Clones of Chinese hamster cells cultivated in vitro not permanently resistant to azaguanine

The frequency of clones not permanently resistant to azaguanine (AG) was measured in Chinese hamster ovary cells (CHO) grown in vitro by plating them in 7.5 μg/ml AG and isolating a number of clones in the course of 5 experiments. Such isolated clones were propagated to a point at which their resistance to both AG and the reverse selective medium, HAT, could be determined. Out of a total of 13 clones isolated, 4 of these could not be distinguished from the parent CHO line, either on the basis of their growth in a gradient of AG concentrations or the reverse selective HAT medium or on the basis of their mutation frequency to resistance to 30 μg/ml AG. All four of the apparent phenocopies were isolated from plates in which although lower numbers of cells were seeded, a higher frequency of clones able to grow in AG was yielded. This suggests that the higher “mutation” frequencies obtained at lower cell densities are due to the appearance of phenocopies which occur only under these conditions. It is concluded that under low plating density conditions, the lower levels of AG (7.5 μg/ml) are not satisfactory for mutagenesis and mutation rate studies.     

Effects of L-ascorbic acid on the mutagenicity of ethyl methanesulfonate in cultured mammalian cells.

The effects of L-ascorbic acid (AsA) on the mutations induced by ethyl methanesulfonate (EMS) were examined by means of the 6-thioguanine (6TG)-resistant mutation assay and chromosome aberration assay in cultured Chinese hamster V79 cells. When cells were treated with EMS at various concentrations in the presence of 100 micrograms/ml AsA, EMS-induced 6TG-resistant mutations were reduced about one third or one fourth. EMS-induced chromosome aberrations were also reduced by AsA. These reductions in the mutagenicity of EMS were also found when cells were treated with mixtures of AsA and EMS which had previously been incubated at 37.0 degrees C for 2 h. In pre- and post-treatments with AsA, however, the frequencies of EMS-induced mutations were not reduced, but rather increased markedly.     

The dose-response relationship for ethyl methanesulfonate-induced mutations at the hypoxanthine-guanine phosphoribosyl transferase locus in Chinese hamster ovary cells.

The frequency of ethyl methanesulfonate (EMS)-induced mutations to 6-thioguanine resistance in a Chinese hamster ovary cells clone K1-BH4 was studied at many EMS doses including the minimally lethal range (0-100 microng/ml) as well as the exponential killing portion (100-800 microng/ml) of the survival curve. The mutation frequency increases approximately in proportion with increasing EMS concentration at a fixed treatment time. The pooled data for the observed mutation frequency, f(X), as a function of EMS dose X, is adequately described by a linear function f(X)=10(-6)(8.73+3.45 X), where 0 less than or equal to X less than or equal to 800 microng/ml. One interpretation of the linear dose-response is that, as a result of EMS treatment, ethylation of cellular constituents occurs, which is directly responsible for the mutation. Biochemical analyses demonstrate that most of the randomly isolated 6-thioguanine-resistant variants possess a highly reduced or undetectable level of HGPRT activity suggesting that the EMS-induced mutations to 6-thioguanine resistance affect primarily, if not exclusively, the HGPRT locus.     

