Comparative induction of gene mutations and chromosome damage by 1-methoxy-1,3,5-cycloheptatriene (MCHT), 1. Results from a battery of standard tests

The ability of 1-methoxy-1,3,5-cycloheptatriene (MCHT) to induce gene mutations and chromosome breaks has been examined in a battery of standard assays. MCHT was not mutagenic to 5 strains of Salmonella, with or without S9 fraction. In L5178Y TK+/- mouse lymphoma cells, MCHT induced TK-/- mutants in the presence but not in the absence of S9 fraction. In V79 Chinese hamster cells, MCHT induced azaguanine-resistant mutants in the presence and absence of S9 but the effect was considerably reduced in the absence of S9. MCHT resulted in no increases in chromosome aberrations in cultured human lymphocytes, with or without S9 fraction, neither was there any increase in micro-nucleated polychromatic erythrocytes in treated mice. MCHT thus appears on the basis of these results, to be possibly a specific gene mutagen (rather than clastogen) for mammalian cells. This uncommon mutagenicity profile has been investigated further in an accompanying paper (Cole et al., 1990) and has proved to be an oversimplification.     

Chromosome 11 aberrations in small colony L5178Y TK-/- mutants early in their clonal history

We have developed a cytogenetic technique that allows observation of chromosome rearrangements associated with TK-/- mutagenesis of the L5178Y/TK+/-3.7.2C cell line early in mutant clonal history. For a series of mutagenic treatments we show that the major proportion (93%) of small-colony (sigma) mutants studied have chromosome 11 rearrangements (the chromosome containing the thymidine kinase gene) while large-colony (lambda) mutants do not have detectable chromosome rearrangements. In addition, we find among the chromosome abnormalities in sigma mutants a significant proportion (34%) with dicentric chromosomes involving chromosome 11. These potentially unstable chromosome rearrangements may help to explain the karyotypic instability and heterogeneity among chromosome 11 aberrations previously noted in sigma mutants when they are analyzed later in their clonal history.     

High-resolution cytogenetic analysis of L5178Y TK+/- 3.7.2C cells: variation in chromosome 11 breakpoints among small-colony TK-/- mutants

Since the finding that the mouse lymphoma L5178Y TK+/- ----TK-/- forward mutational assay system can detect and distinguish a range of genetic lesions, including large chromosomal aberrations and smaller, perhaps point mutational events, the chromosomal analysis of these lesions at the highest possible level of band resolution has become increasingly important. We have developed an acridine orange/colcemid/hypotonic treatment for TK-/- mutants to provide high-resolution chromosomes with over 500 G-bands for breakpoint analysis. Using such high-resolution procedures, we find that independently induced small-colony mutants show rearrangements in the distal portion of chromosome 11, with breakpoints occurring between bands B3 and E1.2. This finding of a range of chromosomal breakpoints in different TK-/- mutants complements recent molecular genetic analysis of mutants and is consistent with the hypothesis that chromosomal lesions in small-colony mutants may affect a large portion of the genome in the vicinity of the tk-1 gene.     

Mutagenicity and clastogenicity of adriamycin in L5178Y/TK(+/-)-3.7.2C mouse lymphoma cells

Adriamycin was found to be both mutagenic and clastogenic to L5178Y/TK(+/-)-3.7.2C mouse lymphoma cells. A dose of only 5 ng/ml (survival = 62% or 67%) gave an induced TK mutant frequency of 307 or 296 per 10(6) survivors in two separate experiments. This dose was also clastogenic, inducing 20 chromosome aberrations/100 cells analyzed. The majority of the mutants were small-colony mutants, indicating that adriamycin likely acts primarily by a clastogenic mechanism.     

