Analyses of differential sensitivities of synchronized HeLa S3 cells to radiations and chemical carcinogens during the cell cycle. Par V. Radiation- and chemical carcinogen-induced mutagenesis

Effect of Multiple Irradiation with Low Doses of Gamma-rays on Morphological Transformation and Growth Ability of Human Embryo Cellsin Vitro

We have measured expression of transformed phenotypes in human embryo (HE) cells repeatedly irradiated with a dose of 7.5 cGy per week throughout the life span of these cells in vitro. Irradiation was repeated until the cells had accumulated 195 cGy at which time the cells had reached the equivalent of their 26th passage and samples of cells at several passages were assayed for cell survival by colony formation, for mutation at hypoxanthine guanine phosphoribosyl transferase (HGPRT) locus and for transformation by focus formation. The lifespan (mean population doublings) of multiple irradiated cultures with a total dose of 97.5 cGy was slightly, but significantly, prolonged over that of controls. For example, if cells had accumulated 195 cGy, the maximum number of cell division of HE cells in vitro extended to 130-160% of non-irradiated control. Although transformed foci were not observed with cells until cells had accumulated 97.5 cGy, it increased with increasing accumulated dose. No cells, however, showed unlimited life span in vitro and also expressed tumorigenicity.

Cellular and molecular effects for mutation induction in normal human cells irradiated with accelerated neon ions

We investigated the linear energy transfer (LET) dependence of mutation induction on the hypoxanthine-guanine phosphoribosyl transferase (HPRT) locus in normal human fibroblast-like cells irradiated with accelerated neon-ion beams. The cells were irradiated with neon-ion beams at various LETs ranging from 63 to 335 keV/microm. Neon-ion beams were accelerated by the Riken Ring Cyclotron at the Institute of Physical and Chemical Research in Japan. Mutation induction at the HPRT locus was detected to measure 6-thioguanine-resistant clones. The mutation spectrum of the deletion pattern of exons of mutants was analyzed using the multiplex polymerase chain reaction (PCR). The dose-response curves increased steeply up to 0.5 Gy and leveled off or decreased between 0.5 and 1.0 Gy, compared to the response to (137)Cs gamma-rays. The mutation frequency increased up to 105 keV/microm and then there was a downward trend with increasing LET values. The deletion pattern of exons was non-specific. About 75-100% of the mutants produced using LETs ranging from 63 to 335 keV/mum showed all or partial deletions of exons, while among gamma-ray-induced mutants 30% showed no deletions, 30% partial deletions and 40% complete deletions. These results suggested that the dose-response curves of neon-ion-induced mutations were dependent upon LET values, but the deletion pattern of DNA was not.

Qualitative and quantitative difference in mutation induction between carbon- and neon-ion beams in normal human cells

We investigated the difference in cell-killing effect and mutation induction between carbon- and neon-ion beams in normal human cells. Carbon- and neon-ion beams were accelerated by the Riken Ring Cyclotron (RRC) at the Institute of Physical and Chemical Research in Japan. Cell-killing effect was measured as the reproductive cell death using the colony formation assay. Mutation induction at the HPRT locus was detected to measure 6-thioguanine-resistant clones. The mutation spectrum of the deletion pattern of exons of induced mutants was analyzed using the multiplex polymerase chain reaction (PCR). Cell-killing effect was almost the same between carbon- and neon-ion beams with similar linear energy transfer (LET) values, while there observed a large difference in mutation frequency. Furthermore, in the case of neon-ion beams 60% of mutants showed total deletions and 35-40% showed partial deletions, while 95-100% of carbon-ion induced mutants showed total deletions. The results suggest that different ion species may cause qualitative and quantitative difference in mutation induction even if the LET values are similar.

