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.     

Induction of specific-locus mutations in male germ cells of the mouse by acrylamide monomer

Acrylamide monomer (AA), injected into male mice at the maximum tolerated dose of 5 x 50 mg/kg (24-h intervals), significantly increased the specific-locus mutation rate in certain poststem-cell stages of spermatogenesis, but not in spermatogonial stem cells. Germ-cell stages in which the treatment induced dominant lethals--namely, exposed spermatozoa and late spermatids (number of surviving offspring only 3% and 27%, respectively, of those in concurrent controls)--jointly yielded the highest frequency of specific-locus mutations. AA thus conforms to Pattern 1 in our earlier classification of chemicals according to the spermatogenic stage at which they elicit maximum response (Russell et al., 1990). No specific-locus mutations were observed among 17,112 offspring derived from exposed spermatogonial stem cells, a result which rules out (at the 5% significance level) an induced mutation rate greater than 2.3 times the historical control rate. A sustained high productivity in matings made for several months following week 3 indicates that there is no significant spermatogonial killing and that cell selection is presumably not the explanation for the negative result. On the basis of genetic and/or cytogenetic evidence, the mutations induced postmeiotically by AA were 'large lesions' (multi-locus), while one of 2 recovered from exposure of differentiating spermatogonia is probably a small lesion. An earlier survey of mammalian mutagenesis results led us to conclude that, regardless of the classification of a chemical according to the stage at which it elicits its maximum response, the nature of mutations is determined by the germ-cell stage in which they are induced (Russell et al., 1990). The AA results on lesion size and on distribution of mutations among the loci fit the general pattern.     

Biological and chemical monitoring of occupational exposure to ethylene oxide

Studies were carried out on two populations occupationally exposed to ethylene oxide (EtO) using different physical and biological parameters. Blood samples were collected from 9 hospital workers (EI) and 15 factory workers (EII) engaged in sterilization of medical equipment with EtO and from matched controls (CI and CII). Average exposure levels during 4 months (the lifespan of erythrocytes) prior to blood sampling were estimated from levels of N-(2-hydroxyethyl)valine adducts in hemoglobin. They were significantly enhanced in EI and EII and corresponded to a 40-h time-weighted average of 0.025 ppm in EI and 5 ppm in EII. Exposures were usually received in bursts with EtO concentrations in air ranging from 22 to 72 ppm in EI and 14 to 400 ppm in EII. All samples were analyzed for HPRT mutants (MFs), chromosomal aberrations (CAs), micronuclei (MN) and SCEs. MFs were significantly enhanced by 60% in EII but not in EI. These results are the first demonstration of mutation induction in man by ethylene oxide. CAs were significantly enhanced in EI and EII by 130% and 260% respectively. MN were not enhanced in EI but significantly in EII(217%). The mean frequency of SCEs was significantly elevated by 20% in EI and by almost 100% in EII. SCE was the only parameter that allowed distinction between daily and occasionally exposed workers in EII. An interesting finding in exposed workers was the large increase of the percentage of cells with high frequencies of SCE (3–4 times in EI and 17-fold in EII).

The relative sensitivity of endpoints for detection of EtO exposure in the present investigation was in the following order: HOEtVal adducts > SCEs > chromosomal aberrations > micronuclei > HPRT mutants.     

Mouse specific-locus test for the induction of heritable gene mutations by dibromochloropropane (DBCP)

The nematocide DBCP (1,2-dibromo-3-chloropropane) produced negative results in a specific-locus test for gene-mutation induction in the germline of male (101 X C3H)F1 mice, most of which were treated with 5 daily intraperitoneal injections of 80 mg/kg (total exposure, 400 mg/kg); a few received lower exposures. For treated spermatogonial stem cells, the finding of 2 mutations among 39519 offspring--a rate almost identical to the control rate--rules out (at the 5% significance level) an induced mutation frequency greater than 2.0 times the historical control rate. From treated poststem-cell stages, no mutants were found among 6240 offspring, ruling out (at the 5% significance level) a multiple of 8.0 times the control for these cell types. A multiple rearrangement (7 chromosomes involved in 3 translocations) found in one of the mutants probably arose as a postmeiotic event not associated with the DBCP treatment. The fertility of DBCP-treated males was not disturbed, in keeping with the absence of germ-cell toxicity and dominant lethals found by other investigators in these mice, and in contrast to results in certain other species. While the treated (101 X C3H)F1 mice are Ah-responsive, other findings make it questionable whether biotransformation of DBCP to reactive intermediates is accomplished via the Ah-receptor system.     

