Dependency of the yield of sister-chromatid exchanges induced by alkylating agents on fixation time. Possible involvement of secondary lesions in sister-chromatid exchange induction

Chinese hamster V79 cells were pulse-treated (for 60 min) with various mutagens three, two or one cell cycles before fixation (treatment variants A, B and C, respectively) and the frequencies of induced SCEs were analysed and compared. The degree of increase in frequency of SCEs with dose in the treatment variants depended on the mutagen used. For the methylating agents MNU, MNNG and DMPNU, high yields of SCEs were obtained in the treatment variants A and B, and there was no difference in the efficiency with which these agents induced SCEs in these treatment variants. In the treatment variant C, however, no SCEs were induced with mutagen doses yielding a linear increase in SCE frequency in treatment variants A and B. A slight increase in SCE frequency in treatment variant C was observed only when relatively high doses of MNU or MNNG were applied. Like the above agents, EMS, ENU and MMS induced more SCEs in treatment variants A and B than in C, but for these agents treatment variant B was most effective and SCEs were induced over the entire dose range, also in treatment variant C. As opposed to the methylating and ethylating agents, MMC induced SCEs with high efficiency when treatment occurred one or two generations prior to fixation. There was no difference in SCE frequency between these treatment variants. MMC was completely ineffective for the induction of SCEs when treatment occurred three generations before fixation. The unexpectedly low SCE frequencies induced by the methylating and ethylating agents when treatment occurred one generation before fixation were not due to the exposure of cells to BrdU prior to mutagen treatment. From the results obtained, it is concluded that DNA methylation and ethylation lesions give rise to SCEs only with very low probability during the replication cycle after the lesion's induction, and that subsequent lesions produced during or after replication of the methylated or ethylated template (secondary lesions) are of prime importance for SCE formation after alkylation. For MMC, however, primary lesions seem to be most important for SCE induction.     

Induction of sister chromatid exchanges and chromosome aberrations in cho cells arrested in the cell cycle by arginine deprivation

Summary Sister chromatid exchanges (SCE) and chromosome aberrations were induced in nondividing CHO cells that had been arrested in their cell cycle by deprivation of the essential amino acid arginine. Cells arrested in arginine-deficient medium (ADM) were treated with one of the mutagenic agents N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) or mitomycin C (MMC) and refed with complete medium; the recovering cell population was sampled at various intervals thereafter and mitotic cells analyzed for the presence of chromosome aberrations and SCE. Both chemicals were observed to cause delays in the cell cycle of recovering cells and to induce, chromosome aberrations and SCE at low doses. We have described the variation in the incidence of chromosome aberrations and SCE with respect to sampling time and the number of cell cycles traversed. When ADM-arrested CHO cells were treated with three mutagens at various intervals either before or after release from ADM, it was observed that: (a) UV light induced the greatest number of SCE when applied to cells undergoing DNA synthesis, and SCE yeilds induced by this agent could be reduced by postirradiation incubation in ADM; (b) MNNG induced fewer SCE when applied to cells undergoing DNA synthesis, and SCE yields induced by this agent could not be reduced by posttreatment incubation in ADM for 24 hr. (c) MMC induced the same level irrespective of the time of exposure, and SCE yields induced by this agent could not be reduced by posttreatment incubation in ADM for 24 hr. This work was supported by grants from the British Columbia Foundation for Non-Animal Research (to W. D. M.), and the National Cancer Institute of Canada and the National Research Council of Canada (to H. F. S.). Professor H. F. Stich is a Research Associate of the NCI.     

Antigenotoxic effect of lipoic acid against mitomycin-C in human lymphocyte cultures