Cell cycle-dependent effects of wortmannin on radiation survival and mutation

Wortmannin, a known radiation sensitizer, has been used in experiments with synchronized cells to compare its effect on radiation survival and mutation induction within the cell cycle. PL61 cells (CHO cells with an inactivated HPRT gene containing a single active copy of a bacterial gpt gene) were synchronized by mitotic selection. Wortmannin administered before gamma irradiation caused a greater sensitization in G(1)-phase cells relative to late S/G(2)-phase cells. Preferential radiosensitization of G(1)-phase cells by wortmannin sets a limit to the proposed use of wortmannin in radiation therapy, since, in contrast to normal tissues, tumors usually have high proportions of S-phase cells. Wortmannin increased mutation frequencies in both G(1)- and S/G(2)-phase cells. Interestingly, relative increases in radiation-induced mutations in G(1) and S/G(2) phases were comparable. The results are discussed in terms of the contributions of different repair modes in the production of mutations.

Mutations induced in the HPRT gene by X-irradiation during G(1) or S: analysis of base pair alterations, small deletions, and splice errors

Reverse transcriptase PCR was performed with mRNA obtained from HPRT mutants that had base pair alterations, or small deletions or insertions <20bp. The frequencies of mutants yielding RT-PCR products (mRNA) were the same when human EJ30 cells were irradiated in G(1) or S (3-4-fold higher for 6 than 3Gy). However, the frequencies of mutants that did not yield RT-PCR products were approximately 10-fold higher in the cells irradiated in G(1) than in those irradiated in S. Sequence analysis of RT-PCR products and genomic DNA showed that 40% of the RT-PCR products had splice errors (one or more exons not spliced into mRNA), with 64% of them due to 1-17bp deletions. Also, the distributions of molecular alterations in exons, acceptor sites, and donor sites for mutants having splice errors (observed in this study and reported by others) were similar to those reported for mutants not yielding RT-PCR products (isolated from Russian cosmonauts). In addition, we have found previously that large deletions which eliminated 1-9 exons were preferentially induced in G(1). Therefore, we postulate that the preferential induction of mutants not yielding mRNA is due primarily to splice errors that result from deletions preferentially induced during G(1). These splice errors would then result either in no message or a message that is rapidly degraded.

LET dependence of cell death, mutation induction and chromatin damage in human cells irradiated with accelerated carbon ions

We investigated the LET dependence of cell death, mutation induction and chromatin break induction in human embryo (HE) cells irradiated by accelerated carbon-ion beams. The results showed that cell death, mutation induction and induction of non-rejoining chromatin breaks detected by the premature chromosome condensation (PCC) technique had the same LET dependence. Carbon ions of 110 to 124keV/micrometer were the most effective at all endpoints. However, the number of initially induced chromatin breaks was independent of LET. About 10 to 15 chromatin breaks per Gy per cell were induced in the LET range of 22 to 230 keV/micrometer. The deletion pattern of exons in the HPRT locus, analyzed by the polymerase chain reaction (PCR), was LET-specific. Almost all of the mutants induced by 124 keV/micrometer beams showed deletion of the entire gene, while all mutants induced by 230keV/micrometer carbon-ion beams showed no deletion. These results suggest that the difference in the density distribution of carbon-ion track and secondary electron with various LET is responsible for the LET dependency of biological effects.

Characterization of a mammalian cell line that exhibits spontaneous and ultraviolet light-induced hypermutability while retaining resistance to cell killing by ultraviolet light

Chronic exposure of V79 cells to 80 daily doses of 150 J/M2, 290-330-nm ultraviolet light (UVB) produced a mixed cell population that was found to be generally more resistant to cell killing by both UVB and UVC (254 nm) than the wild-type cells. Several subclones from this population were studied for their survival and mutation responses and then one was chosen for further characterization based on this data. The studies carried out on this subclone, designated N806, show that its spontaneous HPRT mutation rate is approximately 10 times higher than that of wild-type V79 cells and it is almost three times more mutable than the wild-type cells when both are induced by UVB or UVC. The mutation responses of N806 and MI2G cells to 50-kVp X-rays are different, but the N806 cells do not appear to be hypermutable as they are with UV. N806 cells are also moderately more resistant to the cytotoxic effects of UV radiation but are more sensitive than MI2G cells when exposed to X-rays. Assays to measure the removal of cyclobutane pyrimidine dimers (CPDs) and the incision step of nucleotide excision repair have revealed no detectable difference in the repair capacities of N806 and parental V79 cells. These results suggest that chronic, protracted UV irradiation may be able to induce a 'mutator phenotype' in a subpopulation of the progenitor cells.

