does not produce an underestimate. For a human exposure concentration of 0.1 ppm on working days during the reproductive lifespan, the mouse experimental results rule out (at the 5% significance level) an induced spermatogonial stem-cell gene mutation rate greater than 8% of the spontaneous rate; for 1.0 ppm, they rule out an induced rate roughly equal to the spontaneous rate. The induced rate for any one poststem-cell stage would have to be about 3 orders of magnitude higher than that for stem cells to constitute an equivalent risk.     

Dose-rate effect on transgenerational mutation frequencies in spermatogonial stem cells of the medaka fish

The estimation of transgenerational genetic risk of radiation exposure to non-human species is crucial for the protection of ecosystems. Here we determined the frequency of specific-locus mutations at the five pigmentation loci in medaka spermatogonial stem cells after gamma irradiation at 0.03 cGy/min and 95 cGy/min. At each total dose, the mutation frequency was significantly lower in the 0.03-cGy/min group than in the 95-cGy/min group, suggesting a dose-rate effect. The ratio of the induced mutation frequency at 0.03 cGy/min to that at 95 cGy/min was approximately 0.42 from 0 to 1.9 Gy and approximately 0.33 from 1.9 to 4.75 cGy. In the mouse, this ratio is estimated to be 0.33 (Russell and Kelly, Proc. Natl. Acad. Sci. USA 79, 542-544, 1982). It is thus possible that the magnitude of the dose-rate effect on transgenerational mutation frequencies is comparable between mouse and medaka spermatogonia, suggesting similar dose-rate effects among vertebrates.     

The frequency of dominant cataract and recessive specific-locus mutations in mice derived from 80 or 160 mg ethylnitrosourea per kg body weight treated spermatogonia

A systematic comparison of the frequency of dominant cataract and recessive specific-locus mutations in mice has been extended to include results for 80 and 160 mg ethylnitrosourea per kg body weight spermatogonial treatment. The frequency of confirmed dominant cataract mutations in the historical control, 80 and 160 mg/kg ethylnitrosourea treatment groups was 1/22594, 8/5090 and 14/6435, respectively. The frequency of recessive specific-locus mutations in the same dose groups was, respectively, 19/227805, 20/13274 and 35/8658. These present results confirm previous results, which indicate that ethylnitrosourea is effective in inducing both recessive specific-locus and dominant cataract mutations although the per locus mutation rate to recessive alleles was observed to be approximately 6 times greater than the per locus mutation rate to dominant alleles. The exclusion of certain classes of lens opacity variant phenotypes, previously demonstrated not to be due to a dominant mutation, from the group of suspected dominant cataract mutations subjected to a genetic confirmation test has greatly improved the efficiency of the test. A total of 23 dominant cataract mutations were confirmed from a group of 67 phenotypic variants. Of the 23 confirmed dominant cataract mutations, 8 were shown to have reduced transmission to the following generation of offspring expressing the mutant phenotype. These results are also consistent with previous results for ethylnitrosourea or radiation treatment in which it was shown that approximately one-third of the recovered mutations have reduced penetrance. One group of dominant cataract mutations, with phenotypic effects on the polar, sub-capsular or corneal regions, is overly represented in the group of recovered mutations with a reduced transmission of offspring expressing the mutant phenotype. Two hypotheses are suggested for this observation, both dependent on the fact that the regions affected indicate that the mutations are expressed later in the development of the eye. Either all carrier individuals have not expressed the phenotype at the time of examination and classification, or later acting mutations are more subject to environmental interactions resulting in more variable expression. Finally, it is argued that a dominant cataract mutation test represents a most practicable protocol to screen for induced dominant mutations in germ cells of the mouse. The imposition of the criterion that suspected variants be subjected to a genetic confirmation test has at least two advantages beside the fact that results represent unambiguous mutational events.(ABSTRACT TRUNCATED AT 400 WORDS)     

Unlike other chemicals, etoposide (a topoisomerase-II inhibitor) produces peak mutagenicity in primary spermatocytes of the mouse