Antitumor agents are used in therapy against many forms of human cancer. One of these is mitomycin-C (MMC). As with many agents, it can interact with biological molecules and can induce genetic hazards in non-tumor cells. One of the possible approaches to protect DNA from this damage is to supply antioxidants that can remove free radicals produced by antitumor agents. Lipoic acid (LA) is known as one of the most powerful antioxidants. The aim of this study was to investigate antigenotoxic effects of LA against MMC induced chromosomal aberrations (CA), sister chromatid exchanges (SCE) and micronucleus (MN) formation in human lymphocytes. Lymphocytes were treated with 0.2 μg MMC/heparinized mL for 48 h. Three different concentrations (0.5, 1, 2 μg/mL) of LA were used together with MMC in three different applications; 1 h pre-treatment, simultaneous treatment and 1 h post-treatment. A negative, a positive and a solvent control were also included. In all the cultures treated with MMC + LA, the frequency of abnormal cells and CA/cell significantly decreased compared to MMC. Statistically significant reduction was also observed in SCE/cell and MN frequencies in all treatments. These results demonstrated anticlastogenic and antimutagenic effects of LA against MMC induced genotoxicity. LA showed the most efficient effect during 1 h pretreatment. On the other hand, MMC + LA treatments induced significant reduction in mitotic index than that of MMC treatment alone. These results are encouraging that LA can be a possible chemopreventive agent in tumorigenesis in both cancer patients and in health care persons handling anti-cancer drugs.     

Spontaneous and mitomycin-C induced sister-chromatid exchanges : Comparison of in vivo and in vitro systems

Frequencies of sister-chromatid exchanges (SCE) were measured in vitro in mouse fibroblasts and in vivo in mouse bone-marrow cells. SCE levels in these cell systems were measured in response to varying concentrations of bromodeoxyuridine (BrdU) and mitomycin-C (MMC). Although BrdU was found to induce SCE in both cellular systems, baseline SCE levels were 2- to 3-fold higher in vitro than in vivo. SCE induction was found to be a linear function of MMC concentration in vivo and in vitro; however the slope of the in vivo curve was 5-fold higher. The interaction of BrdU substituted DNA and MMC was examined by administering a fixed dose of MMC with increasing concentrations of BrdU. The induced SCE frequencies appeared to be additive. In addition to measuring drug-induced SCE, the BrdU differential staining technique allows concomitant measurement of the inhibition of cellular replication by the test drugs.     

Characterization of the enhancing effect of caffeine on sister-chromatid exchanges induced by ultraviolet radiation in excision-proficient xeroderma pigmentosum lymphoblastoid cells

Cells of some excision-proficient xeroderma pigmentosum (XP) cell lines are highly sensitive to post-UV caffeine treatment in terms of sister-chromatid exchange (SCE) induction as well as cell lethality. In the present study, we conducted a detailed investigation of the enhancing effect of caffeine on SCE frequency induced by UV in excision-proficient XP cells, and obtained the following results. (1) Continuous post-UV treatment with 1 mM caffeine markedly enhances UV-induced SCEs and such enhanced SCEs occur with similar frequency during either the 1st or the 2nd cell cycle in the presence of caffeine and 5-bromodeoxyuridine (BrdUrd). (2) The high sensitivity of the cells to post-UV caffeine treatment persists for at least 2 days after UV when irradiated cells are held in either the proliferating or the nonproliferating state prior to the addition of BrdUrd. (3) Caffeine exerts its effect on cells in S phase. (4) Neither BrdUrd in the medium nor the incorporated 5-bromodeoxyuridine monophosphate (BrdUMP) in DNA plays an appreciable role in the expression of the enhancing effect of caffeine. The most likely explanation for our findings is as follows. In excision-proficient XP cells, the cause of SCE formation such as UV-induced lesions or resulting perturbations of DNA replication persists until the 2nd round or more of post-UV DNA replication. If caffeine is given as post-UV treatment, such abnormalities may be amplified, resulting in a synergistic increase in SCE frequency.     

Antagonizing effect of 3-aminoharman on induction of sister-chromatid exchanges by mutagens

3-Aminoharman (3AH, 3-amino-1-methyl-9H-pyrido[3,4-b]indole), which has been reported as a novel substance with an antagonistic effect on induction of sister-chromatid exchange (SCE) by polycyclic mutagens in the presence of the metabolic activation system, was examined with a cultured human lymphoblastoid cell line, NL3, for its effect on SCE induction by direct-acting mutagens such as mitomycin C (MMC), nitrogen mustard N-oxide (NMO), methyl methanesulfonate (MMS), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), 4-nitroquinoline 1-oxide (4NQO) and 3-hydroxyamino-1-methyl-5H-pyrido[4,3-b]indole (OH-Trp-P-2), and also by ultraviolet light (UV) irradiation. The results obtained on simultaneous treatment with 3AH and mutagens were as follows: (1) 3AH suppressed more than 50% of SCEs induced by MMC, NMO and OH-Trp-P-2; (2) 4NQO- and MNNG-induced SCEs were also suppressed by 3AH but to a lesser degree; (3) MMS-induced SCEs were not, however, altered by 3AH; and (4) the suppression of SCE by 3AH was dose-dependent. Treatment of cells with 3AH for 2 h immediately before MMC exposure suppressed SCE induction to a significant degree similar to the simultaneous treatment, but post-treatment with 3AH was much less effective. 3AH inhibited SCE induction by NMO when 3AH treatment was carried out either before or after NMO treatment, to an extent similar to the simultaneous treatment. Treatments with 3AH either before or after UV exposure did not change the UV-induced SCEs. Results with these direct-acting mutagens ruled out the relevance of metabolic activation as a necessary step for the antagonizing effect of 3AH.     

