A novel mutant of mouse lymphoma cells sensitive to alkylating agents and caffeine

The mammalian XRCC genes: their roles in DNA repair and genetic stability

Analysis of the XRCC genes has played an important part in understanding mammalian DNA repair processes, especially those involved in double-strand break (DSB) repair. Most of these genes were identified through their ability to correct DNA damage hypersensitivity in rodent cell lines, and they represent components of several different repair pathways including base-excision repair, non-homologous end joining, and homologous recombination. We document the phenotypic effects of mutation of the XRCC genes, and the current state of our knowledge of their functions. In addition to their continuing importance in discovering mechanisms of DNA repair, analysis of the XRCC genes is making a substantial contribution to the understanding of specific human disorders, including cancer.

The genetic basis of resistance to ionising radiation damage in cultured mammalian cells

To test the genetic similarity of independently-isolated hamster cell mutants sensitive to ionising radiation, these were fused in pairs and the hybrids exposed to X-rays. Some mutants (irs1, irs3, xrs-1, XR-1, BLM2) were found to complement all others tested for radiosensitivity in hybrids, and are therefore in separate genetic groups. The mutants irs2 and V-E5, both isolated from V79 cells, did not complement and therefore belong to the same group. Another pair, EM7 and irs1SF, formed hybrids with intermediate levels of survival between mutant and wild-type. However, the parental cells fused to irs1SF also showed intermediate sensitivity, suggesting a semi-dominant mutant phenotype rather than a lack of complementation. Crosses of some of these hamster mutants to the radiosensitive mouse mutant M10 showed clear complementation (irs1 x M10, irs2 x M10) but for others the complementation did not greatly exceed the sensitivity of one (irs3 x M10) or both mutants (XR-1 x M10). Taken with our previously-published data, these results show that there are at least 8 genetic groups determining resistance to ionising radiation damage in rodent cells.

Cell fusion-mediated improvement in transfection competence for repair-deficient mutant of mouse T cell line

A multiple mutagen-sensitive mutant (XUM1) of mouse T-cell lymphoma line, L5178Y, is hypersensitive to ionizing radiation, ultraviolet (UV) light, and cross-linking agents (such as mitomycin C). The frequency of transfection for XUM1 cells after exposure to calcium phosphate-coprecipitated pSV2neo DNA was more than 10(4)-fold less effective than that for Ltk-aprt- (LTA) cells. Other transfection methods (DEAE-dextran and polybrene-DMSO) were not effective for L5178Y and XUM1 cells. The transfection-proficient trait of LTA cells was demonstrated to be genetically dominant by examining the the transfection frequency in hybrid clones constructed between XUM1 and LTA cells. To circumvent the problem with XUM1, the LTA genes necessary for transformation processes were introduced into XUM1 cells by constructing hybrids between XUM1 and LTA cells irradiated with X-rays which causes directional chromosome elimination for hybrid cells. Four of 194 hybrid clones tested were transfection-proficient and hypersensitive to UV (XL102, XL107, XL215, and XL216). All four clones were not hypersensitive to X-rays or mitomycin C. The frequencies of transfection for XL102 and XL216 were nearly the same level as that for LTA cells. The efficiency of transfection for XL107 and XL215 was 10 to 100-fold lower than that for LTA cells.

Mutagen detection with a mouse line containing 3 distinct mutations conferring sensitivity

A mouse-cell mutant sensitive to methyl methanesulfonate (MMS), X-rays, ultraviolet light (UV), and crosslinking agents was selected using the replica plating and cell suspension spotting methods. This mutant (XUM1) is a mitomycin C-sensitive derivative of previously reported XU1, a mutant sensitive to MMS, X-rays and UV. Since XU1 is highly susceptible to the lethal effect of 4-nitroquinoline-1-oxide (4NQO), XUM1 is also hypersensitive to 4NQO. Growth inhibition area tests showed that low concentrations of mutagens were detected with the multiple mutagen-sensitive mutant XUM1. Hence XUM1 cells will be useful in detecting with high sensitivity a wide range of mutagens and carcinogens which mimic X-rays, UV and crosslinking agents.