Basis for differential cellular sensitivity to 8-azaguanine and 6-thioguanine

Cellular resistance to the cytotoxic purine analogues 8-azaguanine (AG) and 6-thioguanine (TG) is usually mediated by a mutation leading to the loss or reduction in hypoxanthine phosphoribosyltransferase (HPRT) activity. However, stable AG-resistant variants have often been shown to contain wild-type levels of HPRT, while cellular resistance to TG is always accompanied by a profound deficiency in HPRT activity. Such AG-resistant, HPRT-positive cells are still sensitive to TG. To investigate the basis of this differential sensitivity, we examined the inhibition of the HPRT activity by AG and TG in whole cells, in cell-free extracts, and with purified mouse HPRT. In addition, the relative incorporation and utilization of AG and TG by L929 cells were determined under a variety of culture conditions. Results show that, compared to TG, AG is generally a very poor substrate for HPRT. Incorporation of radioactive AG by HPRT-positive cells was extremely sensitive to the free purine concentrations in the medium, so that under the usual culture conditions employing undialyzed serum, cellular uptake and utilization was minimal even when relatively high levels of AG were present. In contrast, the incorporation of radioactive TG was comparable to that of a natural substrate, hypoxanthine. These results indicate that the differential cellular sensitivity to AG and TG is due to the difference between these two guanine analogues as substrates of HPRT. Additional data indicate also that cellular resistance to TG is mediated exclusively by HPRT deficiency, but resistance to very high levels of AG may result through at least two other mechanisms not involving HPRT deficiency. These observations may help resolve some of the conflicting data in the literature, and demonstrate that TG is a better selective agent for the HPRT-deficient phenotype.     

The influence of serum components on the growth and mutation of Chinese hamster cells in medium containing 8-azaguanine

Low concentrations (?20 μg/ml) of 8-azaguanine are 1000 fold more toxic to V79 Chinese hamster cells in medium containing 10% dialyzed fetal calf serum than in medium containing 10% undialyzed serum. Serum enzyme activity that converts AG to nontoxic 8-azaxanthine degrades AG at the same rate, whether or not the serum is dialyzed. However, cytotoxicity results similar to those obtained with US were produced in medium containing DS and 2.5 μg of hypoxanthine (HX)/ml (DSH). Therefore, serum HX is considered to be responsible for the relatively low cytotoxicity of AG in medium containing US. Colonies that arose in medium containing AG were isolated and characterized. Those that remained resistant to AG (40 μg/ml) and sensitive to aminopterin in the presence of HX and thymidine (HAT) were considered mutants; nonmutants were sensitive to AG and resistant to HAT. Colonies isolated from medium containing DSH of US and low concentrations of AG were not mutants, but those from medium containing high concentrations (? μg/l) of AG were mutants. Spontaneous and N-methyl-N′-nitrosoguanidine induced mutants were detectable in medium containing DSH without replating the cells prior to adding AG (?30 μg/ml), but in order to detect MNNG induced mutations in medium containing DS replating was essential. In DS, the mutation frequency increased as an exponential function of the toxicity of MNNG, but remained two orders of magnitude lower than the induced mutation frequencies that occurred in DSH, HX, in DSH or US, produced profound effects, other than interference with AG toxicity, that distort the results of mutagenesis assays. To study mutation using AG resistance as the endpoint, it is essential to use dialyzed serum.     

Lethal and Amanitin-Resistance Mutations in the Caenorhabditis Elegans Ama-1 and Ama-2 Genes

Mutants of Caenorhabditis elegans resistant to alpha-amanitin have been isolated at a frequency of about 1.6 x 10(-6) after EMS mutagenesis of the wild-type strain, N2. Four new dominant resistance mutations have been studied genetically. Three are alleles of a previously identified gene, ama-1 IV, encoding the largest subunit of RNA polymerase II. The fourth mutation defines a new gene, ama-2 V. Unlike the ama-1 alleles, the ama-2 mutation exhibits a recessive-lethal phenotype. Growth and reproduction of N2 was inhibited at a concentration of 10 micrograms/ml amanitin, whereas ama-2/+ animals were inhibited at 100 micrograms/ml, and 800 micrograms/ml was required to inhibit growth of ama-1/+ larvae. We have also determined that two reference strains used for genetic mapping, dpy-11(e224)V and sma-1(e30)V, are at least four-fold more sensitive to amanitin that the wild-type strain. Using an amanitin-resistant ama-1(m118) or ama-1(m322) strain as a parent, we have isolated amanitin-sensitive mutants that carry recessive-lethal ama-1 alleles. The frequency of EMS-induced lethal ama-1 mutations is approximately 1.7 x 10(-3), 1000-fold higher than the frequency of amanitin-resistance alleles. Nine of the lethal alleles are apparent null mutations, and they exhibit L1-lethal phenotypes at both 20 degrees and 25 degrees. Six alleles result in partial loss of RNA polymerase II function as determined by their sterile phenotypes at 20 degrees. All but one of these latter mutations exhibit a more severe phenotype at 25 degrees C. We have also selected seven EMS-induced revertants of three different ama-1 lethals. These revertants restore dominant resistance to amanitin. The selection for revertants also produced eight new dominant amanitin resistance alleles on the balancer chromosome, nT1.     

