Mutation induction in a mouse lymphoma cell mutant sensitive to 4-nitroquinoline 1-oxide and ultraviolet radiation

The mutant mouse lymphoma cell Q31, which is sensitive to 4-nitroquinoline 1-oxide and ultraviolet radiation (UV), was compared with the parental L5178Y cell for the effect of caffeine and mutation induction after UV irradiation. Caffeine potentiated the lethal effect of UV in both cell strains to a similar extent, indicating that the defective process in Q31 cells was caffeine-insensitive. UV-induced mutation to 6-thioguanine resistance was determined in L5178Y and Q31 cells. The maximal yield of mutants was obtained 7 days post-irradiation in L5178Y cells and 14 days in Q31 cells for higher UV doses. It appears that a much longer time is required for the mutant cells than for the parental cells for full expression of the resistance phenotype even at equitoxic UV doses. A substantially higher frequency in induced mutations was observed in Q31 cells than in L5178Y cells at a given dose of UV. A plot of induced mutation frequency as a function of logarithm of surviving fraction again indicates hypermutability of Q31 cells as compared with the parental strain. In contrast, X-rays induced a similar frequency of mutations to 6-thioguanine resistance in L5178Y and Q31 cells.     

Chromosomal hypersensitivity in mutant M10 and Q31 mouse cells exposed to ultraviolet radiation (UV) and 4-nitroquinoline-1-oxide (4NQO)

2 mutant mouse cells M10 and Q31 were examined for chromosomal aberrations induced by ultraviolet radiation (UV) and 4-nitroquinoline-1-oxide (4NQO), as compared with mouse lymphoma L5178Y cells. Q31 cells are UV- and 4NQO-sensitive cells isolated from L5178Y cells. M10 cells are similar but are sensitive to ionizing radiation and 4NQO. After treatment with UV or 4NQO, chromatid-type aberrations in these cell strains were induced more frequently in the first mitotic cells, at late fixation times. After UV exposure (2.4 J/m2), the maximal frequencies of chromatid-type breaks in Q31 cells were about 5 times higher than in L5178Y cells. In M10 cells such breaks were only as frequent as in L5178Y cells. After 4NQO treatment (50 ng/ml) the frequencies of chromatid-type breaks in M10 and Q31 cells were significantly higher than in L5178Y cells. From these results and those of previous studies (Takahashi et al., 1982), M10 cells may be considered hypersensitive to gamma-rays and 4NQO, but not to UV, and thus react similarly to L5178Y cells. The hypersensitivity of M10 cells to 4NQO may result from a defect in the ionizing-radiation repair mechanism as has been suggested to occur in ataxia telangiectasia (AT) cells. Q31 cells are hypersensitive to UV and 4NQO, but not to gamma-rays. Q31 cells may be considered to be deficient in a UV-like repair pathway. In conclusion, characteristics of murine M10 and Q31 cells are compared with those of human AT and xeroderma pigmentosum (XP) cells.     

UV- and X-ray-sensitive double mutants of mouse L5178Y cells are synergistically more sensitive to 4-nitroquinoline-1-oxide than is either of the single mutants

The X-ray-sensitive mutant M10 and the UV-sensitive mutant Q31 of mouse lymphoma L5178Y cells are both sensitive to killing by 4-nitroquinoline-1-oxide (4NQO). Since cell hybridization experiments showed that the 4NQO sensitivities in M10 and Q31 cells behaved as codominant traits (Shiomi et al., 1982c), it is not possible to determine by complementation test whether the M10 and the Q31 mutations responsible for 4NQO sensitivities are allelic. We have obviated this difficulty by selecting double mutants that are sensitive to both X-rays and UV. From X-ray-sensitive M10 cells, two UV-sensitive mutants (XU 1 and XU 2) were isolated by a cell-suspension spotting method. XU 1 and XU 2 were found to belong to the same complementation group as Q31 (group I). Double mutants XU 1 and XU 2 were 30-37-fold more sensitive to 4NQO than parental L5178Y cells, whereas the single mutants M10 and Q31 were only 6-8-fold more sensitive to 4NQO than L5178Y cells in terms of D10 values (dose required to reduce survival to 10%). These results show that the M10-Q31-double mutations enhance 4NQO sensitivity synergistically, indicating that the M10 and the Q31 mutations relevant to 4NQO sensitivities are non-allelic. The implications of this finding are discussed.     