Mutagen-sensitive cell lines are obtained with a high frequency in V79 Chinese hamster cells

A replica-plating technique has been adopted for the isolation of mutagen-sensitive mutants of Chinese hamster V79 and CHO cell lines. After the mutagenic treatment (ENU) clones derived from these cell lines were replica plated into micro wells and replicas were treated with UV (254 nm), X-ray, MMC, EMC or MMS. Clonal cell lines which demonstrated mutagen sensitivity were retested by the determination of survival. Only one UV-sensitive line was obtained in 1500 clonal lines derived from CHO cells. This mutant appeared also sensitive to 4NQO and MMC. The sensitivity to UV and MMC was 2-3-fold enhanced, while the increase in sensitivity to 4NQO was 4-5-fold. In V79 cells 9 mutagen-sensitive lines were found after screening of 500 clonal lines; six of them showed increased sensitivity towards UV, two towards MMC, and one cell line was found to be X-ray sensitive. A considerable cross-sensitivity for the various agents was found among the isolated mutants. When a 2-fold increase is taken as a minimum to indicate mutagen sensitivity 6 mutants were sensitive to UV, 8 mutants were sensitive to MMC, 6 mutants were sensitive to 4NQO and 4 mutants were sensitive to X-rays. The difference in sensitivity to UV versus 4NQO makes it unlikely that 4NQO can be considered as a UV-mimetic agent. The sensitivity to MMC appears to fall into 2 classes: a class with moderate sensitivity (2-8-fold) and a class with high sensitivity (30-100-fold). The presence of similar classes is indicated for UV. Except for the two lines V-E5, V-B7 and the two lines V-H11, V-H4 all obtained mutants have a different spectrum of mutagen sensitivities which suggests that different genetic alterations underly these effects. The observed high frequency of mutagen-sensitive mutants in V79 cells, although unexpected and substantially higher than those published for CHO cells and L5178Y cells, can still be explained by the presence of functionally hemizygous loci.

Chromosomal instability in mutagen-sensitive mutants isolated from mouse lymphoma L5178Y cells. I. Five different genes participate in the formation of baseline sister-chromatid exchanges and spontaneous chromosomal aberrations

In a search for cell mutants that show an increase or a decrease in the frequency of baseline sister-chromatid exchanges (SCEs) or spontaneous chromosomal aberrations (CAs), large numbers of mutagen-sensitive clones previously isolated from mouse lymphoma L5178Y cells were analyzed. In addition to two SCE mutants (ES 4 and AC 12) previously reported, three other mutants were identified as an SCE mutant. An ethyl methanesulfonate-sensitive mutant ES 2 and an alkylating agent-sensitive mutant MS 1 exhibited, respectively, 1.4-fold and 1.8-fold higher baseline SCE frequencies than did the parental L5178Y. In contrast, M10, which is sensitive to X-ray and 4-nitroquinoline 1-oxide, showed a reduced frequency of baseline SCEs (0.65-fold). These 5 mutants including ES 4 and AC 12 had 3--9-fold increases in spontaneous CA frequencies. Measurement of baseline SCE formation in inter-mutant hybrids revealed that M10 mutation is dominant, MS 1 and ES 4 mutations are semidominant, and ES 2 and AC 12 mutations are recessive. Because SCE frequencies in hybrids formed between pairs of 4 mutants (ES 2, MS 1, ES 4 and AC 12) were significantly lower than those in the tetraploid mutant cells, these 4 mutants probably belong to different complementation groups. Since M10 behaved dominantly with respect to SCE phenotype, it was not possible to determine by complementation test whether it belongs to a different group from the other mutants. However, the finding that M10 is complemented by other mutants for EMS sensitivity indicates that the M10 mutation is different from the other mutations. From these results, it is concluded that at least 4 different genes participate in the formation of high levels of baseline SCEs. The defects in ES 2, MS 1, ES 4, and AC 12 produce common lesions responsible for the formation of both SCEs and CAs. In contrast, the defect in M10 is associated with a high increase in spontaneous CA frequency, but conversely associated with a decrease in baseline SCE frequency. This suggests that M10 is defective in the process involved in the formation of baseline SCEs.