Interspecific comparison of ethyl methanesulfonate-induced mutation rates in relation to genome size.

A detailed presentation is made of the experimental data from the various systems used by Heddle and Athanasiou to conclude that “the relationship between mutation rate and genome size is as striking for EMS as it is for radiation, thus confirming the reality of the ABCW relation” and that “there is a relatively constant value of rec for all organisms.” It is noted that 2 of the 9 mutation rates cited came from seed treatments of higher plants and were not converted to haploid-genome mutation rates necessary for a valid comparison with other test systems. It is argued that the use of EMS-induced mutation rates from Drosophila and mouse post-meiotic male germ cells for comparisons with radiation-induced mutation rates from Drosophila and mouse spermatogonia is inappropriate. The paucity of the available data that was used is emphasized, and the dearth of all available data is recognized. The method of using the actual initially applied concentration of EMS alone as a measurement of “dose” is criticized. Nevertheless, when this procedure recommended by Heddle and Athanasiou as being necessary “to provide a consistent measure of dose” for inter-specific comparisons of EMS-induced mutation rates is applied, the papers from which the data they used were scrutinized, and other available mutation-rate data assessed, no evidence was found for a relationship between EMS-induced haploid-genome mutation rate and genome size in organisms from E. coli to H. vulgare that differ in DNA content by a factor of more than 1000. X-Ray-equivalent values differed by more than two orders of magnitude from one test system to another and by one order of magnitude for different male-germ cells of Drosophila. Our previous analysis of the available data for radiation-induced mutation rates found no relationship between mutation rate and genome size. It is considered that the failure to find a relation between EMS mutation rate and genome size from the type of analysis suggested by Heddle and Athanasiou has no bearing on the utility of the rec concept. Uncritical extrapolation from one chemical to another and to an X-ray equivalent of genetic damage has been forcefully criticized elsewhere.     

Desmutagenic and bio-antimutagenic activity of docosahexaenoic acid and eicosapentaenoic acid in cultured Chinese hamster V79 cells

The antimutagenic activities of docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA) were examined by studying their effects on induction of 6-thioguanine (6TG)-resistant mutations by ethyl methanesulfonate (EMS) in cultured Chinese hamster V79 cells. DRA had a remarkable inhibitory effect against the cytotoxicity of EMS, when cells were simultaneously-treated with EMS, showing a blocking or scavenging activity of DHA in reduction of surviving fraction of cells. DHA had not so significant effect, when cells were treated before and after treatment with EMS. On the other hand, EPA had marked inhibiting effects against cytotoxicity of EMS, when cells were treated with EPA, before, simultaneous and after treatment with EMS. Against the induction of mutations by EMS, an antimutagenic activity of DHA was found when cells were pre-treated, simultaneously-treated or post-treated with DHA. EPA was also effective in reducing EMS-induced 6TG-resistant mutations when the cells were treated using the three different treatment procedures described above. The results suggest that in cultured Chinese hamster V79 cells, DHA and EPA may have both desmutagenic activity, which inactivates EMS chemically and/or enzymatically and bio-antimutagenic activity which suppresses mutation fixation after DNA is damaged by EMS.     

