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.     

Mutagenicity of 2-amino-N6-hydroxyadenine to TK6 human lymphoblast cells

TK6 human lymphoblast cells (tk +/-; hprt+) were treated with various concentrations of 2-amino-N6-hydroxyadenine (AHA) for 24 h. AHA was quite toxic to TK6 cells in the dose range 0-0.05 micrograms/ml, but additional toxicity was not observed between 0.05 and 0.10 micrograms/ml. AHA induced mutations at 2 distinct genetic loci: the autosomal thymidine kinase (tk) and the X-linked hypoxanthine-guanine phosphoribosyl transferase (hprt). Significant levels of both tk-NG mutants (normal growth rate of 16-18 h, colonies visible after 10-11 days incubation) and tk-SG mutants (slow growth rate of greater than 24 h, colonies visible after 18 days incubation) were induced. 15 hprt- mutants were isolated and analyzed by Southern blot. 8 of these had normal restriction fragment patterns after digestion with PstI, EcoRI, and HindIII, and were defined as 'point' mutations; the remaining 7 had partial deletions of the hprt gene. 32 tk- mutants were also isolated. 3 of 22 normal growth mutants and 6 of 10 slow growth mutants had lost the active tk allele. These data suggest that both point mutations and larger-scale alterations are induced by AHA.     

Mutagenicity of 2-amino-N6-hydroxyadenine (AHA) at three loci in L5178Y/tk+/- mouse lymphoma cells: molecular and preliminary cytogenetic characterizations of AHA-induced tk-/- mutants.

2-Amino-N6-hydroxyadenine (AHA) is a remarkably efficient and specific inducer of point mutations in Neurospora, with few or no larger scale events being detected (de Serres et al., 1985). In the present studies, AHA is shown to be a potent point mutagen at the tk +/-, hprt+ and Na+/K+ ATPase loci in L5178Y/tk (+/-)-3.7.2C mouse lymphoma cells. Both large and small colony tk-/- mutants were analyzed at the molecular level and a preliminary assessment was made of small colony mutant karyotypes (230 bands/haploid metaphase cell; large colony mutants typically have normal karyotypes and were not analyzed). AHA induced greatly delayed (7-9 cell doublings) cytotoxicity, suggestive of a mutational mechanism (e.g., base-pair substitution) requiring DNA replication prior to its phenotypic expression. Approximately one-third of the tk -/- mutants formed small colonies, a phenotype which is typically associated with alterations to chromosome 11b, the site of the functional tkb allele in the parental cells. However, banded karyotypes have provided convincing evidence for alterations chromosome 11b in only 2 of the 7 small colony mutants analyzed. Southern blot analysis showed that 78% (21/27) of these small colony mutants have retained the Nco-1 6.3-kb band, which is diagnostic of the tkb allele. This makes AHA unique among the mutagens examined so far in inducing small colony mutants without inducing large losses of tkb DNA. Although a dose-dependent increase in the proportion of small colony mutants was noted, no significant dose-dependent differences were seen at the molecular level in the relatively few mutants analyzed. The majority of AHA-induced tk -/- mutants formed large colonies. Southern blot analysis showed that 86% (25/29) of these had retained the Nco-1 6.3-kb band which is diagnostic of the tkb allele. It is concluded that AHA induces primarily micromutations (less than 100 base pairs), probably through a base-pair substitution mechanism, at the tk, hprt and Na+/K+ ATPase loci in this system, with some larger scale damage (kilobases of DNA at the molecular level; chromosome 11b damage at the cytogenetic level) also occurring.     

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.     

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.     

Spindle poisons induce allelic loss in mouse lymphoma cells through mitotic non-disjunction

Aneuploidy is an important contributor to reproductive failure and tumor development. It arises spontaneously or as a result of exposure to aneugenic agents through non-disjunction. Two spindle poisons, colchicine (COL) and vinblastine (VBL) are mutagenic in the mouse lymphoma assay (MLA), a gene mutation assay that targets the heterozygous thymidine kinase (tk) gene on chromosome 11 in mouse lymphoma L5178Y tk+/- 3.7.2c cells. To investigate the mechanisms of spindle poison mutagenesis, we analyzed the COL- and VBL-induced TK mutants at the molecular and cytogenetic level. Loss of heterozygosity (LOH) analysis employing a microsatellite region within the tk locus revealed that almost all mutants had lost the functional tk allele. To determine the extent of the LOH, we further examined LOH mutants for heterozygosity at nine microsatellite loci spanning the entire chromosome 11. Interestingly, every microsatellite marker showed LOH in all COL- and VBL-induced LOH mutants, suggesting that these mutants were generated by loss of the whole chromosome 11 through mitotic non-disjunction. Chromosome painting analysis supported this hypothesis; there were no mutants showing structural changes such as deletions or translocations involving chromosome 11. In contrast, spontaneous TK mutants followed from point mutations, deletions and recombinational events as well as whole chromosome loss. Our present study indicates that spindle poisons induce mutations through mitotic non-disjunction without structural DNA changes and supports a possible mechanism in which a recessive mutation mediated by aneuploidy may develop tumors.     