Characteristics of γ-ray-induced chromosomal aberrations in mutagen-sensitive mutants of L5178Y cells

We have examined the chromosomal radiosensitivities of an ionizing-radiation- and MMS-sensitive mutant (M10), and a UV- and 4NQO-sensitive mutant (Q31), isolated from mouse lymphoma L5178Y cells, with regard to killing effects. In the first mitoses after 100 R γ-irradiations, it was found that M10 cells were highly radiosensitive in terms of chromosomal aberrations accompanying longer mitotic delay (3 h); the frequencies of both chromatid-type and chromosome-type aberrations were, respectively, about 7 and 4 times higher than that of wild-type L5178Y cells. Furthermore, chromatid exchanges, particularly triradials, isochromatid breaks with sister union, and chromatid gaps and breaks were markedly enhanced at G₁ phase of M10 cells. In contrast, the chromosomal radiosensitivity of Q31 cells after 100 R irradiation was similar to that of L5178Y cells. On the other hand, spontaneous aberration frequencies (overall breaks per cell) of M10 and Q31 cells were, respectively, 5.1 and 2.2 times higher than that of wild-type L5178Y cells. The chromosomal hypersensitivity to γ-rays in M10 cells is discussed in the light of knowledge obtained from ataxia telangiectasia cells.     

Studies on three mutagen-sensitive mutants of mouse L5178Y cells. I. Characterization of the hybrids between L5178Y and mutagen-sensitive mutants

Three mutagen-sensitive mutants, MS-1, M10 and Q31, have been isolated from mouse L5178Y cells. MS-1 cells are sensitive to methyl methanesulfonate (MMS), M10 cells are cross-sensitive to X-rays, MMS and 4-nitroquinoline 1-oxide (4NQO), and Q31 cells are cross-sensitive to UV and 4NQO. Lines resistant to 6-thioguanine (TGr) and 5-bromo-2'-deoxyuridine (BUr) were isolated from L5178Y and these three mutagen -sensitive mutants. All the TGr lines were sensitive to 5-bromo-2'-deoxyuridine and HAT medium and all the BUr lines were sensitive to 6-thioguanine and HAT medium. The hybrids homozygous for the mutagen-sensitive markers showed nearly the same sensitivity to UV, 4NQO, X-rays and MMS as their parental TGr and BUr lines. The hybrids constructed by fusing L5178Y BUr and TGr lines from each of MS-1, M10 and Q31 displayed the normal UV, X-ray and MMS resistancy of L5178Y cells. Thus the UV-, X-ray- and MMS-sensitive markers in MS-1, M10 and Q31 were recessive in somatic cell hybrids. The 4NQO-sensitive phenotype, however, behaved codominantly in somatic cell hybrids.     

Studies on three mutagen-sensitive mutants of mouse L5178Y cells. II. Complementation analyses between two methyl methanesulfonate-sensitive mutants and between two 4-nitroquinoline-1-oxide-sensitive mutants

Three mutagen-sensitive mutants, MS-1, M10 and Q31, were isolated from mouse L5178Y cells. MS-1 cells are sensitive to methyl methanesulfonate (MMS), M10 cells are cross-sensitive to X-rays, MMS and 4-nitroquinoline-1-oxide (4NQO); and Q31 cells are cross-sensitive to UV and 4NQO. MMS-, X-ray- and UV-sensitive markers in these mutants behaved recessively in hybrids between pairs of these mutants as in hybrids between L5178Y and these mutants as reported before (Shiomi et al., 1982b). Complementation analyses were carried out by forming hybrids between two MMS-sensitive mutants (MS-1 and M10) and between two 4NQO-sensitive mutants (M10 and Q31). MMS and 4NQO survivals were measured in these hybrid cells. MS-1 and M10 were found to belong to different complementation groups for MMS-sensitive phenotypes. The hybrid clones between M10 and Q31 were as sensitive to 4NQO as each of the mutants, indicating codominance of 4NQO sensitivity in these mutants. The hybrids constructed with L5178Y and three mutants were stable as to their chromosome constitution for 100 days of cultivation without selective pressure. From the segregation studies on these hybrids, it is concluded that neither the X-ray-sensitive mutation in M10 nor the UV-sensitive mutation in Q31 is located on the X chromosome.     