Recovery of mitomycin C-treated mouse 10T1/2 cells during confluent holding

The relationship between cytotoxicity, sister-chromatid exchanges (SCE) and the repair of DNA crosslinks was studied in mouse 10T1/2 cells during confluent holding following either acute or protracted MMC treatment. No cytotoxic effects were observed with increasing doses of MMC until SCE frequencies 1.8 times background levels were induced. Protracted MMC treatments were less cytotoxic than acute MMC exposure at doses which yielded similar frequencies of SCE. The kinetics of recovery during confluent holding in acute MMC-treated cells were similar for cytotoxicity and the repair of DNA interstrand crosslinks. These results suggest that a type of non-lethal DNA damage which causes SCE may persist for long periods of time in MMC-treated cells. This non-lethal damage may accumulate during protracted MMC exposure while damage leading to cell killing is repaired.     

Sister-chromatid exchanges and cell-cycle kinetics in human lymphocyte cultures exposed to alkylating mutagens: apparent deformity in dose-response relationships

Experiments have been carried out using human whole-blood cultures to determine the effects of sampling times and of the duration of 5-bromodeoxyuridine (BrdUrd) treatment before fixation on sister-chromatid exchange (SCE) frequencies following exposure to mitomycin C (MMC). Cells were pulse treated for 1 h with 3 X 10(-6) M MMC at G1, and then sampled at 4-h intervals up to 88 h after stimulation of cultures with phytohemagglutinin (PHA). Results showed that this MMC treatment induced a 5-6 h proliferation delay per cell cycle, and that SCE frequencies first increased with time of fixation, peaking at 68 h, and then decreased. When cells were similarly treated with MMC, but subsequently exposed to BrdUrd for various times before fixation of cultures at 72 h, the SCE frequencies markedly increased with increasing durations of BrdUrd incubation times. These data indicate that, in mutagen-treated cultures, lymphocytes having relatively longer cell-cycle times show a higher mean frequency of SCEs. In a subsequent experiment, cells were treated for 1 h with increasing doses of MMC or 4-nitroquinoline 1-oxide (4NQO) at 0, 24, or 48 h, and then fixed at 72 h after PHA stimulation. Results showed that the optimal treatment times at which the agents could most efficiently produce SCEs were different for MMC and 4NQO, and that the dose-response curves tended to 'bend down' at very high doses; that is, treatments with very high doses induced smaller than expected numbers of SCEs. However, cells similarly treated with very high doses showed a higher, expected frequency of SCEs when sampled at 84 h, but again had a lower than expected SCE frequency when fixed at 96 h. The results indicate that there is an optimal time for sampling at which one can observe the maximum increase in SCE frequencies following mutagen exposure, and strongly suggest that the higher the dose, the later the optimal sampling time. Because of the apparent deformity of dose-response curves obtained after various treatments and sampling times, it seems necessary that extra fixation-time points be included in test protocols so as to avoid false negatives or confirm possible positives.     

Fate of DNA lesions that elicit sister-chromatid exchanges

Using 3-way differential staining (TWD) of sister chromatids, the fate of DNA lesions involved in sister-chromatid exchange (SCE) formation was determined in murine bone marrow cells in vivo, after treatment with either mitomycin C (MMC) or cyclophosphamide (CP). Both MMC (2.6 mg/kg b.w.) and CP (7 mg/kg b.w.) induced an SCE frequency near the expected in the 2 subsequent cell divisions, but the frequency of SCE occurring at the same locus in successive cell divisions was substantially lower than expected. The results are compared with previous data obtained after exposure to gamma-rays. A model of SCE induction is proposed.     