Do trifluorothymidine-resistant mutants of L5178Y mouse lymphoma cells re-express thymidine kinase activity following 5-azacytidine treatment?

TFT is an effective selective agent for TK-deficient mutants of L5178Y TK+/- -3.7.2C mouse lymphoma cells. Mutants can be classified by colony size into small colonies (many of which show readily observable chromosome abnormalities associated with chromosome 11--the location of the TK gene) and large colonies (which may represent events affecting only the expression of the TK gene). The precise nature of the induced damage causing the loss of the TK-enzyme activity for both mutant type is not known and is currently under investigation. The hypomethylating agent 5-azacytidine can be utilized to investigate the possibility that mutants might be the result of a suppressed rather than an altered TK gene. Mutant cell lines are treated with 5-azacytidine and then evaluated for re-expression of the TK enzyme as measured by resistance to THMG. In these studies, 11 mutants have been evaluated. None of the 11, including 10 small-colony mutants (6 with chromosome 11 translocations) and 1 large-colony mutant, show a high conversion to TK competency following 5-azacytidine treatment.     

The mutagenicity of 2-amino-N6-hydroxyadenine to L5178Y tk +/- 3.7.2C mouse lymphoma cells: measurement of mutations to ouabain, 6-thioguanine and trifluorothymidine resistance, and the induction of micronuclei

2-Amino-N6-hydroxyadenine (AHA) was tested in the mouse lymphoma L5178Y tk +/- assay using the microtitre cloning technique over concentrations from 0.005 micrograms/ml-1 (100% viability) to 6 micrograms/ml (10% viability) as measured by cloning efficiency immediately after treatment. At low, non-toxic concentrations (0.005-0.25 micrograms/ml) a dose-related linear increase in the frequency of ouabain-resistant mutants was seen, in addition to an increase in 6-thioguanine- and trifluorothymidine-resistant mutants. No consistent induction of micronucleated cells was observed in this concentration range. Toxic concentrations (20-90% kill) induced a dose-related increase in micronuclei, while the frequency of ouabain-resistant mutants fell (although it was still highly significantly above the control value). These results suggest that the mechanism of action of AHA depends on the concentration, with point mutations being induced at low, non-toxic doses and detectable chromosome breakage occurring only at higher doses. Both large-colony and small-colony trifluorothymidine-resistant mutants were induced at all concentrations. The utility of using multiple genetic end-points in one cell line and the importance of dose range selection for risk assessment and an understanding of the mode of action of test substances is underlined.     

Chromosome analysis of small and large L5178Y mouse lymphoma cell colonies: comparison of trifluorothymidine-resistant and unselected cell colonies from mutagen-treated and control cultures

Mutagenesis assays at the thymidine kinase (TK) locus in L5178Y mouse lymphoma cells frequently yield mutant colonies with a bimodal size distribution. The objectives of this study were to determine whether a relationship exists between mutant colony size and chromosomal aberrations and whether the colony-size distributions obtained from this assay can indicate the clastogenic activity of a test chemical. Cells from 8 different types of L5178Y mouse lymphoma cell colonies were examined for chromosomal abnormalities within 10 cell generations after colony isolation. The colonies included small (sigma) and large (lambda) unselected cell (UC) and trifluorothymidine-resistant (TFTr) colonies derived from TK +/- cell cultures treated with the solvent dimethyl sulfoxide (DMSO) or hycanthone methanesulfonate (HYC). Chromosome abnormalities were present in cells from 12% (7/60) of the UC colonies, but there was no apparent relationship between colony diameter and the presence of chromosomal abnormalities. Abnormalities affecting chromosome 11, which is believed to be the site of the TK gene, were not observed in cells from UC colonies. Abnormalities affecting chromosome 11 were observed only in cells from sigma-TFTr colonies irrespective of whether they were spontaneous (5/15 colonies) or induced by HYC (4/15 colonies). Overall, 30% (9/30) of sigma-TFTr colonies had cells with an abnormal chromosome 11 and 10% (3/30) had abnormalities affecting other chromosomes. Abnormalities affecting chromosome 11 were not observed in cells from lambda-TFTr colonies (0/30 colonies). The observation of only 30% of sigma-TFTr colonies with chromosome damage affecting chromosome 11 indicates that other mechanisms, in addition to chromosome damage at the level of resolution used in this study (i.e., 200-300 chromosome bands). contribute to small TFTr colony size.     