Cytogenetic analysis of the L5178Y/TK+/− → TK−/− mouse lymphoma mutagenesis assay system

The L5178Y/TK^+/? → TK^?/? mouse lymphona mutagen assay, which allows selection of forward mutations at the autosomal thymidine kinase (TK) locus, uses a TK^+/? heterozygous cell line, TK^+/? 3.7.2C. Quantitation of colonies of mutant TK^?/? cells in the assay forms the basis for calculations of mutagenic potential of test compounds. We have evaluated the banded karyotypes of the parent TK^+/? heterozygous cell line, as well as homozygous TK^?/? mutants, in order to relate the genetic and morphological properties of mutant colonies. The parent cell line displays karyotype homogeneity, all cells containing normal mouse chromosomes, readily identifiable chromosome rearrangements, and cell line specific marker chromosomes. Mutant TK^?/? colonies of the TK^+/? 3.7.2C cell line form a bimodal frequency distribution of colony sizes for most mutagenic or carcinogenic test substances. Large-colony (λ) TK^?/? mutants with normal growth kinetics appear karyotypically identical within and among clones and with the TK^+/? parental cell line. In contrast, most slow-growing small-colony (σ) TK^?/? mutants have readily recognizable chromosome rearrangements involving chromosome 11, which contains the thymidine kinase gene locus. It is possible that the heritable differences in growth kinetics and resultant colony morphology in λ and σ mutants are related to the type of chromosomal damage sustained. Large-colony mutants receive minimal damage, possibly in the form of point mutations at the TK locus, while small-colony mutants receive damage to other genetic functions coordinately with loss of TK activity, implying gross insult to chromosomal material. It seems likely that λ and σ mutants result from 2 different mutational mechanisms that may be distinguished on the basis of mutant colony morphology.     

Synergism of mutant frequencies in the mouse lymphoma cell mutagenicity assay by binary mixtures of methyl methanesulfonate and ethyl methanesulfonate

The effect of mixed mutagen exposures on the rate and type of induced mutants was studied in the L5178Y/TK+/-----TK-/- mouse lymphoma cell mutagenicity assay. In this assay, exposure to ethyl methanesulfonate (EMS) results in more mutants that form large colonies than small colonies. Exposure to methyl methanesulfonate (MMS) results in more mutants that form small colonies than large colonies. Other reports in the literature suggest that large colony TK-/- mutants appear to result from small-scale, perhaps single-gene mutations, and that small-colony TK-/- mutants appear to be associated with chromosomal mutations. Treating cells for 4 h with simple, 2-component mixtures containing 6.45 micrograms/ml MMS and either 261, 392, 560 or 712 micrograms/ml EMS resulted in synergism of mutants at each mixture level. The frequencies of total mutants were synergized 12, 20, 35 and 72%, respectively, in mixed exposures with graded doses of EMS, above the sums of the mixture components. Small colony mutants were synergized to a greater extent than large colony mutants. The frequencies of small colony mutants in mixed exposures were increased 31, 54, 73 and 123%, respectively, while the frequencies of large colony mutants were increased -7, -6, 11 and 39%. Statistical analyses provide strong evidence of synergism (within the limits of the assay) for total and small-colony mutants at all doses of EMS tested, and for large-colony mutants above 400 micrograms/ml EMS. Similar magnitudes of synergism resulted when other constant levels of MMS (4.30 or 8.60 micrograms/ml) were mixed with the same graded doses of EMS. The degree of synergism was dependent on EMS concentration but not on MMS concentration.     

Mutagenicity and clastogenicity of teniposide (VM-26) in L5178Y/TK +/- -3.7.2C mouse lymphoma cells

The antitumor drug teniposide (VM-26) is a potent inducer of DNA breaks (Long et al., Cancer Res., (1985) 45, 3106), but it is only weakly mutagenic at the hprt locus in CHO cells (Singh and Gupta, Cancer Res., (1983) 43, 577). In the present study, the mutagenic and clastogenic activities of teniposide were evaluated in L5178Y/TK +/- -3.7.2C mouse lymphoma cells. Although teniposide is a weak mutagen at the hprt locus, it is a potent mutagen at the tk locus, with as little as 0.5 ng/ml producing 220 TK mutants/10(6) survivors at 96% survival (background = 100/10(6) survivors). This same dose of teniposide induced 38 aberrations per 100 metaphases (background = 7/100 cells). At 7 ng/ml, teniposide induced approximately 2700 TK mutants/10(6) survivors at approximately 10% survival. At the highest dose sampled for aberration analysis (5 ng/ml), teniposide induced 44 aberrations/100 cells. Most of the aberrations were chromosomal rather than chromatid events. As expected for a compound acting primarily by a clastogenic mechanism, most of the TK mutants were small colonies. Thus, teniposide is a potent clastogen, and it is a potent mutagen at the tk locus but not at the hprt locus. These results support the hypothesis that the location of the target gene affects the ability of the assay to detect both intragenic events and events causing functional multilocus effects. Thus, a heterozygous locus (like tk) but not a functionally hemizygous locus (like hprt) may permit the detection of mutagens that act primarily by a clastogenic mechanism. Because teniposide induces topoisomerase II-associated DNA breaks, and because there is evidence that teniposide may not interact directly with DNA, we discuss the possibility that the potent clastogenic/mutagenic activity of teniposide may be mediated by topoisomerase II.     