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.

Isolation and cross-sensitivity of X-ray-sensitive mutants of V79-4 hamster cells

The V79-4 Chinese hamster line was mutagenized and surviving clones screened for X-ray sensitivity using a replica microwell technique. One slightly sensitive clone and 3 clearly sensitive clones were isolated from approximately 5000 screened, and designated irs 1 to irs 4. The 3 more sensitive clones showed different responses to the genotoxic agents mitomycin C (MMC), ethyl methanesulphonate (EMS) and ultraviolet light (UV). irs 1 showed considerable sensitivity to all the agents tested, in the order MMC much greater than EMS greater than UV. irs 2 and irs 3 had similar sensitivities to EMS and to UV (EMS greater than UV) but irs 3 was more sensitive than irs 2 to MMC. None of these mutants is identical in phenotype to previously published mutants.

Genetic analysis of mitomycin-C-sensitive mutants of a Chinese hamster ovary cell line

5 mutants of a Chinese hamster ovary (CHO) cell line, which exhibit similar levels of sensitivity to killing by mitomycin C, have been analysed genetically to determine whether they represent one or more genetic complementation groups. Hybrids were constructed by fusing cells carrying either the neo or the Ecogpt marker and selecting in medium containing G418 and mycophenolic acid. Selectable markers were introduced into the cells by DNA transfection using pSV5-neo or pSV5-gpt, which represents a quick and convenient method for generating resistant derivatives. Hybrids generated by crosses between any one mutant and the parental cell line exhibited near wild-type resistance to mitomycin C, indicating that the mutants are phenotypically recessive. Self-cross hybrids for all 5 mutants had D37 values for killing by mitomycin C of between 20 and 30 ng/ml. The values obtained for crosses between different mutants were 60-105 ng/ml, with the exception of 1 pairing which gave a value of 33 ng/ml. These results indicate that that the mutants represent at least 4 different genetic complementation groups, suggesting that cellular resistance to mitomycin C is mediated via a number of different mechanisms.

Analysis of repair processes by the determination of the induction of cell killing and mutations in two repair-deficient Chinese hamster ovary cell lines

Two UV sensitive DNA-repair-deficient mutants of Chinese hamster ovary cells (43-3B and 27-1) have been characterized. The sensitivity of these mutants to a broad spectrum of DNA-damaging agents: UV254nm, 4-nitroquinoline-1-oxide (4NQO), X-rays, bleomycin, ethylnitrosourea (ENU), ethyl methanesulphonate (EMS), methyl methanesulphonate (MMS) and mitomycin C (MMC) has been determined. Both mutants were not sensitive to X-rays and bleomycin. 43-3B was found to be sensitive to 4NQO, MMC and slightly sensitive to alkylating agents. 27-1 was sensitive only to alkylating agents. The results suggest the existence of two repair pathways for UV-induced cytotoxicity: one pathway which is also used for the removal of 4NQO and MMC adducts and a second pathway which is also used for the removal of alkyl adducts. Parallel to the toxicity, the induction of mutations at the HPRT and Na+/K+-ATPase loci was determined. The increased cytotoxicity to UV, MMC and 4NQO in 43-3B cells and the increased cytotoxicity to UV in 27-1 cells correlated with increased mutability. It was observed that the increase in mutation induction at the HPRT locus was higher than that at the Na+/K+-ATPase locus. As only point mutations give rise to viable mutants at the Na+/K+-ATPase locus the lower mutability at this locus suggests that defective excision repair increases the chance for deletions. Despite an increased cytotoxicity to ENU in 27-1 cells the mutation induction by ENU was the same in 27-1 and wild-type cells at both loci, which suggests that the mutations are mainly induced by directly miscoding adducts (e.g. O-6 alkylguanine), which cannot be removed by CHO cells. As EMS and MMS treatment of 27-1 cells caused an increase in mutation induction at the HPRT locus and a decrease at the Na+/K+-ATPase locus it indicates that these agents induce a substantial fraction of other mutagenic lesions, which can be repaired by wild-type cells. This suggests that O-6 alkylation is not the only mutagenic lesion after treatment with alkylating agents.