Analysis of trifluorothymidine-resistant (TFTr) mutants of L5178Y/TK+/- mouse lymphoma cells

Three classes of TFTr variants of L5178Y/TK+/- -3.7.2C mouse lymphoma cells can be identified--large colony (lambda), small colony (sigma), and tiny colony (tau). The sigma and lambda mutants are detectable in the routine mutagenesis assay using soft agar cloning. The tau mutants are extremely slow growing and are quantitated only in suspension cloning in microwells. Variants of all three classes have been analyzed in the process of evaluating the usefulness of the thymidine kinase locus in L5178Y/TK+/- mouse lymphoma cells for detecting induced mutational damage. 150 of 152 variants from mutagen treated cultures and 163 of 168 spontaneous mutants were TFTr when rechallenged approximately 1 week after isolation (3 weeks after induction). All of the 41 mutants assayed for enzyme activity were TK-deficient. The sigma and tau phenotypes were found to correlate with slow cellular growth rates (doubling time greater than 12 h), rather than from effects of the TFT selection or mutagen toxicity. Cytogenetic analysis of sigma mutants approximately 3 weeks after induction shows an association between the sigma phenotype and readily observable (at the 230-300 band level) chromosomal abnormalities (primarily translocations involving that chromosome 11 carrying the functional TK gene) in 30 of 51 induced mutants studied. Using an early clonal analysis of mutants (approximately 2 weeks after induction) 28 of 30 sigma mutants showed chromosome 11 rearrangements. All lambda mutants studied (17 of 17 evaluated 3 weeks after induction and 8 of 8 evaluated 2 weeks after induction) showed normal karyotypes (at the 230-300 band resolution level), including the chromosome 11s. These observations support the hypothesis that sigma (and likely tau) mutants represent chromosomal mutations and lambda mutants represent less extensive mutations affecting the TK locus. The inclusion of sigma mutants in the total induced mutant frequency, as well as distinguishing them as a separate subpopulation of TK-deficient mutants, is, therefore, essential in obtaining maximum utility of the information provided by the L5178Y/TK+/- mouse lymphoma assay.     

Cytogenetic characterization of the L5178Y TK+/-3.7.2C mouse lymphoma cell line

The cytogenetic characterization of the L5178Y TK+/-3.7.2C mouse lymphoma cell line was carried out, utilizing G-banded metaphase chromosomes, to provide a karyotypic basis for the precise delineation of induced rearrangements in TK-/- mutants. Band-pattern measurements were used to construct ideograms which represent the position, number, size and staining intensity of the chromosome bands. The TK+/-3.7.2C cell line has been shown to provide quantitation of forward mutations induced at the autosomal thymidine kinase (TK) locus in this cell line. Chromosome analysis of the TK+/-3.7.2C cell line and derived TK-/- mutants has become important in demonstrating that the TK+/-----TK-/- assay may detect and distinguish between chromosomal events and smaller, perhaps point-mutation, events in mutant colonies.     

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.     

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.     

Comparative induction of gene mutations and chromosome damage by 1-methoxy-1,3,5-cycloheptatriene (MCHT), 2. Results using L5178Y mouse lymphoma cells to detect both gene and chromosome damage; validation with ionizing radiation, methyl methanesulphonate, ethyl methanesulphonate and benzo[a]pyrene

A variation of the mouse lymphoma (L5178Y TK+/(-)-3.7.2c) assay has been developed using a microtiter cloning technique instead of the standard agar method. The cell line has been used to detect both gene mutations (at the Na+/K+ ATPase and thymidine kinase loci) and chromosome damage (micronucleus induction) in the same experiment. The system was validated using gamma-irradiation (a known clastogen), 2 direct-acting mutagens, ethyl and methyl methanesulphonate and an indirect-acting mutagen, benzo[a]pyrene. Using the assay, 1-methoxy-1,3,5-cycloheptatriene was shown to be a clastogenic mutagen in the presence of S9, since a clear dose-dependent increase in micronuclei was observed, mainly small colony thymidine kinase mutants were observed, and no ouabain-resistant mutants were induced, a profile very similar to gamma-irradiation. The results suggest that metabolic activation potential explains the results in the accompanying paper (Asquith et al., 1990). The implications for mutagenicity testing are discussed.     