Inhibition of erythroid differentiation in MEL cells by UV irradiation. Cell cycle and DNA repair activity

Irradiation with a 3-s pulse of 254 nm UV light has been used to study sensitivity to mutagenic agents of mouse erythroleukemia (MEL) cell cultures in correlation with the cell cycle. A dose of UV irradiation was chosen that had no consequences for cell viability and growth. For this reason phenotypic effects were monitored on the progeny of all cells of the irradiated cultures by scoring those unable to undergo erythroid differentiation upon induction with dimethyl sulfoxide. The very short period of irradiation made it possible to show that MEL cells, synchronized by two sequential blocks of deoxythymidine and one of hydroxyurea (HU), are sensitive to UV irradiation only in a very short period of time at about 60 min after release from HU block. Determinations of deoxythymidine incorporation into DNA show that this time period corresponds only marginally to the initial part of the S phase during which irradiation has no consequences for cell properties. Cells are not sensitive to UV irradiation in G1 and in G2/M unless, immediately after irradiation and for the following 2 h, cultures are treated with 1 mM HU to interfere with DNA repair. Alkaline sucrose gradient analyses show at all tested times that irradiation leads to fragmentation of cell DNA. The data suggest that an immediate increase of deoxythymidine incorporation into DNA following irradiation is not necessary for the efficient repair of damaged DNA. In fact, the percent of cells expressing the erythroid phenotype is normal in the progeny of cells irradiated in G2/M, when TdR incorporation is at a minimum. Repair activities appear then to be mechanistically divided into two phases, (1) recognition labeling of the altered sites and (2) reconstitution of the DNA sequences. The first activity appears to be operative at all phases of the cycle, the second activity is little or not operative in G2/M, possibly delayed to the following G1 period.

Selective gene mutation in MEL cells

MEL cells, undergoing erythroid differentiation and parasynchronized by dimethyl sulfoxide (DMSO) induction, were irradiated with a 3-s pulse of UV light at sublethal dose. A large number of clones deficient in different gene functions are found in the progeny of the treated cells, if the pulse irradiation is performed 18-24 h from the start of DMSO induction. Kinetics of thymidine incorporation into DNA show that the period of sensitivity corresponds to the S phase. The results show that the activities of the tested genes are differently affected depending on the exact time of cell irradiation. Maximum percent inhibition of cells not expressing glucose-6-phosphate dehydrogenase (G-6-PD) (70%) is produced by irradiating at 20 h from the start of DMSO induction; 6-phosphogluconate dehydrogenase (6-PGD) (55%), and hypoxanthine (guanine) phosphoribosyltransferase (HPRT) (33%), at 21 h; hemoglobin (50%), at 22 h. The time difference in the sensitivity to UV light is highly reproducible and has been exploited to isolate, with high efficiency, cellular clones deficient in any one of the tested functions. Determinations of enzymatic activities on cell lysates show that the expression of tested genes is actually altered in cells that, on the basis of cytochemical tests, appear unaffected by UV irradiation. While the production of mutant clones is observed only during the S phase of the cell cycle, immediate statistical damage of the cellular DNA is produced at all times of irradiation. This finding excludes that the two types of phenotypic alterations, blocked or altered gene expression, both propagated in the progeny of the cells as clonal properties, may derive from a preferential alteration of those functions during the S phase.