Estimation of the frequencies of induced mutations in spermatogenic cells of senescence-accelerated prone mice of the SAMP1 strain

The results obtained in this work demonstrate the dynamics of cytogenetic changes of spermatogenic cells in senescence-accelerated prone mice, strain SAMP1, after a single exposure to a chemical mutagen, dipin, at a genetically active dose of 30 mg/kg. In the time interval between days 3 and 28 the frequency of induced spermatogonial micronuclei does not significantly exceed the level of spontaneous mutagenesis. The lack of an experimental effect of micronuclei in this time interval is probably a consequence of mitotic delay and (or) of the death of a considerable part of genetically defective cells in the spermatogonial compartment. Different stages of meiosis exhibit different chemical sensibilities: the yield of round spermatids with micronuclei is maximum after treatment of early primary spermatocytes (preleptotene-leptotene stage) with dipin. The high sensibility of preleptotene and leptotene spermatocytes is confirmed by the sperm head shape abnormality assay. Chromosome damage caused by dipin in spermatogonial stem cells is irreversible, as evidenced by a sharp increase in the frequencies of spermatogonial and meiotic micronuclear aberrations within long periods after treatment. Increased genetic instability in the stem compartment does not lead to irreversible degradation of the system of development of male sex cells in senescence-accelerated SAMP1 mice.     

The micronucleus assay in human exfoliated cells of the nose and mouth: application to occupational exposures to chromic acid and ethylene oxide

We have applied the micronucleus (MN) assay to exfoliated cells of buccal and nasal cavities to monitor the genotoxic risk in a group of workers exposed to chromic acid and in another group exposed to ethylene oxide (EtO). The first group comprised 16 subjects working in a 'hard' type chrome-plating factory showing increased chromium absorption and chromium-induced rhinopathy. The second group comprised 9 subjects working in a sterilization unit, exposed to EtO concentrations lower than 0.38 ppm as timed weighted average (TWA) for a working shift; 3 of them were involved in a acute exposure too. The frequency of MN in buccal mucosa was within the norm for exposure both to chromium and to EtO. The MN frequency in nasal mucosa was not altered in chromium platers, whereas a significant increase (p less than 0.01) in MN was found in 2 out of 3 subjects involved in the accidental EtO leakage and a non-significant increase in MN was found in the group chronically exposed to EtO.     

Sensitivity of Drosophila melanogaster to low concentrations of gaseous mutagens. II. Chronic exposures.

Sex-linked recessive lethal mutations were induced in Drosophila melanogaster males by gaseous 1,2-dibromoethane at concentrations ranging from 0.2 to 2 parts per million. Significant numbers of mutations could be induced at all these concentrations. Pronounced germ-cell sensitivity differences were observed. For low exposures, spermatids and spermatocytes were about 10--20 times more sensitive than spermatozoa. The dose-effect relation was linear below 60 ppm . h for the 3 cell types. At higher exposures, sterility prevented mutation detection in spermatocytes and in spermatogonia. The lowest effective exposure for spermatozoa was 18 ppm . h (0.25 ppm for 72 h). In spermatids, the lowest exposure tested, 2.3 ppm . h (0.2 ppm for 11 h) induced 4 times the spontaneous mutation rate. Therefore, using prolonged exposure periods one may be able to detect concentrations in the range of parts per billion. Thus, Drosophila appears suitable as a system for detecting very low concentrations of gaseous mutagens in industrial, agricultural and environmental atmospheres.     