Sensitivity to DNA-damaging agents and mutation induction by UV light in UV-sensitive CHO cells

Three UV-sensitive (UVs) mutants isolated from a CHO cell line were analyzed for survival after exposure to H2O2, EMS, MMC, CCNU, X-rays and for mutation induction after UV-irradiation. The UVs mutants showed normal sensitivities to EMS and H2O2, whereas they were hypersensitive to the bifunctional alkylating agents MMC and CCNU and to hypoxic X-irradiation. Compared to parental cells, one of the UV-sensitive clones showed approximately 3- and 7-fold enhancement in the mutagenic response per unit UV dose for 6-thioguanine and ouabain resistance, respectively.

UV-induced mutagenesis at the hypoxanthine-guanine phosphoribosyl transferase locus in two L5178Y mouse lymphoma cell strains with different UV sensitivities

Two strains of L5178Y mouse lymphoma cells, L5178Y-R (LY-R) and L5178Y-S (LY-S), differ markedly in their sensitivity to 254 nm UV radiation (D0 = 0.7 and 5.5 J/m2; n = 6.0 and 2.0 for LY-R and LY-S cells, respectively). In this study, the frequency of hypoxanthine-guanine-phosphoribosyl-transferase-deficient mutants was determined, using 6-thioguanine (TG) as a selective agent, in populations of LY-R and LY-S cells exposed to various fluences of UV radiation. The spontaneous mutation frequency for LY-R cells was (3.7 +/- 0.6) X 10(-5) TGr mutants per viable cell, and the UV induction rate was (2.2 +/- 0.8) X 10(-4) TGr mutants per viable cell, per J/m2. Both spontaneous and induced mutation frequencies were much lower for LY-S cells. The spontaneous mutation frequency for these cells were too low to make its measurement practicable (less than 0.0013 X 10(-5) TGr mutants per viable cell). Mutation induction rate was (4.2 +/- 2.2) X 10(-7) TGr mutants per viable cell, per J/m2. These differences in mutability do not appear to be due to gene duplication in LY-S cells, or to selective growth disadvantage of LY-S-derived TG-resistant mutants. Possible mechanisms underlying the differences in mutability of LY-R and LY-S cells are considered.

X-ray-sensitive mutants of Chinese hamster ovary cell line. Isolation and cross-sensitivity to other DNA-damaging agents

A standard technique of microbial genetics, which involves the transfer of cells from single colonies by means of sterile toothpicks, has been adapted to somatic cell genetics. Its use has been demonstrated in the isolation of X-ray-sensitive mutants of CHO cells. 9000 colonies have been tested and 6 appreciably X-ray-sensitive mutants were isolated. (D10 values 5-10-fold of wild-type D10 value.) A further 6 mutants were obtained which showed a slight level of sensitivity (D10 values less than 2-fold of wild-type D10 value). The 6 more sensitive mutants were also sensitive to bleomycin, a chemotherapeutic agent inducing X-ray-like damage. Cross-sensitivity to UV-irradiation and treatment with the alkylating agents, MMS, EMS and MNNG, was investigated for these mutants. Some sensitivity to these other agents was observed, but in all cases it was less severe than the level of sensitivity to X-irradiation. Each mutant showed a different overall response to the spectrum of agents examined and these appear to represent new mutant phenotypes derived from cultured mammalian cell lines. One mutant strain, xrs-7, was cross-sensitive to all the DNA-damaging agents, but was proficient in the repair of single-strand breaks.