The cancer chemotherapy agent, and topoisomerase-II inhibitor, etoposide (VP-16) produced both recessive mutations at specific loci and dominants at other loci with peak frequencies in primary spermatocytes, a cell type in which the topo-II gene has been shown to be activated. Etoposide thus differs from all other chemicals whose germ-cell-stage specificity has been analyzed. No effects of etoposide exposure of spermatogonial stem cells ( 15,000 offspring scored) were detectable by either mutagenicity or productivity endpoints. The significant mutagenic response that followed exposure of poststem-cell stages ( 25,000 offspring scored) showed a clear peak, with three of four specific-locus mutants, and three of four dominant mutants conceived during weeks 4 or 5 (days 22–35) post-injection, a period that also encompassed the dominant-lethal peak. For this period, the induced specific-locus rate (with 95% confidence limits) at a weighted-average exposure of 75.1 mg etop/kg was 59.5 (14.6, 170.9) × 10⁻⁶/locus. At least 3 of the 4 specific-locus mutations were deletions, paralleling findings with etoposide or analogs in other test systems where a recombinational origin of the deletions has been suggested. Because, unlike other chemicals that induce deletions in male germ cells, etoposide is effective in stages normally associated with recombinational events, it will be of interest to determine whether this chemical can affect meiotic recombination.     

A comparison of the dominant cataract and recessive specific-locus mutation rates induced by treatment of male mice with ethylnitrosourea

Mice were derived from parental males treated with 250 mg ethylnitrosourea per kg body weight. The mice were screened simultaneously for induced dominant cataract and recessive specific-locus mutations. In the spermatogonial treatment group, 16 dominant cataract, 1 dominant corneal opacity and 60 recessive specific-locus mutations were recovered and genetically confirmed in 9352 offspring observed. This lower yield of dominant cataract mutations, when compared with the yield of recessive specific-locus mutations, is similar to results observed by Kratochvilova in a series of experiments on dominant cataract mutations induced by radiation treatment. These results taken with reported results from other dominant mutation test systems, suggest a lower per-locus mutation rate to dominant than to recessive alleles. A corollary to the hypothesis that most dominantly expressed alleles code for an alteration in the function of the normal gene product is that a limited subset of mutations could normally lead to a dominantly expressed mutation. This may explain the lower per-locus mutation rate to dominant than to recessive alleles.

Genetic confirmation tests of recovered presumed dominant cataract mutations indicate that a certain category of phenotypic variants (bilateral, severe or unique lens opacity) is likely to be a true mutation but only represents 7 of the 19 mutations recovered. A second category of phenotypic variants (unilateral, neither severe nor unique lens opacity) has an extremely low probability of being a true mutation. Only 1 confirmed mutation in 181 phenotypic variants was obtained. The remaining category of phenotypic variants (either unilateral severe or unique, or bilateral neither severe nor unique lens opacity) represented the majority, 11, of the confirmed mutations obtained. However, 266 presumed mutations in this category were recovered. If a sub-class of phenotypic variants within this category could be identified that could be ignored owing to a very low probability of being a true mutation, the efficiency of recovery of confirmed dominant cataract mutations would be greatly increased with no sacrifice in the accuracy of the observed mutation rate.

Finally, the 17 confirmed dominant cataract mutations obtained included a class of 7 that produced significantly fewer than the Mendelian expectation of offspring exhibiting the mutant phenotype. This class probably represents both mutations with penetrance effects and mutations with viability effects.

The present experiments represent the first systematic comparison of induced genetically confirmed dominant and recessive mutations for a chemical mutagen in mice. Such results contribute to our limited understanding of the mutation process to dominant alleles.     

Dominant cataract and recessive specific locus mutations in offspring of X-irradiated male mice