Mutagenicity evaluation of HC Blue No. 1 and HC Blue No. 2. III. Effects in the Salmonella typhimurium/Escherichia coli reversion assay and the mouse lymphoma L5178Y TK+/- forward mutation assay

The hair-dye ingredients, HC Blue No. 1 (HCB1) and HC Blue No. 2 (HCB2), were tested for the induction of bacterial mutation using Salmonella typhimurium strains TA1535, TA1537, TA98 and TA100; and Escherichia coli strains WP2uvrA-. In addition, both dyes were evaluated in the mouse lymphoma L5178Y TK+/- assay (MLA) for the potential to induce forward mutation. A liver homogenate (S9) prepared from Aroclor 1254-induced male Fischer 344 rats was used to provide a means for metabolic activation. HCB1 was not mutagenic in the Ames assay, but was weakly mutagenic in the MLA only in the presence of metabolic activation. In contrast, HCB2 was a strong mutagen in the Ames assay in tester strain TA98 both in the presence and absence of metabolic activation. A positive response was also noted with HCB2 in the MLA, both in the presence and absence of metabolic activation. Negative findings from the Ames assay of this study agree with other published results where an identical lot of HCB1 was used. Using the same lot, a weak positive result was observed in the MLA, however, the activation requirements and magnitude of the response were different from that of a lot evaluated by the NTP. In contrast, HCB2 appears to be both a bacterial and mammalian cell mutagen independent of lot variability.     

Mutagenicity and clastogenicity of proflavin in L5178Y/TK +/- -3.7.2.C cells

We evaluated the ability of proflavin to induce specific-locus mutations at the heterozygous thymidine kinase (tk) locus of L5178Y/TK +/- -3.7.2C mouse lymphoma cells, which appears to permit the recovery of mutants due to single-gene and chromosomal mutations. Proflavin was highly mutagenic at the tk locus, producing 724-965 TK mutants/10(6) survivors (background = 56-85/10(6); survival = 29-32%). Most of the mutants were small colonies, which suggested that proflavin may induce chromosomal mutations. The potent clastogenicity of proflavin was confirmed by cytogenetic analysis for chromosomal aberrations. At the highest dose analyzed (1.5 micrograms/ml), proflavin produced 82 aberrations/100 metaphaes (background = 2/100). The large-colony TK mutant frequency produced by proflavin (48-109/10(6) survivors; background = 23/10(6); survival = 57-61%) was similar to published HPRT mutant frequencies produces by proflavin in L5178Y and CHO cells (50-100/10(6) survivors; background = 2-50/10(6); survival = 50-62%). These results lead to the conclusion that proflavin is a potent clastogen and induces a high frequency of small-colony TK mutants; however, it induces a low frequency of HPRT mutants and a low frequency of large-colony TK mutants.     

Genotoxicity of gamma-irradiation in L5178Y mouse lymphoma cells

The ability of gamma-irradiation to induce gene mutation at the thymidine kinase locus and gross chromosome aberrations in L5178Y TK+/- 3.7.2C mouse lymphoma cells was evaluated. Positive results were obtained for both end-points. The majority of mutants were found to be small-colony mutants which correlated with the induction of gross chromosome aberrations.     