Molecular dosimetry of the mutagen ethyl methanesulfonate in Drosophila melanogaster spermatozoa: linear relation of DNA alkylation per sperm cell (dose) to sex-linked recessive lethals.

The dosage-response curve for EMS was determined with dose measured as ethylations of DNA per sperm cell, and response measured as the relative frequency of sex-linked recessive lethals induced in sperm cells of Drosophila melanogaster. Dose can be converted to ethylations per nucleotide of DNA by dividing ethylations of DNA per sperm cell by 3 X 10(8) nucleotides per sperm cell. Adult males were exposed to equal amounts of either [3H]EMS for determining dose or nonlabeled EMS for determining mutational response. By feeding EMS for 24 h in a concentration of 25 mM, a high dose of 1.4 X 10(-2) ethylations per nucleotide was observed. With 1.4% of the nucleotides ethylated, 57% of the X-chromosomes were hemizygously viable; therefore, ethylation per se is not very efficient in inducing mutations. The relative frequency of mutations increased linearly with the dose from a dose of 2.1 X 10(-4) to 1.4 X 10(-2) ethylations per nucleotide. No threshold was apparent, and the statistical limits of the exponent, 1.0 +/- 0.1, excluded an exponent as high as 1.2. This linear relation suggests no change in mechanism of mutagenesis occurs from low to high dose in Drosophila. A nonlinear relation was found between exposure and dose; when exposure was increased by a factor of 250 (from 0.1 to 25 mM EMS in the feeding medium) dose was increased by a factor of only 68. By extrapolating down from our lowest dose of 2.1 X 10(-4) ethylations per nucleotide with an observed frequency of 0.55% +/- 0.08% sex-linked recessive lethals, we estimate the doubling dose for sex-linked recessive lethals to be 4 X 10(-5) ethylations per nucleotide.     

Differential spermatogonial stem-cell survival and mutation frequency

One group of adult C3H×101 hybrid male mice was given 3 injections of 12.5 μCi of [³H]thymidine at 9-h intervals and irradiated 24 h after the last injection with X-ray doses of 100, 300, 500, 600, 1000 R or the first fraction of a split 1000-R dose given as two 500-R exposures 24 h apart. Mice were killed 207 and 414 h after irradiation. A second group of mice was given a single injection of 12.5 μCi of [³H]thymidine 1 h before irradiation with single exposures of 300, 500, 600, 1000 R, or the first fraction of a 1000-R exposure given as two 500-R fractions 24 h apart. Mice were killed 120 and 207 h after irradiation. In both experiments, parallel groups of mice were given X-ray only as a control for the effect of [³H]thymidine. Two sets of slides were prepared for each mouse receiving [³H]thymidine: one set was not autoradiographed and was used for scoring cell survival; the second set was coated with emulsion and used for scoring percentage of labeled cells. The dose-response curves for survival at 120 and 207 h were curvilinear, with no evidence of discontinuity over the 100–1000-R range. After multiple injections of [³H]thymidine and irradiation 24 h later, percentage of labeled cells at 207 h was comparable for controls, 100, 300, and 600 R; significantly lower than controls for 1000 R; and significantly above controls after 500 + 500 R. Thus the surviving stem-cell population was qualitatively the same for that portion of the dose-response curve giving a linear increase in mutation rate but was different for both 1000-R and 500 + 500-R exposures, and the single and fractionated 1000-R exposures differed from each other. This parallelism between survival of labeled cells and mutation frequency in spermatogonial stem cells suggests that a stage in the cell cycle 24–42 h after DNA synthesis is resistant to cell killing but sensitive to mutation induction. The mutation rate after a single 1000-R exposure is low because labeled, mutation-sensitive cells have been selectively killed. Mutation frequency after the 500 + 500-R dose is increased because of synchronization induced by the first dose combined with selective killing of unlabeled cells by the second fraction. Irradiation 1 h after labeling with [³H]-thymidine demonstrated that the S phase of the spermatogonial stem-cell cycle is sensitive to radiation-induced cell killing.     