Ploidy dependence of induced mutation frequency in transformed Syrian hamster cells

The ploidy dependence of the induced frequency of a phenotype can be used to determine the dominant or recessive nature of a somatic mutation to a given trait. To demonstrate this we induced mutations in diploid and spontaneously occurring tetraploid clones of Syrian hamster embryo cells by treatment with EMS (1.2 mg/ml, 4 h). Mutagenized cells were assayed for the recessive mutation to 6-thioguanine resistance (5 μg/ml) and the dominant mutation to ouabain resistance (1.2 mM). The frequency of induction of the dominant mutation was equal in the diploid and tetraploid clones (2.3 × 10^?4). The frequency of induction of the recessive mutation was greatly reduced in the tetraploid clone relative to the diploid clone (1.8 × 10^?4 vs. 1.2 × 10^?3).6TG^r mutant subclones from the tetraploid clone remain nearly tetraploid, or even increase in ploidy, but show a reduction in the number of X chromosomes from two to one, or in some cases none (based on chromosome morphology). The principle of ploidy dependence is now being used to study the induction of phenotypes related to neoplastic transformation.     

Antigen recognition by T lymphocytes. 3. Evidence for two populations of thymus-dependent rosette-forming cells in spleen and lymph nodes

Rosette-forming cells, present in normal spleen, are composed of 70% theta-positive cells with “high” in vitro sensitivity to Azathioprine (AZ) (1 μg/ml) and 30% theta-negative cells with “low” sensitivity to AZ (500 μg/ml). Theta-positive RFC are also found in the thymus (with “high” sensitivity to AZ) and in lymph nodes and peripheral blood (with “intermediate” sensitivity to AZ:50 μg/ml). RFC with “high” sensitivity to AZ (T1) are eliminated from the spleen by adult thymectomy in less than 6 days; it takes more than 48 hours exposure to antilymphocyte serum (ALS) in vivo to suppress them, whereas RFC with “intermediate” sensitivity to AZ (T2), present in lymph nodes and peripheral blood, disappear 6 hours after in vivo ALS treatment but not after adult thymectomy.     

Experiments on the effect of the medium in mutation tests with the HGPRT system in cultured mammalian cells

Higher mutation frequencies were observed on 8AG than on 8AG medium when HGPRT-deficient mutants were being selected in V79 Chinese hamster cells.2 alternative explanations for the effect of the medium were considered, namely (1), that mechanisms are present that cause resistance to 8AG only, in addition to that (or those) causing resistance to both drugs, and (2), that mutants with low HGPRT content survive on 8AG but not on 6TG medium, owing to lower affinity of 8AG for the enzyme. The second explanation was favoured as a result of various experimental approaches, including kinetics of expression on the 2 media, cross-resistance at different expression times and serial selection on the 2 media.     

Mutagenesis in cultured human diploid cells. III. Induction of 8-azaguanine-resistant mutations by furylfuramide.

Trans-2-(2-furyl)-3-(5-nitro-2-furyl) acrylamide (furylfuramide: FF or AF2) was tested for ability to induce 8-azaguanine (8AG) resistant mutations in cultured human diploid cells. FF had a relatively severe cytotoxic effect on the cells. From the concentration-survival curve, the D0 value for 2-h treatment with FF was estimated to be 11 mug/ml. When cells were treated with FF at various concentrations for 2 h, cultured in normal medium for 48 h, and then selected in medium containing 8AG at 30 mug/ml, the induced mutation frequency increased gradually with increase in concentration of FF. When cells were treated with FF at 10 mug/ml for 2 h, cultured in normal medium for various periods of mutation expression time, and selected with 8AG at 30 mug/ml, the highest induced mutation frequency was obtained with 48 h of mutation expression time. Microscopic examination of the numbers of cells in colonies indicated that the total number of cells increased by half during this mutation expression time of 48 h.     