Male mice were X-irradiated with 3.0 + 3.0 Gy or 5.1 + 5.1 Gy (fractionation interval 24 h). The offspring were screened for dominant cataract and recessive specific locus mutations. In the 3.0 + 3.0-Gy spermatogonial treatment group, 3 dominant cataract mutations were confirmed in 15 551 offspring examined and 29 specific locus mutations were recovered in 18 139 offspring. In the post-spermatogonial treatment group, 1 dominant cataract mutation was obtained in 1120 offspring and 1 recessive specific locus mutation was recovered in 1127 offspring. The induced mutation rate per locus, per gamete, per Gy calculated for recessive specific locus mutations is 2.0 X 10(-5) in post-spermatogonial stages and 3.7 X 10(-5) in spermatogonia. For dominant cataract mutations, assuming 30 loci, the induced mutation rate is 5.0 X 10(-6) in the post-spermatogonial stages and 1.1 X 10(-6) in spermatogonia. In the 5.1 + 5.1-Gy spermatogonial treatment group, 3 dominant cataract mutations were obtained in 11 205 offspring, whereas in 13 201 offspring 27 recessive specific locus mutations were detected in the spermatogonial group. In the post-spermatogonial treatment group no dominant cataract mutation was observed in 425 offspring and 2 recessive specific locus mutations were detected in 445 offspring. The induced mutation rate per locus, gamete and Gy in spermatogonia for recessive specific locus mutations is 2.8 X 10(-5) and for dominant cataract mutations 0.9 X 10(-6). In post-spermatogonial stages, the mutation rate for recessive specific locus alleles is 6.2 X 10(-5). In the concurrent untreated control group, in 11 036 offspring no dominant cataract mutation and in 23 518 offspring no recessive specific locus mutation was observed. Litter size and the number of carriers at weaning have been determined in the confirmation crosses of the obtained dominant cataract mutants as indicators of viability and penetrance effects. Two mutants had a statistically significantly reduced litter size and one mutant had a statistically significantly reduced penetrance.     

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.     

X-ray-induced specific-locus mutation rates in young male mice

The specific-locus mutation frequency resulting from 300 R of acute X-irradiation has been determined for the germ cells present in male mice at 2, 4, 6, 8, 10, 14, 21, 28, and 35 days of age. The sample size was large enough for each of these nine age groups to ensure that a high mutation rate would be noticed. The testis of the mouse undergoes many developmental changes between birth, when most or all germ cells are gonocytes, and 35 days, when the cell population has come to resemble that of the adult. It was important to know if the germ cells present in these developmental stages of immature male mice yield the same mutation frequency as that found earlier for spermatogonia in the adult by W. L. Russell.None of the nine age groups has a mutation rate statistically significantly higher than that of the adult. Taken together, the nine groups of males have an average mutation frequency quite to that of the adult. This does not rule out the possibility that individual age groups may have a mutation frequency somewhat different from that of the adult.The distribution of mutations among the loci seems to be similar to that found for mutations induced in spermatogonia of the adult. Clusters of specific-locus mutations were found only on day 21.This paper and that presented earlier on the newborn report the first specific-locus mutation-rate studies on male mice irradiated between birth and adulthood. If the results can be carried over to man, it can be concluded that irradiation of the immature testis, from birth to puberty, will not present any greatly increased genetic hazard over that from irradiation of the adult testis. In fact, as the data stand in the mouse, they indicate a mutation rate similar to the adult for all but the earlier stages tested and, for these stages, a probably lower rate, representing a transition from the significantly lower rate reported earlier for newborns.     

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.     

Induction of congenital malformations in the offspring of male mice treated with X-rays at pre-meiotic and post-meiotic stages

The induction of congenital malformations among the offspring of male mice treated with X-rays at pre-meiotic and post-meiotic stages has been studied in two experiments. Firstly, animals were exposed to varying doses (108–504 cGy) of X-rays and mated at various time intervals (1–7, 8–14, 15–21 and 64–80 days post-irradiation), so as to sample spermatozoa, spermatids and spermatogonial stem cells. In the second experiment, only treated spermatogonial stem cells were sampled. One group of males was given a single 500-cGy dose, a second group a fractionated dose (500 + 500 cGy, 24 h apart) and a third group was left unexposed.In the first experiment, induced post-implantation dominant lethality increased with dose, and was highest in week 3, in line with the known greater radiosensitivity of the early spermatid stage. Preimplantation loss also increased with dose and was highest in week 3. There was no clear induction of either pre-implantation or post-implantation loss at spermatogonial stem cell stages.There was a clear induction of congenital malformations at post-meiotic stages, the overall incidence being 2.0 ± 0.32% in the irradiated series and 0.24 ± 0.17% among the controls. The induction was statistically significant at each dose. At the two highest doses the early spermatids (15–21 days) appeared more sensitive than spermatozoa, and at this stage the incidence of malformations increased with dose. The data from Expt. 1 on the induction of malformations by irradiation of spermatogonial stages were equivocal. In contrast, Expt. 2 showed a statistically significant induction of malformations at both dose levels (2.2 ± 0.46% after 500 cGy and 3.1 ± 0.57% after 500 + 500 cGy). The relative sensitivities of male stem cells, post-neiotic stages and mature oocytes to the induction of congenital malformations were reasonably similar to their sensitivities for specific-locus mutations, except that the expected enhancing effect of the fractionation regime used was not seen.Dwarfism and exencephaly were the two most commonly observed malformations in all series.     