The effect of caffeine on post-replication repair and survival in two L5178Y cell lines with different sensitivities to UV irradiation

2 Strains of murine lymphoma L5178Y cells that varied from the point of view of sensitivity to UV irradiation (mean lethal doses: 3.6 and 8.5 J/m2 for L5178Y-R and L5178Y-S cells, respectively) also differed with respect to sensitization by caffeine. L5178Y-S cells were sensitized to UV irradiation by 0.75 mM caffeine, whereas in the same conditions L5178Y-R cells were not sensitized. Sedimentation analysis of the newly synthesized DNA indicated UV-induced gap formation in L5178Y-S cells only. The subsequent gap filling was inhibited by caffeine. Exposure to UV irradiation induced no gaps in L5178Y-R cells. However, when caffeine was added immediately after irradiation, DNA with reduced molecular weight was found in irradiated cells of both strains after a 2-h chase. On the other hand, caffeine inhibited elongation of undamaged DNA strands in neither of the 2 cell strains.     

Post-irradiation inhibition of scheduled DNA synthesis and stimulation of ADP-ribosylation in sensitive and resistant L5178Y murine lymphoma cells

Post-irradiation changes in DNA synthesis and ADP-ribosyltransferase (ADPRT) activity in L5178YS and L5178YR, radiation sensitive and resistant murine lymphoma cells are described. DNA synthesis was inhibited to a greater extent in L5178YS than in L5178YR cells. The stimulation of ADPRT activity by irradiation was not significantly different between these two cell lines. These observations contribute to other evidence which has failed to confirm a general association of ADP-ribosylation with the DNA synthesis inhibition response. The contrast between the response of L5178Y cells and the corresponding behaviour of ataxia telangiectasia cells and normal human cells indicate that entirely different mechanisms are involved in determining the differences in radiosensitivity in these two systems.     

Repair of DNA single-strand breaks in radiation-sensitive mutants of mouse cells

The radiation-sensitive mutant M10 of mouse lymphoma L5178Y cells was examined for its ability to rejoin DNA single-strand breaks induced by gamma-rays. The alkaline sucrose gradient sedimentation analysis revealed that M10 cells repaired single-strand breaks but simultaneously produced increasing amounts of small DNA fragments with time of postirradiation incubation, something which was not observed in L5178Y cells. Since small fragments did not appear in M10 cells irradiated at room temperature, DNA fragmentation may result from cold treatment during irradiation followed by incubation at 37 degrees C. This indicates that the cold susceptibility is characteristic of M10 cells and is not related to radiation sensitivity of this mutant. This conclusion is supported by the finding that no DNA degradation takes place after cold treatment with a subsequent incubation in the other radiosensitive mutant LX830 that belongs to the same complementation group as M10.     

The contribution of alkylation to the activity of quinone antitumor agents

Studies have shown that the quinone group can produce tumor cell kill by a mechanism involving active oxygen species. This cytotoxic activity can be correlated with the induction of DNA double strand breaks and is enhanced by the ability of the quinone compound to bind to DNA by alkylation. The cytotoxic activity and the production of DNA damage by model quinone antitumor agents were compared in L5178Y cells, sensitive and resistant to alkylating agents, to assess the contribution of alkylation to the activity of these agents. The resistant L5178Y/HN2 cells were found to be two fold and six fold more resistant to the alkylating quinones, benzoquinone mustard and benzoquinone dimustard, respectively, than parent L5178Y cells. In contrast, the L5178Y/HN2 cells showed no resistance to the nonalkylating quinones, hydrolyzed benzoquinone mustard and bis(dimethylamino)benzoquinone. The alkylating quinones produced approximately two fold less cross-linking in L5178Y/HN2 cells compared with L5178Y sensitive cells. DNA double strand break formation by hydrolyzed benzoquinone mustard and bis(dimethylamino)benzoquinone was not significantly different in sensitive and resistant cells. However, the induction of double strand breaks by the alkylating quinones benzoquinone mustard and benzoquinone dimustard was reduced by 5-fold and 15-fold, respectively, in L5178Y/HN2 cells. These results show that the alkylating activity of the alkylating quinones cannot directly explain all of the enhanced cytotoxic activity of these agents. Furthermore, they provide strong evidence that the enhanced formation of DNA double strand breaks by alkylating quinone agents is directly related to the ability of these agents to bind to DNA. This increased formation of strand breaks may account for the enhanced cytotoxic activity of the alkylating quinones.     