Isolation and characterization of mutants at the APRT locus in the L-5178Y TK+/TK- mouse lymphoma cell line

2,6-Diaminopurine(DAP)-resistant mutants have been isolated from mouse lymphoma 5178Y TK+/TK- heterozygotes. In the presence of 50 microM DAP, two colony types were isolated. Small colonies contained 50% wild-type adenine phosphoribosyl transferase (APRT) activity (partial mutants), whereas large colonies have undetectable levels of APRT (aprt- mutants). aprt- mutants could be isolated following mutagenesis with ICR-191 or EMS from the partial mutants. Southern blot analysis of EcoRI digested wild-type DNA using a 3.1 kb mouse aprt genomic probe indicated sequence polymorphism at one or both EcoRI sites flanking the allele. Southern blot analysis of one of the partial mutants and one ICR-induced aprt- mutant (single step) indicated that both strains were hemizygous at the APRT locus. Such stable hemizygous strains would be useful in short-term mutagen tests.     

Micronucleus, chromosome aberration, and small-colony TK mutant analysis to quantitate chromosomal damage in L5178Y mouse lymphoma cells

In testing the hypothesis that the small-colony thymidine kinase-deficient mutants of L5178Y/TK+/- -3.7.2C mouse lymphoma cells represent an estimate of the clastogenicity of test chemicals, we have been performing gross aberration analysis. The present study was initiated to determine if the cytokinesis block method of micronucleus analysis could be performed in mouse lymphoma cells and to compare 3 different endpoints of clastogenicity: the number of metaphases with aberrations, number of binucleates with micronuclei, and small-colony TK mutant frequency. In this study, 12 compounds having varying clastogenic potencies were evaluated. As would be expected, the 3 endpoints vary in the relative magnitude of the quantitated response. This difference likely results from the types of clastogenic damage detected by each endpoint. Of the 3 endpoints tested, only the small-colony TK mutant frequency measures events compatible with long-term cell survival.     

Effect of pH shifts on the mutant frequency at the thymidine kinase locus in mouse lymphoma L5178Y TK+/- cells

Evidence has been accumulating that conditions of nonphysiological pH may affect the results of in vitro genetic tests by mechanisms unrelated to the chemical being tested. Medium was pH-adjusted with HCl, NaOH or with organic buffers (Good's zwitterions). In the absence of S9 mix, no changes in mutant frequency were observed over a pH range of 6.4-9.2; a small, 1.9-fold increase was observed for a moderately toxic treatment (24% relative growth) at pH 6.3. However, in the presence of S9 mix, the mutant frequency increased sharply for pH values below 6.8. At pH 6.4, a 4-fold increase was induced, and pH 6.0 resulted in a 10-fold increase in mutant frequency. Basic pH shifts in the presence of S9 mix caused no changes in mutant frequency up to pH 8.0; treatment with pH 8.8 was highly toxic (5.3% relative growth) and caused a 3-fold increase in mutant frequency. Thirteen mutant clones induced at pH 6.0 with S9 mix were challenged with trifluorothymidine after their expansion in nonselective medium and all retained their resistance; another 14 clones were tested for thymidine utilization and all incorporated only 0.1-5.5% of the 14C-labeled thymidine used by the parental line. The induced mutants were primarily of the small-colony phenotype, which indicated clastogenic activity. This was confirmed with chromosome studies which showed a large increase in cells with aberrations consisting of chromatid breaks and complex rearrangements. The results show that the combination of weak acidity (pH 6-6.8) and S9 mix is mutagenic and clastogenic to L5178Y TK+/- cells.     

A comparison of the CHO/HGPRT+ and the L5178Y/TK+/− mutation assays using suspension treatment and soft agar cloning: Results for 10 chemicals