X-ray-sensitive mutant mouse cells with various sensitivities to chemical mutagens

Three X-ray-sensitive mutants (LX821, LX827 and LX830) have been isolated from mouse-lymphoma L5178Y cells. These mutants are much more sensitive to the lethal effects of ionizing radiation than the parental L5178Y cells but are as resistant to ultraviolet radiation as L5178Y cells. We have previously isolated a mutant M10 that is sensitive to methyl methanesulfonate (MMS) and cross sensitive to ionizing radiation and 4-nitroquinoline 1-oxide (4NQO). Unlike M10 cells, newly isolated mutants were not sensitive to MMS and were less sensitive to 4NQO. These results indicate that new mutants may be deficient in the repair of DNA damage specific to ionizing radiation. LX821 and LX827 cells were concomitantly resistant to 5-bromodeoxyuridine, whereas LX830 cells were not.

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.

Isolation and characterization of mitomycin-C-sensitive mouse lymphoma cell mutants

26 mutants with increased sensitivity to the lethal effects of mitomycin C (MMC) were isolated from mouse lymphoma L5178Y cells by a replica-plating technique. Most of them were about 5-10 times more sensitive in terms of D37 values to MMC than were parental cells. 5 of the MMC-sensitive mutants isolated from independently mutagenized cell populations were further analyzed. They were highly sensitive to the killing by decarbamoyl (DC) MMC, a monofunctional derivative of MMC, but were not sensitive to ultraviolet radiation, X-rays, 4-nitroquinoline-1-oxide or methyl methanesulfonate. These 5 mutants were classified into at least 2 genetic complementation groups. The implication of these mutations in cross-link and mono-adduct repair of DNA damage induced by MMC and DCMMC is discussed.

Multiple hypersensitivity to mutagens in a cell strain (46BR) derived from a patient with immuno-deficiencies

46BR is a fibroblast cell strain established from an individual with hypogammaglobulinaemia. The cells are unique in showing hypersensitivity to the lethal effects of a wide range of DNA-damaging agents. Thus they are hypersensitive to gamma- and 254-nm UV-irradiation and show a limited capacity to repair potentially lethal gamma-irradiation damage when compared with fibroblasts from normal individuals. A slight hypersensitivity to mitomycin C was also revealed but we were not able to discriminate 46BR from normals with 4-nitroquinoline oxide. The cells were hypersensitive to the alkylating agents, dimethyl sulphate, methyl methanesulphonate, ethyl methanesulphonate, N-methyl-N'-nitro-N-nitrosoguanidine and N-methyl-N-nitrosourea but not N-ethyl-N-nitrosourea. A consideration of the spectra of DNA lesions produced by these alkylating agents together with the sensitivity to ionising radiation and mitomycin C suggests that 46BR cells are defective in a repair step that is common to all agents. We suggest that the cells are defective in DNA polymerisation or ligation. Support for this suggestion comes from the absence of any hypersensitivity to N-ethyl-N-nitrosourea since its major reaction products are not removed by excision pathways that require polymerisation and ligation.

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.

Isolation of UV-sensitive mutants of mouse L5178Y cells by a cell suspension spotting method

We have isolated 56 UV-sensitive mutant clones from a mouse L51 T/t line of L5178Y cells by a cell suspension spotting method. Five mutants have also been isolated from L51 T/t and L5178Y cells by the method reported by Thompson and coworkers (22). We divided the mutants into two groups, "highly sensitive" and "moderately sensitive" mutants, according to their sensitivity to UV irradiation. Fifty-eight mutants were highly sensitive and three were moderately sensitive to UV. The reconstruction experiments indicate that more than 90% of highly sensitive mutants were recovered by the cell suspension spotting method. Frequencies of recovered mutants highly sensitive to UV increased with increasing dose of mutagens. Recovered mutant frequency reached 10(-2) after treatment with 1.5 micrograms/ml of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) (survival 0.2%). Eight UV-sensitive mutants were divided into four complementation groups. These mutants were 2-6 times more sensitive to UV than parental L51 T/t cells in terms of D37 (dose required to reduce survival to 37%). Four representative UV-sensitive mutants which are classified into different complementation groups were examined for their sensitivity to killing by UV, 4-nitroquinoline-1-oxide (4NQO), mitomycin C (MMC), X-rays, and MNNG. All four classes of mutants were found to be cross-sensitive to UV, 4NQO, and MMC, but not sensitive to X-rays and MNNG.