The distribution of mitomycin C-induced sister chromatid exchanges in the euchromatin and heterochromatin of the Indian Muntjac

The frequency of sister chromatid exchanges (SCEs) induced by mitomycin C (MMC) in Indian Muntjac chromosomes was determined by the fluorescence plus Giemsa (FPG) technique. Using scanning cytophotometry the relative DNA content of each chromosome was measured with and without acid or alkali pretreatments for C-banding. During acid and alkali treatments, euchromatin lost 20 to 30% of its DNA, while heterochromatin lost less than 5%; an intermediate DNA loss was observed for the short arm of the X chromosome. After growth of cells in the presence of MMC during the first cycle and in the presence of bromodeoxyuridine (BrdU) during the first and second cycles of DNA replication, SCEs in the euchromatin were proportional to DNA content. SCEs at the junctions between the neck of the X chromosome and the long and short arms occurred more frequently than expected. A threshold effect for the induction of SCEs was observed in regions resistant to DNA extraction by acid and alkali treatments (i.e., the neck and short arm of the X chromosome). At high concentrations of MMC, the frequency of SCE at each junction appears to plateau at 0.5.     

Sister chromatid exchanges and inhibition of DNA synthesis in irradiated human cells

X-ray irradiation inhibits DNA synthesis and enhances the frequency of sister chromatid exchanges (SCE) in normal human lymphocytes. On the contrary, cells from patients with Down's syndrome, Xeroderma pigmentosum (form II) and progeria, characterized by radioresistant DNA synthesis, do not show such an increase in SCE frequency. We suggest that radiation-induced SCE frequency is a result of inhibition of DNA replication, rather than a direct damage of chromosomes by ionizing radiation. It is in agreement with Painter's /13/ hypothesis according to which SCE are formed due to asynchronous completion of replication in contiguous replicon clusters. So, probability of SCE formation is the more the lower is rate of replication. Thus, the extent of radiation damage cannot be measured directly by the SCE frequency.     

Molecular dosimetry of the chemical mutagen ethyl methanesulfonate in Escherichia coli and in V-79 chinese hamster cells

Caffeine increases the number of sister-chromatid exchanges (SCE) induced by mitomycin C (MMC) in human peripheral lymphocytes in culture. This enhancement decreases when the treated cells are held in medium before phytohemagglutinin (PHA) stimulation, or when caffeine is added to cultures some time after PHA stimulation but prior to DNA synthesis. There thus appears to be a caffeine-sensitive prereplication repair system, presumably an excision mechanism, capable of repairing a fraction of the MMC-induced DNA lesions.     

DNA repair replication,DNA breaks and sister-chromatid exchange in human cells treated with adriamycin in vitro

The effects of adriamycin (AM) on DNA repair replication, the frequency of sister-chromatid exchange (SCE), the rate of cell proliferation and the frequency of DNA strand breaks were studied in human cells in vitro. No repair replication was observed in lymphocytes exposed to AM in concentrations up to 10^?3 moles/1. DNA repair replication induced by UV and alkylating agents was not affected by a concentration of AM that completely inhibited cell proliferation (10^?6 moles/1).Fibroblasts exposed to AM at 10^?4 moles/1 in the presence of hydroxyurea showed an increase of strand breaks and cross-links in DNA. When AM was added to UV-irradiated fibroblasts, there was an increase of DNA strand breaks in addition to the breaks caused by UV alone. Similar effects were observed in lymphocytes.A dose-dependent increase of SCE was observed in lymphocytes exposed to low concentrations of AM (<10^?7 moles/1). At higher concentrations the increase of SCE levelled off, and cell proliferation became severely inhibited. There was no evidence of removal of SCE-inducing damage in cells exposed to AM during G₀ or G₁. The level of SCE induced in the third cell cycle after treatment with AM was not different from that induced during the first two cell cycles.These results suggest that the various genotoxic and cytotoxic effects of AM are caused by different types of cellular damage. Moreover, AM-induced DNA damage persists for several cell cycles in human cells in vitro and seems to be resistant to repair activity.     