Insulin stimulation of glucose entry in chick fibroblasts and HeLa cells

3 to 5-fold stimulation by insulin of the rate of D-glucose entry into chick fibroblasts in culture is observed in cells transferred for several hours to medium containing little (50 to 100 μg/ml) or no D-glucose. No stimulation is obtained in cells trans-ferred for the same period to “high” glucose (1 mg/ml) medium. The latter finding probably accounts for the consistent failure of earlier studies to demonstrate stimulation. Pyruvate alone is as stimulatory as insulin and reverses the D-glucose “repression”. Hela cells are as sensitive to insulin as chick cells.     

Molecular analysis of spontaneous and ethyl methanesulphonate-induced mutations of the hprt gene in hamster cells

Independent spontaneous or ethyl methanesulphonate (EMS)-induced mutants lacking HPRT enzyme activity were analysed for changes in hprt gene structure. Of 21 spontaneous mutants, 6 had total gene deletions, 2 had partial gene deletions, and 13 were indistinguishable from wild-type by Southern analysis. In contrast a sample of 23 EMS-induced mutants, each of which showed potentially interesting characteristics (e.g. high reversion frequency, X-chromosome rearrangement), showed no detectable hprt gene changes. RNA isolated from 59 mutants with presumptive point mutations (13 spontaneous, 46 EMS-induced) was analysed on dot blots for changes in the amount of hprt mRNA. A wide range of mRNA levels was found, from mutants with undetectable amounts to those with more than wild-type amounts. However, Northern blots of all these mutant RNAs revealed only one (EMS-induced) mutation with a change in hprt mRNA size. Taken with our previously-published data on these mutants, it is argued that they represent a broad range of mutational types, and that the hprt gene mutation system provides a sensitive means of distinguishing mutational spectra of different DNA-damaging agents.     

Drug Resistance of Staphylococci

According to an epidemiological survey of drug resistance in Staphylococcus aureus, it was found that there are three types of cross-resistance to macrolide antibiotics (EM, erythromycin: OM, oleandomycin: LM, leucomycin: SP, spiramycin), i.e., resistance to EM, OM, LM, and SP, to EM and OM, and inducible resistance to “EM, OM”. In the inducible strains of S. aureus, EM and OM are active inducers, and the optimal concentrations of the inducers are 0.1 μg/ml and 1.0 μg/ml, respectively. The induction of high resistance (800 μg/ml or more) to both EM and OM occurred within 10 min exposure to 0.1 μg/ml of EM, and the resistance of induced cells was lost after overnight growth in the absence of inducer. After 1 to 3 hr exposure to 1.0 μg/ml of OM, the inducible strains acquired high resistance (100 μg/ml or more) to EM and to a lesser extent, resistance to OM, and the acquired resistance was lost when grown in antibiotic free media. When a known concentration of EM was mixed with the induced cells or with a crude extract from induced cells which had acquired high resistance to EM and OM, the antibiotic activity of EM was still retained in the mixture, indicating that the induced mixture or the extract from the induced cells was incapable of antibiotic (EM) inactivation under the test conditions.     

The effect of folate deficiency on the cytotoxic and mutagenic responses to ethyl methanesulfonate in human lymphoblastoid cell lines that differ in p53 status

