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

Genomic Instability Evolutionary Footprints on Human Health: Driving Forces or Side Effects?

In this work, we propose a comprehensive perspective on genomic instability comprising not only the accumulation of mutations but also telomeric shortening, epigenetic alterations and other mechanisms that could contribute to genomic information conservation or corruption. First, we present mechanisms playing a role in genomic instability across the kingdoms of life. Then, we explore the impact of genomic instability on the human being across its evolutionary history and on present-day human health, with a particular focus on aging and complex disorders. Finally, we discuss the role of non-coding RNAs, highlighting future approaches for a better living and an expanded healthy lifespan.

Screening of biomarker genes activated by irradiation of ultraviolet B rays in mouse lymph node M10 cells

When M10 cells derived from mouse lymph nodes were irradiated with the UVB lamp at a peak emission of 312 nm, the cell growth was suppressed in proportion to irradiation time (10-30 s) and cell apoptosis was also induced by the irradiation. Dynamic changes in 597 genes after exposing these cells to UVB irradiation were investigated by DNA array analysis using array membranes and a (33)P-labeling probe. After 2 h of irradiation, the gene expression in the cells was examined and compared with that in untreated cells. Radioactivity was analyzed using Array Gauge software. The data were further processed using software, EX-ARRAY, which was developed for extracting significant data from the results of 2 background-subtraction methods, i.e., global and local background subtraction. The number of genes suppressed under UV irradiation increased with irradiation time, while that of activated genes decreased. Finally, we confirmed 4 genes (HMG-14, CDX-2, MCP-3, and GRP-78) to be up-regulated and confirmed their activation by northern blot. We propose these genes as the new biomarkers of lymphocyte sensitive to UVB irradiation.

Different contributions of the indirect effects of gamma-rays on the cytotoxicity in M10 and XRCC4 transfected M10 cells

The protective effects of dimethyl sulfoxide (DMSO) against cell killing by (137)Cs gamma-rays were investigated in XRCC4-deficient cell line M10, XRCC4-complemented M10 and the parental mouse leukemia cell line L5178Y. Cell survival was determined by the colony-forming ability. M10 cells were more sensitive to gamma-ray-induced cell death than L5178Y and complemented M10 cells. Cell survival was increased in both M10 and L5178Y in the presence of DMSO. However, estimation of the DMSO-protectable fraction revealed a smaller protectable fraction for M10 cells than for L5178Y cells, indicating that indirect effects contributed in a smaller extent to the cytotoxicity in M10 than that in L5178Y. This effect is due to XRCC4 deficiency, since transfection of XRCC4 cDNA into M10 cells restored the radioprotective effects of DMSO to the level seen in L5178Y. In M10 cells, the killing effects of high LET radiation (Auger electrons from (125)I-antipyrine, carbon ions with an LET of 166 keV microm(-1)) were similar to those of low LET radiation ((137)Cs gamma-rays, characteristic X-rays from (125)I-bovine serum albumin). We discuss that lethal lesions produced by indirect actions in L5178Y and XRCC4-complemented M10 cells may differ, at least in part, from DNA double-strand breaks repairable by non-homologous end joining.

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.

A Chinese hamster ovary cell line hypersensitive to ionizing radiation and deficient in repair replication

An X-ray-sensitive Chinese hamster ovary cell line was isolated by means of a semi-automated procedure in which mutagenized cells formed colonies on top of agar, were X-irradiated, and were photographed at two later times. We compared the photographs to identify colonies that displayed significant growth arrest. One of the colonies identified in this manner produced a stable line (irs1SF) that is hypersensitive to ionizing radiation. The X-ray dose at which 10% of the population survives (D10) is 2.25 Gy for irs1SF and 5.45 Gy for the parental line. The new mutant is also moderately sensitive to ethyl methanesulfonate. irs1SF performs only half as much X-ray-induced repair replication as the parental line, indicating a defect in excision repair. This defect is believed to be the primary cause of the line's radiosensitivity. Although irs1SF repairs DNA double-strand breaks at a normal rate, it repairs single-strand breaks more slowly than normal. irs1SF has an elevated number of spontaneous chromatid aberrations and produces significantly higher numbers of X-ray-induced chromatid aberrations after exposure during the G1 phase of the cell cycle. The line is hypomutable, with X-ray exposure inducing only one-third as many 6-thioguanine-resistant colonies as the parental line.