Evidence for caffeine-sensitive damage in methylazoxymethanol acetate-treated L5178Y cells.

The effects of methylazoxymethanol (MAM) acetate on colony survival, cell proliferation and DNA synthesis of murine lymphoma L5178Y cells are studied. Decreased sensitivity and immediate depression of cell proliferation and DNA synthesis were found in L5178Y cells in contrast to the reports on HeLa cells. Pre-labelling with 5-bromodeoxyuridine (BUdR) did not enhance significantly the carcinogen-induced cell lethality. Post-treatment with caffeine greatly enhanced cell lethality and depression of cell proliferation. These effects of caffeine were diminished when the cells had passed through two generations following the MAM acetate treatment. Experiments with synchronized cells showed that the action of caffeine was located primarily in S phase following the MAM acetate-treatment. These results strongly suggest that in L5178Y cells, MAM acetate induces damage, which is repaired by a mechanism analogous to post-replication repair of UV light-induced damage.     

The repair of double-strand DNA breaks correlates with radiosensitivity of L5178Y-S and L5178Y-R cells

To better understand the basis for the difference in radiosensitivity between the variant murine leukemic lymphoblast cell lines L5178Y-R (resistant) and L5178Y-S (sensitive), the production and repair of DNA damage after X irradiation were measured by the DNA alkaline and neutral elution techniques. The initial yield of single-strand DNA breaks and the rates of their repair were found to be the same in both cell lines by the DNA alkaline elution technique. Using the technique of neutral DNA elution, L5178Y-S cells exhibited slightly increased double-strand breakage immediately after irradiation, most significantly at lower doses (i.e., less than 10 Gy). Nevertheless, even at doses that yielded equal initial double-strand breakage of both cell lines, the survival of L5178Y-S cells was significantly less than that of L5178Y-R cells. When the technique of neutral DNA elution was employed to measure the kinetics of DNA double-strand break repair, both cell lines exhibited biphasic fast and slow components of repair. However, the double-strand repair rate was much lower in the radiosensitive L5178Y-S cells than in the L5178Y-R cells (T1/2 of 60 vs 16 min). This difference was more pronounced in the fast-repair component. These results suggest that the repair of double-strand DNA breaks is an important factor determining the radiosensitivity of L5178Y cells.     

Chromosomal instability in mutagen-sensitive mutants isolated from mouse lymphoma L5178Y cells. II. Abnormal induction of sister-chromatid exchanges and chromosomal aberrations by mutagens in an ionizing radiation-sensitive mutant (M10) and an alkylating agent-sensitive mutant (MS1)