Folic acid deficiency acts synergistically with alkylating agents to increase genetic damage at the HPRT locus in Chinese hamster ovary cells in vitro and in rat splenocytes in vivo. The present studies extend these observations to human cells and, in addition, investigate the role of p53 activity on mutation induction. The human lymphoblastoid cell lines TK6 and WTK1 are derived from the same parental cell line (WI-L2), but WTK1 expresses mutant p53. Treatment of folate-replete or deficient WTK1 and TK6 cells with increasing concentrations (0-50microg/ml) of ethyl methanesulfonate (EMS) resulted in significantly different HPRT mutation dose-response relationships (P<0.01), indicating that folate deficiency increased the EMS-induced mutant frequency in both cell lines, but with a greater effect in TK6 cells. Molecular analyses of 152 mutations showed that the predominant mutation (65%) in both cell types grown in the presence or absence of folic acid was a G>A transition on the non-transcribed strand. These transitions were mainly at non-CpG sites, particularly when these bases were flanked 3' by a purine or on both sides by G:C base pairs. A smaller number of G>A transitions occurred on the transcribed strand (C>T=14%), resulting in 79% total G:C>A:T transitions. There were more genomic deletions in folate-deficient (15%) as compared to replete cells (4%) of both cell types. Mutations that altered RNA splicing were common in both cell types and under both folate conditions, representing 33% of the total mutations. These studies indicate that cells expressing p53 activity exhibit a higher rate of mutation induction but are more sensitive to the toxic effects of alkylating agents than those lacking p53 activity. Folate deficiency tends to reduce toxicity but increase mutation induction after EMS treatment. The p53 gene product did not have a major influence on the molecular spectrum after treatment with EMS, while folate deficiency increased the frequency of deletions in both cell types.     

槲皮素对人脑胶质瘤干细胞生物学行为及miR-29s家族的影响分析

目的探讨分析槲皮素对人脑胶质瘤干细胞（BGSCs）生物学行为及miR-29s家族的影响。 方法使用干细胞培养液对U87人脑胶质瘤细胞进行培养,采用CCK-8法检测槲皮素对BGSCs细胞增殖抑制率,采用流式细胞技术检测槲皮素对BGSCs细胞凋亡影响,并采用real-time PCR鉴定槲皮素对BGSCs细胞中miR-29a、miR-29b以及miR- 29c表达的影响。采用t检验以及方差分析进行统计学分析。 结果随着槲皮素浓度的增加,BGSCs细胞增殖抑制率增加24 h 0 μg/ml（0.00±0.12）%、10 μg/ml（1.36±0.38）%、20 μg/ml（15.33±3.01）%、40 μg/ ml（29.50±4.57）%、80 μg/ml（40.21±6.42）%、160 μg/ml（61.21±7.48）,F = 76.273,P < 0.05;48 h 0 μg/ml （0.09±0.05）%、10 μg/ml（9.84±2.17）%、20 μg/ml（28.57±3.84）%、40 μg/ ml（43.59±5.21）%、80 μg/ml（59.50±3.28）%、160 μg/ ml（70.21±9.48）%,F = 85.392,P < 0.05,且同浓度槲皮素作用48 h对BGSCs细胞增殖抑制率高于作用24 h（P < 0.05）。随着槲皮素浓度的升高,BGSCs细胞凋亡率升高[0 μg/ml（13.42±1.21）%、20 μg/ml（38.47±9.28）%、40 μg/ml（59.34±7.20）%、80 μg/ml（71.42±9.47）%,F = 57.493,P < 0.05]。不同浓度槲皮素处理BGSCs细胞后,可促进BGSCs细胞miR-29s家族miR- 29a/ b/ c相对表达量,且随着槲皮素浓度的增加,BGSCs细胞miR-29s家族相对表达量增加[miR-29a 0 μg/ml（1.04±0.08）、20 μg/ml（1.16±0.05）、40 μg/ml（1.30±0.10）、80 μg/ ml（1.41±0.09）,F = 19.281,P < 0.05;miR-29b 0 μg/ml（1.06±0.09）、20 μg/ml（1.13±0.05）、40 μg/ml（1.25±0.07）、80 μg/ml（1.30±0.09）,F = 13.427,P < 0.05;miR-29c 0 μg/ml（1.03±0.07）、20 μg/ml（1.15±0.03）、40 μg/ml（1.22±0.06）、80 μg/ml（1.31±0.08）,F = 14.502,P < 0.05]。 结论槲皮素可有效抑制人脑BGSCs增殖,促进人脑BGSCs凋亡,并促进人脑BGSCs中miR- 29s家族表达。     

Dose-rate effects of ethyl methanesulfonate on survival and mutation induction in cultured Chinese hamster cells