Effect of high-density extremely low frequency magnetic field on sister chromatid exchanges in mouse m5S cells

The induction of sister chromatid exchanges (SCEs) was evaluated in the cultured mouse m5S cells after exposure to extremely low frequency magnetic field (ELFMF; 5, 50 and 400 mT). Exposure to 5 mT and 50 mT ELFMF led to a very small increase in the frequency of SCEs, but no significant difference was observed between exposed and unexposed control cells. The cells exposed to 400 mT ELFMF exhibited a significant elevation of the SCE frequencies. There was no significant difference between data from treatments with mitomycin-C (MMC) alone and from combined treatments of MMC plus ELFMF (400 mT) at any MMC concentrations from 4 to 40 nM. These results suggest that exposure to highest-density ELFMF of 400 mT may induce DNA damage, resulting in an elevation of the SCE frequencies. We suppose that there may be a threshold for the elevation of the SCE frequencies, that is at least over the magnetic density of 50 mT.     

Effects of mitomycin C on sister chromatid exchange in normal and Bloom's syndrome cells

Bloom's syndrome lymphocytes, which are characterized by a high incidence of sister chromatid exchanges (SCE: 80.6 per cell), were treated with mitomycin C (MMC) and the effect of the chemical on SCE frequency compared with that in normal cells. Raising the concentration of MMC from 1 X 10(-9) to 1 X 10(-7) g/ml led to about 10-fold increase (61.7 SCE per cell) in the SCE frequency over the base line in normal lymphocytes (6.4 SCE per cell), though chromosome aberrations remained at a relatively low frequency. MMC caused about a two-fold rise in SCE in cells of Bloom's syndrome (128.8 SCE at 10(-9) g/ml; 139.3 SCE at 10(-8) g/ml). The frequency of chromosome aberrations in Bloom's syndrome cells at concentrations of MMC of 1 X 10(-9) and 1 X 10(-8) g/ml was 0.350 and 0.825 per cell, respectively, and low when compared to the increased number of SCE. The increased frequency of SCE in normal and Bloom's syndrome cells is in contrast to the reported findings with cells from Fanconi's anemia and xeroderma pigmentosum. The distribution of SCE in MMC-treated normal cell correlates with that of spontaneous SCE in cells of Bloom's syndrome.     

Effect of high-density extremely low frequency magnetic field on sister chromatid exchanges in mouse m5S cells

The induction of sister chromatid exchanges (SCEs) was evaluated in the cultured mouse m5S cells after exposure to extremely low frequency magnetic field (ELFMF; 5, 50 and 400 mT). Exposure to 5 mT and 50 mT ELFMF led to a very small increase in the frequency of SCEs, but no significant difference was observed between exposed and unexposed control cells. The cells exposed to 400 mT ELFMF exhibited a significant elevation of the SCE frequencies. There was no significant difference between data from treatments with mitomycin-C (MMC) alone and from combined treatments of MMC plus ELFMF (400 mT) at any MMC concentrations from 4 to 40 nM. These results suggest that exposure to highest-density ELFMF of 400 mT may induce DNA damage, resulting in an elevation of the SCE frequencies. We suppose that there may be a threshold for the elevation of the SCE frequencies, that is at least over the magnetic density of 50 mT.     

Effects of temperature on chemically induced sister-chromatid exchange in human lymphocytes

Lymphocytes from healthy adults were studied for sister-chromatid exchanges (SCEs) when pulse-treated in G0 with mitomycin C (MMC), ethyl methanesulfonate (EMS), or 4-nitroquinoline N-oxide (4NQO) at various temperatures ranging from 0 degrees C to 41 degrees C and then cultured in medium containing 5-bromodeoxyuridine at 37 degrees C. The results showed that the frequencies of SCEs induced by MMC or EMS varied according to the treatment temperature. In MMC- or EMS-exposed cultures, the SCE frequency increased continuously with increasing treatment temperature; treatment at 37 degrees C resulted in a 3-4 times greater induction of SCEs than did that at room temperature (25 degrees C). On the other hand, SCE frequencies in cells exposed to 4NQO remained within normal deviation, showing no temperature-dependent changes. Baseline SCE frequencies remained almost constant within the temperature range tested. These data indicate that treatment temperature is a very critical factor in determining the sensitivity of cells to the chemical induction of SCEs.     