To determine the mutual relationships between cell survival and induction of sister-chromatid exchanges (SCEs) as well as chromosomal aberrations (CAs), mutagen-induced SCEs and CAs were analyzed in an ionizing radiation-sensitive mutant (M10) and an alkylating agent-sensitive mutant (MS 1) isolated from mouse lymphoma L5178Y cells. The levels of CA induction in both mutants strictly corresponded to the sensitivity to lethal effects of mutagens, except that caffeine-induced CAs in M10 are considerably lower than those in L5178Y. The results clearly indicate that except for caffeine-induced CAs in M10, mutagen-induced lethal lesions are responsible for CA induction. In contrast, SCE induction in mutants was complicated. In M10, hypersensitive to killing by gamma-rays, methyl methanesulfonate (MMS), and 4-nitroquinoline 1-oxide (4NQO), but not sensitive to UV or caffeine, the frequency of SCEs induced by gamma-rays was barely higher than that in L5178Y, and the frequencies of MMS- and UV-induced SCEs were similar to those in L5178Y, but 4NQO- and caffeine-induced SCEs were markedly lower than those in L5178Y. MS 1, which is hypersensitive to MMS and caffeine, but not sensitive to UV or 4NQO, responded to caffeine with an enhanced frequency of SCEs and had a normal frequency of MMS-induced SCEs, but a reduced frequency of UV- and 4NQO-induced SCEs. Thus, susceptibility to SCE induction by mutagens is not necessarily correlated with sensitivity of mutants to cell killing and/or CA induction by mutagens. Furthermore, the spontaneous levels of SCEs are lower in M10 and higher in MS 1 than that in L5178Y (Tsuji et al., 1987). Based on these results, we speculate that M10 may be partially defective in the processes for the formation of SCEs caused by mutagens. On the other hand, MS 1 may modify SCE formation-related lesions induced by UV and 4NQO to some repair intermediates that do not cause SCE formation. In addition, MMS-induced lethal lesions in MS 1 may not be responsible for SCE induction whereas caffeine-induced lethal lesions are closely correlated with SCE induction. Thus, the lesions or mechanisms involved in SCE production are in part different from those responsible for cell lethality or CA production.     

The mutagenicity of 5-azacytidine and other inhibitors of replicative DNA synthesis in the L5178Y mouse lymphoma cell

The mutagenic potential of the cytidine analog, 5-azacytidine (Aza Cyd), was tested at the thymidine kinase (TK) gene locus of L5178Y mouse lymphoma cells. 3-h exposure to as little as 20 ng/ml Aza Cyd yielded a substantial increase in TK-deficient L5178Y cells as measured by drug-induced resistance to trifluorothymidine (TFTres) 48 h later. This mutagenic effect was diminished up to 75% when Aza Cyd was tested in the presence of either enzymatically active or heat-denatured 9000 X g supernatant prepared from rat liver homogenate. The mutagenicity of Aza Cyd was also decreased in the presence of 1-5 X 10(-3) M thymidine and eliminated in the presence of greater than 1 X 10(-5) M cytidine. Two L5178Y TK-deficient cell lines had no selective survival advantage compared to TK-competent L5178Y cell stock when plated in soft-agar medium that contained Aza Cyd. Four other specific inhibitors of scheduled DNA synthesis in mammalian cells, deoxyadenosine, aphidicolin, 1-beta-D-arabinofuranosylcytosine, and hydroxyurea were also L5178Y/TK mutagens. These data along with other published results suggest that chemicals known to disrupt nucleotide biosynthesis, alter deoxyribonucleotide pools, or directly inhibit DNA polymerase can cause stable, heritable increases in TFT resistance through mechanisms dependent upon altered replicative DNA synthesis, yet not necessarily dependent upon DNA incorporation or the binding of these mutagenic agents to nuclear DNA.     

Effect of UVC and araC on L5178Y-R and L5178Y-S cells. Nucleoid sedimentation

The effects of UVC radiation (lambda = 254 nm, 85 J/m2) and/or 1-beta-D-arabino-furanosylcytosine (araC, 2 x 10(-3) M, 2 h) on two mouse lymphoma cell lines, UVC-sensitive and X-ray resistant L5178Y-R and UVC-resistant and X-ray sensitive L5178Y-S, were investigated. AraC treatment inhibited the semiconservative DNA replication to 1.4% and 3.8% in L5178Y-R and L5178Y-S cells, respectively, and decreased the sedimentation distance of nucleoids from the cells of both lines. The shortening of sedimentation distances induced by UVC and araC treatment was 8.1 mm for L5178Y-R cells and 11.8 mm for L5178Y-S, and indicated a higher number of DNA breaks in L5178Y-S cells. Assuming that such breaks are the result of the inhibition of DNA repair replication by araC, we conclude that L5178Y-S cells have a greater number of repaired sites than L5178Y-R cells.     