The dose-rate effects of ethyl methanesulfonate (EMS) on the survival and induction of mutations in Chinese hamster Don cells were investigated. The most effective time of exposure to EMS for reducing the surviving fraction of cells was 4 h, shorter and longer exposure times being less effective. The threshold or minimal concentration of EMS giving a surviving fraction of 0.5 was 0.05 mg/ml. The minimal effective time of exposure to EMS for cell death was 1 h. Corrected survival curves showed that longer exposure times at lower dose rates of EMS had less cytotoxic effect than shorter exposure times at higher dose rates.After exposure of Don cells to various doses of EMS for various times, the frequencies of mutations resistant to 6-thioguanine (6TG) were measured. An exposure time of 4 h produced a lower mutation frequency than shorter or longer exposure times that resulted in the same surviving fraction of cells. An exposure time of 20 h produced the highest induced mutation frequency.This system using cultured Chinese hamster cells should be useful as a sensitive procedure for detecting the mutagenic actions of chemicals.     

Different modifications by vanillin in cytotoxicity and genetic changes induced by EMS and H2O2 in cultured Chinese hamster cells.

The modifying effects of vanillin on the cytotoxicity and 6-thioguanine (6TG)-resistant mutations induced by two different types of chemical mutagens, ethyl methanesulfonate (EMS) and hydrogen peroxide (H2O2), were examined using cultured Chinese hamster V79 cells. The effects of vanillin on H2O2-induced chromosome aberrations were also examined. Vanillin had a dose-dependent enhancing effect on EMS-induced cytotoxicity and 6TG-resistant mutations, when cells were simultaneously treated with vanillin. The post-treatment with vanillin during the mutation expression time of cells after treatment with EMS also showed an enhancement of the frequency of mutations induced by EMS. However, vanillin suppressed the cytotoxicity induced by H2O2 when cells were post-treated with vanillin after H2O2 treatment. Vanillin showed no change in the absence of activity of H2O2 to induce mutations. Post-treatment with vanillin also suppressed the chromosome aberrations induced by H2O2. The differential effects of vanillin were probably due to the quality of mutagen-induced DNA lesions and vanillin might influence at least two different kinds of cellular repair functions. The mechanisms by which vanillin enhances or suppresses chemical-induced cytotoxicity, mutations and chromosome aberrations are discussed.     

Time versus replication dependence of EMS-induced delayed mutation in Chinese hamster cells

We have previously observed in Chinese hamster cells that ethyl methane sulfonate (EMS) induces mutations which are distributed over at least 10-14 cell divisions following treatment. This delayed appearance of mutations could be explained by EMS-induced lesions which remain in DNA and have a probability that is significantly less than 1.0 of producing base mispairing errors during successive replication cycles (replication-dependent). Alternatively, delayed mutation may be a time-dependent process in which a slow acting or damage inducible error-prone repair process removes persistent DNA lesions and replaces them with an incorrect base during the course of 7-10 days of colony growth following EMS exposure. To address this question, the distribution of HGPRT delayed mutation events (fifth division or later) in cells plated immediately for exponential growth after EMS treatment was compared with the distribution in cells which remained under confluent growth conditions for 8 days and then were replated. Both the distribution and rate of accumulation of delayed mutations (mutations/cell division) were similar in the two culture conditions. In contrast, the frequency of early mutations (before the fifth division) in the confluent population was reduced more than 2-fold compared to dividing cells. A comparison of the frequency of EMS-induced DNA lesions in the two populations revealed that the density inhibited population contained one third the DNA lesions of the exponential population. These results argue against a time-dependent process since, if this mechanism applies, one would expect an increase in early mutant events and a decrease in delayed events in the confluent population. The results, however, are consistent with a replication model in which potential early mutant lesions are preferentially removed in the density inhibited culture during the 8 days of incubation while lesions producing late mutants are not removed.