Expression dynamics of transforming phenotypes in X-irradiated Syrian golden hamster embryo cells

We investigated the dynamics of expression for morphological transformation, for anchorage-independently growing (Anch-) cells and for mutation at the hypoxanthine guanine phosphoribosyl transferase (HGPRT) locus in X-irradiated Syrian golden hamster embryo (SHE) cells. No Anch- cells were detected with 0-14 days of post-irradiation incubation before selection. No mutants at the HGPRT locus were detected with 0-5 days of post-irradiation incubation before selection. The maximum number of mutants for all doses was found after post-irradiation incubation for 8 days. On the other hand, the highest frequency of morphological transformants for all doses was detected with 0 days of post-irradiation incubation. The frequency of induction of morphological transformants increased with increasing dose. Then morphological transformants abruptly decreased with increasing lengths of post-irradiation incubation and no morphological transformants were detected with 14 days of post-irradiation incubation before selection (less than 10(-4)). A large fraction of morphological transformants (more than 86%) was cloned with feeder cells and expressed more extensive phenotypes of malignant transformation, such as the acquisition of anchorage-independent growth, immortality in vitro and tumorigenicity during further subculturing.

Drug resistance following irradiation of RIF-1 tumors: influence of the interval between irradiation and drug treatment

RIF-1 tumors contain a small number of cells (1 to 100 per 10(6) cells) that are resistant to 5-fluorouracil, methotrexate, or adriamycin. The frequency of drug-resistant cells among individual untreated tumors is highly variable. Radiation, delivered in vivo at doses of 3 to 12 Gy, increases the frequency of methotrexate- and 5-fluorouracil-resistant cells, but not the frequency of adriamycin-resistant cells. The magnitude of induction of 5-fluorouracil and methotrexate resistance shows a complex dependence on the radiation dose and on the interval between irradiation and assessment of drug resistance. For a dose of 3 Gy, induced 5-fluorouracil and methotrexate resistance is seen only after an interval of 5 to 7 days, whereas for a dose of 12 Gy, high levels of induced resistance are observed 1 to 3 days after irradiation. The maximum absolute risk for induction of resistance is 4 per 10(4) cells per Gy for methotrexate, and 3 per 10(6) cells per Gy for 5-fluorouracil. These results indicate that tumor hypoxia may play a role in the increased levels of drug resistance seen after irradiation, and that both genetic and environmental factors may influence radiation-induction of drug resistance. These studies provide essential data for models of the development of tumor drug resistance, and imply that some of the drug resistance seen when chemotherapy follows radiotherapy may be caused by radiation-induced drug resistance.

Inhibition of MEL cells' capacity to undergo erythroid differentiation by chemicals added during induction

Erythroid differentiation of murine erythroleukemia (MEL) cells, as induced by dimethyl sulfoxide, can be suppressed by chemicals at very low concentrations, not affecting cell viability and proliferation, if present in the culture medium between 18 and 24 h after addition of the inducer. The effect is apparent on the progeny of the treated cells and is determined, between day 3 and 5 following DMSO induction, as percent value of cells expressing the erythroid phenotype. Cultures showing decreased values are no longer terminal and a large number of clones, incapable of expressing the erythroid phenotype, can be isolated from them. In contrast, induced cultures are terminal if the added chemicals do not decrease the expression of the erythroid phenotype. Incorporation of thymidine into induced cultures reveals that maximal sensitivity of MEL cells to chemicals coincides with DNA duplication. In all affected cells, the inhibition to undergo erythroid differentiation is transmitted from one cell generation to the next.

Replication of non-repetitive DNA during early, middle and late S phase. The general class and the subset transcribed