Excision Repair of Uv Radiation-Induced DNA Damage in Caenorhabditis Elegans

Radioimmunoassays were used to monitor the removal of antibody-binding sites associated with the two major UV radiation-induced DNA photoproducts [cyclobutane dimers and (6-4) photoproducts]. Unlike with cultured human cells, where (6-4) photoproducts are removed more rapidly than cyclobutane dimers, the kinetics of repair were similar for both lesions. Repair capacity in wild type diminished throughout development. The radioimmunoassays were also employed to confirm the absence of photoreactivation in C. elegans. In addition, three radiation-sensitive mutants (rad-1, rad-2, rad-7) displayed normal repair capacities. An excision defect was much more pronounced in larvae than embryos in the fourth mutant tested (rad-3). This correlates with the hypersensitivity pattern of this mutant and suggests that DNA repair may be developmentally regulated in C. elegans. The mechanism of DNA repair in C. elegans as well as the relationship between the repair of specific photoproducts and UV radiation sensitivity during development are discussed.     

Cytogenetic analysis of an immunogenic mutant of the L5178Y lymphoma

A mutant of the uniformly lethal L5178Y lymphoma, called the L5178Y/Manitoba (L5178Y/M), was rejected after subcutaneous challenge in syngeneic DBA/2 mice. Karyotypic analysis revealed that the parent L5178Y lymphoma had four chromosome markers, with the mutant L5178Y/M sharing one of them as well as possessing two distinguishing markers. One diploid and two hypotetraploid clones were isolated from the L5178Y/M; they contained all the marker chromosomes and were also rejected by the syngeneic host. In addition to the shared chromosome markers, the L5178Y/M possessed antigens in common with the parent L5278Y. DBA/2 mice made immune to the mutant by subcutaneous immunization were able to slow the growth of the parent tumor but not the unrelated P-815-X2 mastocytoma.     

Characterization of the genotoxicity of anthraquinones in mammalian cells.

Naturally occurring 1,8-dihydroxyanthraquinones are under consideration as possible carcinogens. Here we wanted to elucidate a possible mechanism of their genotoxicity. All three tested anthraquinones, emodin, aloe-emodin, and danthron, showed capabilities to inhibit the non-covalent binding of bisbenzimide Hoechst 33342 to isolated DNA and in mouse lymphoma L5178Y cells comparable to the topoisomerase II inhibitor and intercalator m-amsacrine. In a cell-free decatenation assay, emodin exerted a stronger, danthron a similar and aloe-emodin a weaker inhibition of topoisomerase II activity than m-amsacrine. Analysis of the chromosomal extent of DNA damage induced by these anthraquinones was performed in mouse lymphoma L5178Y cells. Anthraquinone-induced mutant cell clones showed similar chromosomal lesions when compared to the topoisomerase II inhibitors etoposide and m-amsacrine, but were different from mutants induced by the DNA alkylator ethyl methanesulfonate. These data support the idea that inhibition of the catalytic activity of topoisomerase II contributes to anthraquinone-induced genotoxicity and mutagenicity.     

Increased resistance of the radiosensitive M10 mutant cells of the L5178Y mouse lymphoma cell line to heat-induced apoptosis.

M10 cells, which are deficient in the repair of DNA DSBs and are therefore radiosensitive, are about twofold more thermoresistant than their parental L5178Y cells. We found that, after heat shock at 43 degrees C under conditions resulting in 10% survival (D(10)), M10 cells did not undergo apoptosis, whereas L5178Y cells did undergo apoptosis. M10 cells, but not L5178Y cells, constitutively expressed Hsp72 protein. Moreover, the M10 cells accumulated higher amounts of the heat-inducible form of Hsp72. The patterns of activation of the DNA-binding activity of HSF (heat-shock factor) differed in M10 and L5178Y cells. In response to heat shock, M10 cells accumulated greater amounts of Trp53 protein (formerly known as p53) than the parental cells. Cdkn1a (formerly known as p21, Waf1) was constitutively expressed and further accumulated after heat shock only in M10 cells. We suggest that heat-inducible Hsp72 to a larger extent, and constitutive Hsp72 to a lesser extent, together with Cdkn1a may be involved in the protection of M10 cells against heat-induced apoptosis. Apoptosis in these cells is likely to occur in Trp53-dependent manner.