Bleomycin, unlike other male-mouse mutagens, is most effective in spermatogonia, inducing primarily deletions

Dominant-lethal tests [P.D. Sudman, J.C. Rutledge, J.B. Bishop, W.M. Generoso, Bleomycin: female-specific dominant lethal effects in mice, Mutat. Res. 296 (1992) 205-217] had suggested that Bleomycin sulfate (Blenoxane), BLM, might be a female-specific mutagen. While confirming that BLM is indeed a powerful inducer of dominant-lethal mutations in females that fails to induce such mutations in postspermatogonial stages of males, we have shown in a specific-locus test that BLM is, in fact, mutagenic in males. This mutagenicity, however, is restricted to spermatogonia (stem-cell and differentiating stages), for which the specific-locus mutation rate differed significantly (P<0.008) from the historical control rate. In treated groups, dominant mutations, also, originated only in spermatogonia. With regard to mutation frequencies, this germ-cell-stage pattern is different from that for radiation and for any other chemical studied to date, except ethylnitrosourea (ENU). However, the nature of the spermatogonial specific-locus mutations differentiates BLM from ENU as well, because BLM induced primarily (or, perhaps, exclusively) multilocus deletions. Heretofore, no chemical that induced specific-locus mutations in spermatogonia did not also induce specific-locus as well as dominant-lethal mutations in postspermatogonial stages, making the dominant lethal test, up till now, predictive of male mutagenicity in general. The BLM results now demonstrate that there are chemicals that can induce specific-locus mutations in spermatogonia without testing positive in postspermatogonial stages. Thus, BLM, while not female-specific, is unique, (a) in its germ-cell-stage specificity in males, and (b) in inducing a type of mutation (deletions) that is atypical for the responding germ-cell stages (spermatogonia).     

The effect of dose rate on the frequency of specific-locus mutations induced in mouse spermatogonia is restricted to larger lesions; a retrospective analysis of historical data

A series of 19 large-scale germ-cell mutagenesis experiments conducted several decades ago led to the conclusion that low-LET radiation delivered to mouse spermatogonia at dose rates of 0.8 R/min and below induced only about one-third as many specific-locus mutations as did single, acute exposures at 24 R/min and above. A two-hit origin of the mutations was deemed unlikely in view of the then prevailing evidence for the small size of genetic lesions in spermatogonia. Instead, the dose-rate effect was hypothesized to be the result of a repair system that exists in spermatogonia, but not in more mature male reproductive cells. More recent genetic and molecular studies on the marker genes have identified the phenotypes associated with specific states of the mutant chromosomes, and it is now possible retrospectively to classify individual past mutations as "large lesions" or "other lesions". The mutation-frequency difference between high and low dose rates is restricted to the large lesion mutations, for which the dose-curve slopes differ by a factor exceeding 3.4. For other lesion mutations, there is essentially no difference between the slopes for protracted and acute irradiations; induced other lesions frequencies per unit dose remain similar for dose rates ranging over more than 7 orders of magnitude. For large lesions, these values rise sharply at dose rates >0.8 R/min, though they remain similar within the whole range of protracted doses, failing to provide evidence for a threshold dose rate. The downward bend at high doses that had been noted for X-ray-induced specific-locus mutations as a whole and ascribed to a positive correlation between spermatogonial death and mutation load is now found to be restricted to large lesion mutations. There is a marked difference between the mutation spectra (distributions among the seven loci) for large lesions and other lesions. Within each class, however, the spectra are similar for acute and protracted irradiation.