The mouse lymphoma assay (MLA) and Chinese hamster ovary (CHO) cell assay are sensitive indicators of mutagenicity. The CHO assay has been modified technically to permit treatment in suspension and soft agar cloning comparable to the MLA. This methodology eliminates the risk of metabolic cooperation and the trauma of trypsinization. In addition, a larger population of cells can be treated and cloned for mutant selection. In order to compare the effectiveness of the test systems, 10 chemicals were evaluated for the induction of forward mutations in the CHO and MLA. Several of these chemicals have been reported as clastogenic; therefore, abbreviated colony sizing was performed to gauge the extent of genetic damage to the MLA cells. Both test systems detected benzo[a]pyrene, mitomycin C, acridine orange, and proflavin, and, with the exception of proflavin, more large colonies were present than small colonies. The suspect clastogen, phenytoin, was not mutagenic in the MLA and produced inconclusive results in the CHO. Ethidium bromide, a clastogen and a bacterial mutagen, was not mutagenic in either the MLA or CHO. Four compounds (p-aminophenol, benzoin, methoxychlor, and pyrene) were positive in the MLA, generally inducing a large number of small colonies, while demonstrating no mutagenic activity in the CHO assay. They have also been shown to be generally nongenotoxic in other test systems. Overall, the modified CHO assay did not appear to be better than the MLA for the detection of mutagenic agents. However, the MLA does appear to have lower specificity.Abbreviations AO acridine orange - BAP benzo[a]pyrene - BZN benzoin - CHO Chinese hamster ovary cell assay - DPH diphenylhydantoin - EB ethidium bromide - EMS ethylmethanesulfonate - 3MC 3-methylcholanthrene - MLA mouse lymphoma asay - MMC mitomycin C - MXC methoxychlor - PAP p-aminophenol - PRO proflavin - PYR pyrene     

Genotoxicity of 2-amino-6-N-hydroxyadenine (AHA) to mouse lymphoma and CHO cells.

2-Amino-6-N-hydroxyadenine (AHA) treated L5178Y/TK (+/-)-3.7.2C mouse lymphoma cells were evaluated for mutations at the tk, hgprt, and Na+/K+ ATPase loci, as well as for gross chromosome aberrations and induction of micronuclei. In addition, AHA was evaluated for its ability to induce HGPRT mutants in CHO cells. AHA was found to induce mutations at all evaluated loci and in both cell types. The TK mutants were primarily large colonies although a few small colonies were also induced, particularly at the higher concentrations. Preliminary cytogenetic analysis of AHA-treated mouse lymphoma cells indicated that some gross aberrations but not micronuclei were induced. The 20 small-colony TK mutants evaluated by banded karyotype indicate that only a small fraction (2 of 20) showed chromosome 11 abnormalities. From these studies, it appears that AHA may be one of a very few chemicals that is capable of inducing multi-locus point mutations, with only slight clastogenic activity. Particularly at the higher concentrations, some of the mutants may contain multi-locus point mutations that result in slow growth.     

Trigeminal ganglion infection by thymidine kinase-negative mutants of herpes simplex virus after in vivo complementation.

Infection of trigeminal ganglion by herpes simplex virus (HSV) thymidine kinase-negative (TK-) mutants was investigated in mixed infection studies in mice. Mice were corneally inoculated with TK- HSV alone or with mixtures of TK- HSV-TK+ HSV. When inoculated alone, an arabinosylthymine-selected HSV type 1 TK- mutant and a HSV type 2 TK- deletion mutant infected mouse ocular tissues but rarely infected ganglion tissues. However, both TK- mutants readily infected ganglion tissues when they were inoculated in mixtures with TK+ HSV. By means of mixed infection studies, it was demonstrated that TK- HSV could readily establish acute and latent ganglion infections. It was thought that the frequent infection of trigeminal ganglion tissue by both TK- mutants after mixed TK(-)-TK+ HSV infection was the result of in vivo complementation. After mixed TK(-)-TK+ HSV infection and subsequent cultivation of ganglion explants in arabinosylthymine, results supported the conclusion that when TK- was present in ganglia it was in the same neurons that contained TK+ HSV.     

Genotoxicity of theobromine in a series of short-term assays

Theobromine (3,7-dimethylxanthine) was evaluated for genotoxic activity in a series of in vitro assays. Theobromine was not mutagenic in the Ames assay up to a maximum concentration of 5000 micrograms/plate either with or without S9 activation. The compound also failed to induce significant levels of chromosome aberrations in CHO cells (with and without S9 activation) or transformation in Balb/c-3T3 cells. At the maximum tolerated concentration theobromine increased the frequency of TK-/- mutants in mouse lymphoma L5178Y cells. Increased frequencies were observed both with and without S9 activation and they were reproducible in 2 independent experiments. Statistically significant increases in SCEs were obtained in human lymphocytes and in CHO cells under nonactivation test conditions. The spectrum of results in this battery of tests indicate that theobromine treatment results in the expression of genotoxic potential in some assays and the observed activity appears qualitatively and quantitatively similar to that of caffeine, a closely related methylxanthine.     