Inhalation exposure-rate of ethylene oxide affects the level of DNA breakage and unscheduled DNA synthesis in spermiogenic stages of the mouse

The effect of ethylene oxide (EtO) inhalation-exposure rate on the induction of DNA breakage in late spermatids and on unscheduled DNA synthesis (UDS) in early spermatids was studied. The exposures were 450 parts per million (ppm) for 4 h, 900 ppm for 2 h, and 1800 ppm for 1 h. Thus, the total exposure was always 1800 ppm-h. Both DNA breakage and UDS were found to increase by a factor of approximately 3 in going from the low to high EtO concentration, suggesting that the molecular dose of EtO to the testis had increased by a similar factor. Our results are consistent with the EtO exposure-rate effect found by Generoso et al. (1986) for induction of dominant-lethal mutations in late spermatids and early spermatozoa.     

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.     

The induction of recessive mutations in mouse primordial germ cells with N-ethyl-N-nitrosourea

A specific-locus test was carried out to examine the mutagenic activity of N-ethyl-N-nitrosourea (ENU) on mouse primordial germ cells (PGC). Embryos of C3H/He mice were treated transplacentally with 30 or 50 mg ENU per kg of maternal body weight on day 8.5, 10.5, or 13.5 of gestation (G8.5 day, G10.5 day, or G13.5 day). Male and female mice that had been treated with ENU in embryonic stages were mated with female or male tester PW mice to detect recessive mutations induced in PGC.

ENU induced recessive mutations at a relatively high rate in PGC at these developmental stages. The most sensitive stage was G10.5 day. On G8.5 day, the induced mutation rate in males and females was not significantly different. Cluster mutations, which originate from the limited number of PGC and cell killing, were more frequently induced at an earlier developmental stage. The induced mutation rate per unit dose of ENU (1 mg/kg) was higher in G8.5 and G10.5 day PGC than in stem-cell spermatogonia. It can be concluded that mouse PGC are more sensitive than stem-cell spermatogonia to the induction of recessive mutations by ENU.     

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.     

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.     

Genotoxic effects of inhaled ethylene oxide, propylene oxide and butylene oxide on germ cells: sensitivity of genetic endpoints in relation to dose and repair status

We report here results on forward mutation induction (recessive lethal mutations, RL) in Drosophila spermatozoa and spermatids by the three 1,2-alkyl-epoxides ethylene oxide (EO), propylene oxide (PO) and butylene oxide (BO), at doses ranging from 47 to 24,000 ppm h for EO, 375 to 48,000 ppm h for PO, and 24,000 to 91,200 ppm h for BO. The results indicate for EO mutation induction at doses 500-fold below the LD₅₀. In crosses of mutagenized NER⁺ males with NER⁺ females, the 500-fold increase in EO dose from 47 ppm h to 24,000 ppm h resulted in no more than a 17-fold enhanced mutant frequency in spermatozoa. This flat dose–response relationship is primarily the result of efficient repair of EO-induced DNA adducts in the fertilized egg, as was evident from the up to 40-fold or 240-fold increased mutant frequencies above NER⁻ or NER⁺ background levels, respectively, in crosses with NER⁻ females. With decreasing dose, / ratios decreased from 9 to 14 at high doses down to ≈1 at the two lowest doses, indicating that a small fraction of premutagenic lesions induced by EO cannot be repaired by the NER system of Drosophila. Linear extrapolation from high to low EO exposure led to an underestimation of the mutation frequency actually observed at low doses. The pattern of EO-induced ring chromosome loss (CL) differed in two respects from that observed for forward mutations: (a) an increase in CL frequencies was observed only at the two highest EO exposure levels, and (b) inactivation of the NER pathway by the mus201 mutant had no measurable effect on the occurrence of CL. The absence of a potentiating effect of mus201 on EO-induced clastogenicity suggests the formation of clastogenic DNA lesions not causing point mutations, and which are not repaired by NER. Consistent with an inversed correlation of reactivities towards N7-guanine and chain length of 1,2-alkyl-epoxides, the relative mutagenic efficiencies of EO:PO:BO are 100:7.2:1.8 for the NER⁺ groups, and 100:20:0.7 in the absence of NER. Although in Drosophila germ cells EO is also more effective as a clastogen than PO, the difference (EO:PO=100:58) is much smaller than for recessive mutations. These results provide another argument that DNA lesions generating base substitutions as opposed to those causing clastogenic damage may not be the same for these agents.     