Synchronized cultures of Chinese hamster ovary cells were pulse-labelled with 5-bromodeoxyuridine (BrdU) during early (0-2.0 h), middle (2.5-4.0 h) and late (4.5-6.0 h) S phase in two successive cell cycles. In each case, the DNA containing BrdU in both strands was duplicated at the same time in both cycles and was isolated for further characterization by centrifugation in CsCl gradients. These DNAs were then radiolabelled by nick-translation and used in either DNA-DNA or RNA-DNA hybridization experiments. In the DNA-DNA experiments, advantage was taken of the substantial rate increases attainable in high concentrations of dextran sulfate to obtain complete reassociation curves with relatively small amounts of material. Assuming that no unresolved low repetition frequency components exist, renaturation kinetics suggest that early replicating DNA contains a greater proportion of non-repetitive sequences than DNA synthesized at later times, the order being early greater than middle greater than late. However, in terms of complexity the non-repeated DNA duplicated early had only 74% of the diverse sequences present in log-phase cells, whereas that replicated in middle and late S phase had 82 and 79.5%, respectively. It therefore appears that while DNA synthesized at different times in S phase may contain varying proportions of non-repetitive sequences, when their diversity is taken into account very few of these sequences (25% or less) exhibit temporal control of replication. Finally, measurements with total cell RNA indicated that the transcribed fraction of non-repeated DNA showed a slight preference for replication in early S phase.

Differential response of human fibroblasts to the cytotoxic and mutagenic effects of UV radiation in different phases of the cell cycle

The effects of DNA repair on UV-induced mutagenesis and cell killing in human diploid skin fibroblasts in different phases of the cell cycle were studied. The cells were synchronized in G1 by culturing at 30 degrees C. Using this synchronization method, it could be demonstrated that cells irradiated at 30 degrees C and allowed to carry out excision repair for various lengths of time, show a much lower mutation frequency than cells irradiated in the exponentially growing state. Irradiation in early G1 gives rise to less mutations than irradiation in S. However, the surviving fraction is not decreased when cells are irradiated in S in comparison with irradiation in G1. Moreover, there is no recovery from UV-induced lethal effects when irradiated cells are kept stationary at 30 degrees C for various periods of time. This is in contrast with the results obtained with density-inhibited fibroblasts held at 37 degrees C, which show a recovery from the UV-induced lethal effects.

Cell-cycle dependency of radiosensitivity and mutagenesis in fertilized egg cells of rice, Oryza sativa L. : 2. X-ray sensitivity and mutation rate during a cell cycle

In order to examine changes in survival and mutation rates during a cell cycle in higher plant, fertilized egg cells of rice were irradiated with X-rays at 2 h intervals for the first 36 h after pollination, i.e., at different phases of the first and second cell cycles. The most sensitive phase in lethality was late G1 to early S, followed by late G2 to M, which were more sensitive than the other phases. In both M1 and M2 generations, sterile plants appeared most frequently when fertilized egg cells were irradiated at G2 and M phases. Different kinds of mutated characters gave rise to the respective maximum mutation rates at different phases of a cell cycle: namely, albino and viridis were efficiently induced at early G1, xantha at early S, short-culm mutant at mid G2, heading-date mutant at M to early G1. The present study suggests the possibility that the differential mutation spectrums concerning agronomic traits are obtained by selecting the time of irradiation after pollination.

Differential cell cycle phase specificity for neoplastic transformation and mutation to ouabain resistance induced by N-methyl-N'-nitro-N-nitrosoguanidine in synchronized C3H10T 1/2 C18 cells

The transformable mouse embryo fibroblast cell line C3H10T 1/2 C18 has been employed to study the induction by the carcinogen N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) of morphological transformation and mutation to ouabain resistance throughout the cell cycle. Cells were synchronized by means of isoleucine deprivation for 24 hr and initiated DNA synthesis with a high degree of synchrony 7.5 hr after release of the isoleucine block. At various intervals throughout the cell cycle cultures were treated with MNNG at 1.0 microgram/ml and the induction of cytotoxicity, morphological transformation, and ouabain-resistant colonies was determined. All three phenomena exhibited marked cell-cycle phase dependency. Maximal induction of transformation occurred in cultured treated 7.5 hr after release from isoleucine deprivation, when the cells were at the G1/S boundary. In contrast, induction of ouabain-resistant colonies was at a minimum at the time of maximal induction of transformation, and peak induction of ouabain resistance did not occur until 16-18 hr after release from the isoleucine block, when cells were in late S phase. A close correlation was observed between the induction of cytotoxicity and of ouabain-resistant mutants. The results suggest that differences exist in the production or cellular processing of the various early lesions.