Mutagenicity of N-nitrosopyrrolidine derivatives in Salmonella (Ames) and Escherichia coli K-12 (343/113) assays

The mutagenicity of nitrosopyrrolidine (NPYR) and its derivatives was determined by use of the Ames Salmonella assay. A clear specificity to revert the missense stain of TA1535 and a requirement for the phenobarbital-induced rat-liver activation system (S9 mix) were noted. 3,4-Dichloronitrosopyrrolidine was more mutagenic than NPYR, whereas 3-hydroxynitrosopyrrolidine was weakly mutagenic. The carcinogenic nitroso-3-pyrrolidine was not mutagenic under the test conditions. The noncarcinogenic derivatives (2,5-dimethylnitrosopyrrolidine, nitrosoproline and 4-hydroxynitrosoproline) were not mutagenic. Liquid preincubation assays were not any more effective than the pour-plate assays. Selected derivatives of NPYR were tested in the Escherichia coli K-12 (343/113) assay A specificity to revert the missense mutation at the arg locus and a dependence on phenobarbital-induced rat-liver S9 mix were noted with NPYR and its derivatives. 3,4-Dibromonitrosopyrrolidine, which was not mutagenic in Salmonella, was effective in E. coli, and the weakly carcinogenic NPRL was a weak mutagen resulting in a 2-fold enhancement in the E. coli arginine reversion assay.     

Trifluorothymidine resistance and colony size in L5178Y/TK +/- cells treated with methyl methanesulfonate

L5178Y/TK +/- cells treated with methyl methanesulfonate (MMS) were allowed to recover for 0,48,96,144, or 240 hours, and were then plated in soft-agar medium containing trifluorothymidine (TFT). Dose-dependent and consistent increases in the frequency of TFTR cells were observed after each of the 48-240-hour expression periods through the counting of predominantly large, mutant colonies. Size distributions of soft-agar colonies from either MMS-treated or control cells were bimodal in the presence, and unimodal in the absence, of TFT. An increase of small, presumptive TFTR colonies with either increasing MMS concentration or decreasing recovery time was probably a manifestation of chemical toxicity, for a similar increase in small-colony number was observed in the absence of TFT when cells were cloned immediately after MMS treatment, when no induced mutants were yet detectable. Recloning experiments with 22 small-colony-derived cell lines revealed that, with one exception, small-colony morphology was not a heritable trait. While all large- and some small-colony-derived stocks from MMS-treated cells were of the phenotypically stable TK-/- type; spontaneous small TFTR colonies generally were not, their occurrence being directly correlated with serum concentration. No aneuploidy was evident in MMS-treated cell lines several generations after isolation as small TFTR colonies. These results suggest that delayed MMS cytotoxicity in TK +/- cells can temporarily produce increased physiological resistance to TFT in some cells, giving rise to secondary populations of small-colony TFTR variants.     

A comparison of induced mutation at homologous alleles of the tk locus in human cells.

Using a restriction fragment length polymorphism which can distinguish the two copies of the thymidine kinase (tk) gene in the TK6 human lymphoblastoid cell line, we have identified heterozygous subclones with alternate active alleles. Quantitative mutagenesis studies with X-rays revealed a markedly different response, depending on which homolog carried the active allele. The slopes of the dose-response curves differed by approximately 10-fold for mutation of the two alleles and this relationship held true for several independently isolated cell lines. Only one of the cell lines showed a different response to ethyl methanesulfonate. There were no differences among any of the cell lines at the X-linked hprt locus. Analyses of TK- mutants recovered from these cell lines indicated that the reduced yield of mutants from the one allele may be due, at least in part, to a lack of a specific class of TK- mutant, that is, the slow-growing mutants which have been associated with large-scale mutagenic events.