Induction of TK mutations in human lymphoblastoid TK6 cells by the rat carcinogen 3-chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (MX)

3-Chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (MX), a chlorine disinfection by-product in drinking water, is carcinogenic in rats and genotoxic in mammalian cells in vitro. In the current study, the mechanism of genotoxicity of MX in human lymphoblastoid TK6 cells was investigated by use of the Comet assay, the micronucleus test, and the thymidine kinase (TK) gene-mutation assay. MX induced a concentration-dependent increase in micronuclei and TK mutations. The lowest effective concentrations in the MN test and the TK gene-mutation assay were 37.5μM and 25μM, respectively. In the Comet assay, a slight although not statistically significant increase was observed in the level of DNA damage induced by MX in the concentration range of 25-62.5μM. Molecular analysis of the TK mutants revealed that MX induced primarily point mutations or other small intragenic mutations (61%), while most of the remaining TK mutants (32%) were large deletions at the TK locus, leading to the hemizygous-type loss-of-heterozygosity (LOH) mutations. These findings show that aside from inducing point mutations, MX also generates LOH at the TK locus in human cells and may thus cause the inactivation of tumour-suppressor genes by LOH.     

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 of 2-amino-N6-hydroxyadenine at the tk locus in L5178Y strains differing in repair capabilities and karyotype

The cytotoxicity and mutagenicity of 2-amino-N6-hydroxyadenine (AHA) were measured in strains of L5178Y differing in repair capabilities and karyotype. Strain LY-R83 is monosomic for chromosome 11 and is therefore hemizygous for the tk gene, while strains LY-R16 and LY-S1 are TK+/- heterozygotes. Both strain LY-R83 and LY-R16 are sensitive to UV light and are presumed to be deficient in the excision of pyrimidine dimers as shown for the parental strain, LY-R (Hagen et al., 1988; Szumiel et al., 1988). Strain LY-S1 is sensitive to the cytotoxic effects of ionizing radiation and is presumed to be defective in the repair of radiation-induced DNA double-strand breaks, as shown for the parental strain, LY-S (Evans et al., 1987a; Wlodek and Hittelman, 1987). The sensitivities of the three strains to the cytotoxic effects of AHA were similar. After a 4-hour treatment with AHA at 37 degrees C, the D37 for all three strains was approximately 35 ng/ml. The AHA-induced mutant frequency was similar for the hemizygous TK+ strain LY-R83 and the heterozygous TK +/- strain LY-R16, but was slightly higher for strain LY-S1 than for either LY-R strain at an AHA concentration of 100 ng/ml. The proportion of AHA-induced LY-S1 TK -/- mutants forming colonies with diameters less than 0.3 mm was much lower than following treatment with X radiation (24% vs. 61% for AHA and X radiation, respectively). These results indicate that the vast majority of AHA-induced TK -/- mutants harbor single gene mutations. AHA did not result in cyanide-insensitive oxygen uptake, and treatment with this compound did not induce a significant number of DNA single-strand breaks, DNA alkali labile lesions, or DNA degradation in either strain. However, two hours after AHA removal, DNA single-strand breaks and/or alkali-labile lesions, possibly due to the occurrence of DNA repair, were apparent in the DNA of both strain LY-R16 and strain LY-S1.     

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.     

High-resolution cytogenetic characterization of the L5178Y TK+/- mouse lymphoma cell line

High-resolution chromosome preparations from L5178Y TK+/- 3.7.2C mouse lymphoma cells were obtained using acridine orange in the cell harvest procedure. With this technique it is possible to visualize over 500 bands in elongated mouse lymphoma cell chromosomes as compared to the approximately 230 bands visualized in metaphase preparations. High-resolution lymphoma cell chromosomes are described, and chromosome rearrangements carried in the cell line are characterized by ideograms representing the position, number, size, and relative staining intensity of the G-band patterns. Use of elongated chromosomes of mouse lymphoma TK+/- mutants should facilitate analysis of the cytogenetic effects associated with TK+/- ----TK-/- mutagenesis.