Physical,chemical, and biological factors affecting sister-chromatid exchange induction in human lymphocytes exposed to mitomycin C prior to culture

In experiments to assess the effects of several biological, chemical, and physical variables on sister-chromatid exchange (SCE) induction in cultured lymphocytes exposed to mitomycin C (MMC) before PHA stimulation we observed: (1) high SCE frequencies in female cells, and normal SCE frequencies in Y-bearing metaphases in mixed cultures containing equal numbers of MMC-treated female lymphocytes and untreated male lymphocytes; (2) small, but statistically significant, decreases in SCEs with increasing pH after G₀ exposure in the pH range 6.6–7.6; (3) pronounced reductions in MMC-induced SCEs in lymphocytes exposed at 4°C vs. 37°C. In other studies, SCE induction was evaluated in cultures exposed during G₀ to MMC concentrations ranging from 0.25 to 2.5 μg/ml for varying time intervals ranging from 5 min to 24 h. For all concentrations tested SCE induction varied as a linear function of G₀ exposure time. To compare SCE induction between cultures, we calculated the mean frequencies of SCEs induced per metaphase/unit dose MMC/unit G₀ exposure time (SCE/μg/h). A mean frequency of 20.7 ± 4.8 SCE/μg/h was observed for 41 lymphocyte cultures suggesting that a single term adequately describes the rate of SCE induction following G₀ exposure to a 10-fold range in concentration of MMC for time intervals of 30 min to 24 h.     

Use of rat primary lung cells for studying genotoxicity with the sister-chromatid exchange and micronucleus assays

Primary culture of lung cells from CD rats was established for pulmonary genotoxicity studies using two genetic endpoints, sister-chromatid exchange (SCE) and micronucleus formation (MN). In the cell isolation study, a combined enzyme separation of rat lungs with trypsin (1.3 mg/ml) plus collagenase (50 U/ml) gave the highest yield of viable and colony-forming cells. For the MN assay, the cytokinesis block induced by cytochalasin B (CYB) was employed to enumerate MN in binucleated (BN) cells. Treatment of primary lung cells with 2 micrograms CYB/ml for two days appeared to be optimal for scoring micronuclei in CYB-induced BN cells. By this procedure, mitomycin C (MMC), triethylenemelamine, and benzo[a]pyrene caused a dose-related increase in micronucleated BN cells in vitro without metabolic activation. In the SCE assay, maximum second-division metaphases were obtained after cells were incubated with bromodeoxyuridine for 48-54 h. After this incubation time, high frequencies of SCE induced by MMC and 3-methylcholanthrene after in vitro exposure (without S9 activation) or in vivo exposure were observed. The results indicate that rat primary lung cells can metabolize polycyclic aromatic hydrocarbons and that this lung cell system is potentially useful for the detection of pulmonary genotoxicants.     

Modification of the alkaline Comet assay to allow simultaneous evaluation of mitomycin C-induced DNA cross-link damage and repair of specific DNA sequences in RT4 cells

The alkaline Comet assay is a simple, sensitive method for measuring the extent of DNA strand breaks in individual cells. Several modifications to the original assay have been developed to increase its applications. One such modification allows the measurement of DNA cross-links by assessing the relative reduction in DNA migration induced by a strand-breaking agent. Another modification includes the application of fluorescent in situ hybridisation (FISH) to investigate the localisation of specific gene domains within a cell. Although several studies have used these approaches separately, no report to date has combined these two versions of the Comet assay. The current study describes the modification of the Comet assay, to allow both measurement of mitomycin C (MMC)-induced cross-links and the subsequent application of FISH to study repair in the TP53 gene region. RT4 human bladder cancer cells were treated with 0, 5, 50 and 200 microg/ml MMC to study dose response, whilst for cross-link repair studies, they were treated with 50 microg/ml MMC and allowed to repair for up to 24 h. A clear dose response to MMC was displayed, demonstrable by a marked reduction in DNA migration, whilst repair studies showed that MMC-induced cross-links take at least 24 h to repair fully in RT4 cells. For Comet-FISH experiments, the number and location of TP53 hybridisation spots was also recorded for each cell. In dose response experiments, the number of spots per cell, and per Comet tail, decreased as MMC dose increased. In repair experiments, the number of spots, particularly in the Comet tail, increased as repair time increased. Furthermore, our results suggest that repair of the TP53 gene region is most rapid within the first 4 h following MMC treatment. We conclude that the novel experimental protocol presented here has considerable potential in evaluating DNA damage and sequence-related repair responses to cross-linking agents.