Effect of deficiency in excision repair and umuC function on the mutagenicity with ethylene oxide in the lacI gene of E. coli

The influence of uvrB and umuC genes on the induction of lacI- mutants and nonsense mutants by ethylene oxide (EtO) in the lacI gene of E. coli was studied. The uvrB mutation was characterized by much higher mutation frequencies. In contrast the umuC mutation does not significantly affect the induction kinetics. Thus mutation by EtO is enhanced by the lack of excision repair but not influenced by error-prone repair.     

Characterization of MMS-sensitive mutants of Neurospora crassa

Several MMS-sensitive mutants of Neurospora crassa were compared with the wild-type strain for their relative sensitivities to UV, X-ray, and histidine. They were also compared for the frequency of spontaneous mutation at the loci which confer resistance to p-fluorophenylalanine. The mutants were also examined for possible defects in meiotic behavior in homozygous crosses and for any change in the inducible DNA salvage pathways (as indicated by their ability to utilize DNA as the sole phosphate source in the growth medium). On the basis of these characterizations, the present MMS-sensitive mutants of Neurospora can be placed into three groups. The first group includes three mutants, mus-(SC3), mus-(SC13), and mus-(SC28). These are slow growers, insensitive to histidine with no apparent meiotic defects and may have reduced frequency of spontaneous mutation. In addition, their mycelial growth is sensitive to MMS but the conidial viability following MMS, UV or X-ray treatment appears normal or only slightly more sensitive than the wild-type. The second group includes only one mutant, mus-(SC15); its mycelial growth is very sensitive to MMS but the conidial survival following treatment with MMS or UV appears normal; however, the conidial survival following exposure to X-ray is significantly reduced. This mutant shows an increase (more than 10-fold) frequency of spontaneous mutation, but behaves normal like the wild-type with respect to fertility, growth rate and insensitivity to histidine. The third group includes mutants mus-(SC10), mus-(SC25), and mus-(SC29). These mutants are very sensitive to UV, X-rays and MMS and to histadine but have normal growth rates on minimal medium. Mutant mus-(SC10), but not mus-(SC25) and mus-(SC29), has an increased (11 ×) frequency of spontaneous mutation. On the basis of data presented, the MMS sensitivity of the first group of mutants cannot be ascertained to arise from a defect in the DNA repair pathways; instead, it may stem from altered cell permeability or other pleotropic effects of the mus mutations. However, it can be suggested that the second and third group of mus mutants may indeed result from a defect in the DNA repair pathways controlled by the mus genes; this conclusion is based on their cross-sensitivity to a number of DNA-damaging agents such as MMS, UV and/or X-ray, high frequencies of spontaneous mutation (mutator effects) and defects in meiotic behavior.     

Effects of three epoxides--ethylene oxide, propylene oxide and epichlorohydrin--on cell cycle progression and cell death in human diploid fibroblasts

