Koki Sato

Isolation and Characterization of a Mutant Mouse Lymphoma Cell Sensitive to Methyl Methanesulfonate and X Rays

A methyl methanesulfonate-sensitive strain has been isolated from L5178Y mouse lymphoma cells. This mutant, M10, is more sensitive to killing by X rays than the parent wild-type strain. This sensitivity to the alkylating agent and ionizing radiation has not changed for 11 months since the isolation of the mutant. The plating efficiency, doubling time, and sensitivity to ultraviolet light of M10 cells are not appreciably different from those of the wild-type cells.

MURINE CELL LINE SX9 BEARING A MUTATION IN THE DNA-PKCS GENE EXHIBITS ABERRANT V(D)J RECOMBINATION NOT ONLY IN THE CODING JOINT BUT ALSO IN THE SIGNAL JOINT

We established the radiosensitive cell line SX9 from mammary carcinoma cell line FM3A. In SX9 cells a defect of DNA-dependent protein kinase (DNA-PK) activity was suggested. Additionally, a complementation test suggested that the SX9 cell line belongs to a x-ray cross-complementing group (XRCC) 7. Isolation and sequence analyses of DNA-dependent protein kinase catalytic subunit (dna-pkcs) cDNA in SX9 cells disclosed nucleotide “T” (9572) to “C” transition causing substitution of amino acid residue leucine (3191) to proline. Interestingly, the mutation occurs in one allele, and transcripts of the dna-pkcs expressed exclusively from mutated allele. V(D)J recombination assay using extrachromosomal vector revealed the defects of not only coding but also signal joint formation. The frequency of the signal joint decreased to approximately one-tenth and the fidelity drastically decreased to 12.2% as compared with the normal cell line. To confirm the responsibility of thedna-pkcs gene for abnormal V(D)J recombination in SX9, the full-length dna-pkcs gene was introduced into SX9. As a result, restoration of V(D)J recombination by wild typedna-pkcs cDNA was observed. SX9 is a noveldna-pkcs-deficient cell line.

Identification of nucleotide-excision-repair genes on human chromosomes 2 and 13 by functional complementation in hamster-human hybrids

The CHO UV-sensitive mutants UV24 and UV135 (complementation groups 3 and 5, respectively) are defective in nucleotide excision repair. After fusing each mutant with human lymphocytes, resistant hybrid clones showing genetic complementation were isolated by repeated exposure to UV radiation. Using a combination of isozyme markers, DNA probes,and cytogenetic methods to analyze the primary hybrids and their subclones, correction of the repair defect was shown to be correlated with the presence of a specific human chromosome in each case. Chromosome 2 corrected UV24, and the gene responsible was designated ERCC3.Line UV135 was corrected by human chromosome 13 and the gene designated ERCC5.The UV-sensitive mouse cell line, Q31, was shown not to complement UV135 and thus appears to be mutated in the same genetic locus (homologous to ERCC5)as UV135. Breakage of complementing chromosomes with retention of the genes correcting repair defects allowed the following provisional assignments: regional localization of ERCC5to 13q14-q34, exclusion of ERCC3from the region of chromosome 2 distal to p23, and relief of the ambiguity of ACPlassignment (2p23 or 2p25) to 2p23 proximal to MDH1.

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.

Isolation of UV-sensitive variants of human FL cells by a viral suicide method

A new method (viral suicide method) for the isolation of UV-sensitive mutants is described. Colonies of mutagenized human FL cells were infected with UV-irradiated Herpes simplex viruses and surviving ones which seemed to be deficient in host cell reactivation (HCR) were examined for their UV sensitivity. Nineteen of 238 clones examined were sensitive to UV irradiation at the time of the isolation. After recloning, four of these clones have been studied and two (UVS-1 and UVS-2) of them are stable in their UV sensitivity for 4 months in culture. UV sensitivity of UVS-1, UVS-2, and the parental FL cells are as follows: the extrapolation numbers (n) are 2.2, 2.1, and 1.8 and mean lethal doses (D0) are 2.9, 3.7, and 7.8 J/m2 for UVS-1, UVS-2, and the parental FL cells, respectively. They are no more sensitive than FL cells to X- irradiation. The ability of HCR in UVS-2 cells is apparently lower than that in FL cells, whereas UVS-1 cells are the same as FL cells in the ability.

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 μg/ml ofN-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.

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.

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

Two-methyl-methanesulfonate-sensitive strains have been isolated, one of which, M10, was cross-sensitive to X-rays as reported before. Sensitivities of parental L5178Y, M10, and newly isolated MS-1 cells to various mutagens were examined. Mutagens tested were UV, X-rays, 4-nitroquinoline 1-oxide (4NQO), caffeine and alkylating agents; methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS) and mitomycin C (MMC). In terms of D37 values, M10 cells were 2.5-7 times more sensitive to EMS, MMC and 4NQO as well as to MMS and X-rays than were parental L5178Y cells, while the new mutant MS-1 was about 3 times more sensitive to MMS, EMS, MMC and caffeine than were parental cells. The characteristics in sensitivities of M10 cells to X-rays, alkylating agents and 4NQO resemble resemble some ataxia telangiectasia cells; and MS-1 cells to alkylating agents and caffeine are novel among mammalian cell mutants so far reported. Sensitivity of M10 cells to mutagens has so far been stable for one year, and that of MS-1 cells was stable for 6 months in continuous culture.

A mouse-cell mutant sensitive to ionizing radiation is hypermutable by low doses of γ-radiation

Abstract The mutant mouse lymphoma cell M10, which is sensitive to methyl methanesulfonate and ionizing radiation, was compared with the parental L5178Y cells for mutation induction after γ-irradiation. The rate of induced mutations to 6-thioganine resistance in L5178Y cells was 2−3 x 10 −7 per R, as determined after exposure ranging from 25 to 500 R. The induced mutation frequency per unit dose per locus in M10 cells was about 4 times higher than that in L5178Y cels at the lower doses of exposure (25–75 R), but it declined sharply at the higher doses of γ-rays (100–150 R). The rate of induced mutation per unit cell killing in M10 cells was nearly the same as that in L5178Y cells when they were compared at the levels of lower cell killing.

The role of DNA repair on cell killing by charged particles

It can be noted that it is not simple double strand breaks (dsb) but the non-reparable breaks that are associated with high biological effectiveness in the cell killing effect for high LET radiation. Here, we have examined the effectiveness of fast neutrons and low (initial energy = 12 MeV/u) or high (135 MeV/u) energy charged particles on cell death in 19 mammalian cell lines including radiosensitive mutants. Some of the radiosensitive lines were deficient in DNA dsb repair such as LX830, M10, V3, and L5178Y-S cells and showed lower values of relative biological effectiveness (RBE) for fast neutrons if compared with their parent cell lines. The other lines of human ataxia-telangiectasia fibroblasts, irs 1, irs 2, irs 3 and irs1SF cells, which were also radiosensitive but known as proficient in dsb repair, showed moderated RBEs. Dsb repair deficient mutants showed low RBE values for heavy ions. These experimental findings suggest that the DNA repair system does not play a major role against the attack of high linear energy transfer (LET) radiations. Therefore, we hypothesize that a main cause of cell death induced by high LET radiations is due to non-reparable dsb, which are produced at a higher rate compared to low LET radiations.