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.

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.

Toxicity and mutagenicity of low dose rates of ionizing radiation from tritiated water in human lymphoblastoid cells

In order to study the toxic and mutagenic effects of low-dose-rate exposure to ionizing radiation, human lymphoblast cells were grown continuously in tritiated water (3H2O) for up to 8 days. Dose rates ranged from 0.0054 to 0.064 rad/min. Mutation to trifluorothymidine resistance (TK locus) and 6-thioguanine resistance (HGPRT locus) was measured; comparable results were observed at both loci. The mutant fraction as a function of total absorbed dose was independent of dose rate over the range studied. At the lower doses, the dose-response curve was linear, with no indication of a threshold. Overall, it appeared to be slightly biphasic with a diminished slope at higher total doses. These data are discussed in relation to earlier studies utilizing high-dose-rate X-irradiation and incorporated [3H]TdR; 3H2O and [3H]TdR were more mutagenic per rad than X-rays, but 3H2O was less cytotoxic than either X-rays or [3H]TdR.

The use of a cloned bacterial gene to study mutation in mammalian cells

The recombinant DNA molecule pSV2-gpt, which contains the bacterial gene coding for xanthine-guanine phosphoribosyl transferase (XGPRT) activity, was introduced into a hamster cell line lacking the equivalent mammalian enzyme (HGPRT). Hamster cell sublines were found with stable expression of XGPRT activity and were used to study mutation of the integrated pSV2-gpt DNA sequence. Mutants were selected by their resistance to 6-thioguanine (TG) under optimal conditions which were found to be very similar to those for selection of HGPRT-deficient mutants of mammalian cells. The frequency of XGPRT-deficient mutants was increased by treatment with X-rays, ethyl methanesulphonate and ethyl nitrosourea. X-Ray induction of mutants increased approximately linearly with dose up to about 500 rad, but the frequency of mutants per rad was very much higher than that usually found for 'native' mammalian genes. However, still higher frequencies of mutation were found for the hamster HGPRT gene when it had been stably transferred into the same hamster cell line. It is suggested, therefore, that transferred DNA may integrate in sequences which are more 'reactive' than most of the genome. Cell-free extracts of 10 TG-resistant mutants of XGPRT-proficient sublines showed no measurable XGPRT activity. High molecular weight DNA from XGPRT-proficient sublines used in the mutation studies hybridized with nick-translated pSV2-gpt DNA, showing two distinct bands when cut with the restriction enzyme Eco R1. This suggests that a single copy of pSV2-gpt DNA was integrated in these sublines. DNA from most spontaneous and mutagen-induced TG-resistant mutants had lost these two hybridizing bands, but one spontaneous mutant was found with rearranged pSV2-gpt sequence.

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.

Inhibition and recovery of DNA synthesis after X-irradiation in radiosensitive mouse-cell mutants

The mouse lymphoma L5178Y cell line and its radiosensitive variants M10 and LX830 were examined for DNA synthesis after X-irradiation. The dose-response curves show that the rates of DNA synthesis immediately after exposure are reduced in a dose-dependent fashion and that the extents of reduction in these 3 cell lines are similar to one another. But a difference was observed in the recovery of DNA synthesis with time of incubation. The recovered levels in M10 and LX830 cells were much higher than those in L5178Y cells at high doses of X-rays. These results are discussed in relation to radioresistant DNA synthesis in ataxia telangiectasia 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.

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.

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.