Ethylene oxide (EtO), propylene oxide (PO), and epichlorohydrin (ECH) strongly influenced the G1/S progression in human diploid fibroblasts, VH-10. However, these epoxides did not affect substantially the G2/M progression. It was found that G1 arrest is induced by these epoxides 6-18 h after the treatment at doses above 5, 3, and 0.5 mMh for EtO, PO, and ECH, respectively. An inhibitory effect on DNA synthesis was also demonstrated at the same doses within the same time interval. On the contrary, the epoxides transiently stimulated DNA synthesis 3-18 h after the treatment with the lower doses (below 5, 3, and 0.5 mMh for EtO, PO, and ECH, respectively). This effect was manifested both as an elevated rate of DNA synthesis and as an increase in the number of cells in S-phase. Among the three studied epoxides EtO was the most effective one: the increases of the rate of DNA synthesis and of cells in S-phase were 35 and 55%, respectively. All the epoxides tested induced significant decrease of intracellular level of reduced glutathione (GSH) shortly after cell exposure. While low and moderate doses induced a transient decrease in GSH level the high doses induced its irreversible depletion. The extensive GSH depletion was related to cell death. Morphological examination of cell nuclei indicated that epoxide-treated cells die via necrosis. This conclusion is supported by the lack of such features of the apoptosis as chromatin condensation and the occurrence of so called 'apoptotic bodies'. The absence of nucleosomal fragmentation of DNA and an increase of the permeability of the plasma membrane after the epoxide treatment also indicated a necrotic form of cell death. ECH is about ten times more toxic than the two other epoxides, and it causes almost 100% necrosis at dose of 3.0 mMh.     

Determination of the expression time and the dose-response relationship for mutations at the HGPRT (hypoxanthine-guanine-phosphoribosyl transferase) locus induced by X-irradiation in human diploid skin fibroblasts

The lenth of the expression time for mutants resistant to 8-azaguanine or 6-thioguanine induced by X-rays was determined in human diploid skin fibrobalsts. The cells were seeded in the selective medium over a period of 14 days after treatment. Direct expression of at least a part of the mutants was observed at day 0, and an increase of the mutant frequency over the entire cultivation period appeared to be due to spontaneous mutation.The dose-response relationship does not appear to deviate from linearity. The mutation rate per R had a mean value of 2.1 × 10^?7 which is about twice the value of the mutation rate found in rodent cells for the same locus.     

Methods and criteria for deciding whether specific-locus mutation-rate data in mice indicate a positive,negative, or inconclusive result

The binomial approximation of the UMPU (uniformly most powerful unbiased) test for the equality of 2 binomial proportions is shown to be a highly accurate and easily applied method for testing the hypothesis that a given mouse specific-locus mutation frequency is not higher than the spontaneous mutation frequency (43 mutations in 801 406 offspring, for males). Critical sample sizes have been calculated that show at a glance whether P < 0.05.The first hypothesis that the mutation frequency (induced + spontaneous) of treated mice is not higher than the spontaneous mutation frequency is combined with the second hypothesis that the induced mutation frequency of treated mice is no less than 4 times the historical-control mutation frequency to produce a multiple decision procedure with 4 possible decisions: inconclusive result, negative result, positive result, and weak mutagen. Critical sample sizes for the second hypothesis, also with P < 0.05, are combined with those for the first hypothesis into a grid that permits rapid evaluation of data according to these criterea. The justification for using these criteria in reaching decisions, assuming a high level of exposure has been given, is the practical necessity of rapidly determining which chemicals are potent mutagens.Positive results can become apparent in relatively small samples. Larger samples, of at least 11 166 offspring, are required to obtain a negative result. If samples of 18 000 are routinely collected (unless positive results are found earlier), 75% of tests of chemicals that are non-mutagens will give a negative result. If the question being asked is not whether a chemical induces gene mutations but, rather, whether the exposure received by humans causes any important risk from gene mutations, a much smaller sample size may be acceptable, under certain conditions.A comparison of the relative efficiencies of the specific-locus test (for gene mutations and small deficiencies) and the heritable-translocation test (for transmissible chromosome rearrangements), in detecting the same proportional increases over the spontaneous frequencies of their respective types of genetic damage, shows that less work is involved in reaching a conclusive result in the specific-locus test. Proposed specific-locus tests using biochemical markers are at a considerable statistical disadvantage compared with the standard test (using 7 visible markers) for which there is available a very large historical control showing a very low mutation rate.