Effects of trypsin on X-ray-induced cell killing, chromosome abnormalities and kinetics of DNA repair in mammalian cells

When cells are trypsinized before irradiation a potentiation of X-ray damage may occur. This is known as the 'trypsin effect'. Potentiation of X-ray damage on cell killing was seen in V79 Chinese hamster cells but was marginal in Chinese hamster ovary (CHO K1) cells and not evident in murine Ehrlich ascites tumour (EAT) cells. Trypsinization did however increase the number of X-ray-induced chromosomal abnormalities in all 3 lines. To investigate the possibility that trypsin acts by digestion of proteins in chromatin, further experiments were performed to monitor DNA damage and repair. Induction of DNA breaks by X-rays was unaffected by trypsin but trypsinized EAT (suspension) cells repaired single-strand breaks (ssb) less rapidly than controls indicating an inhibitory effect of trypsin on ssb repair. However double-strand break (dsb) repair was unaffected by trypsin. It was also found that the EDTA solution in which the trypsin was dissolved also contributes to the inhibition of dsb repair. The results show that trypsinization can enhance X-ray-induced cell killing, chromosomal damage and DNA repair, the effect varying between cell lines.     

Lack of interference of DNA single-strand breaks with the measurement of double-strand breaks in mammalian cells using the neutral filter elution assay.

In this study, the effect of DNA single strand breaks (ssb) on the neutral (pH 9.6) filter elution of DNA from Chinese hamster ovary (CHO K1) cells containing DNA double strand breaks (dsb) was investigated. Protein associated ssb were induced by the inhibition of DNA topoisomerase I with camptothecin (cpt). Protein associated dsb were introduced by treating cells with the DNA topoisomerase II poison; etoposide (VP-16). Protein associated ssb and dsb were converted to ssb and dsb by proteinase K present in the lysis solution. In some experiments dsb were generated by the restriction endonuclease Pvu II. It was found that elution of DNA in the presence and absence of ssb was similar under neutral conditions. This finding is consistent with the view that the fast component of the bi-phasic repair kinetics observed in irradiated mammalian cells with the neutral filter elution technique is not attributable to the interference of ssb with the measurement of dsb, and thus suggests that the two components of repair observed with the neutral filter elution elution technique may represent two different types of dsb or modes of repair of dsb.     

Delayed repair of DNA single-strand breaks does not increase cytogenetic damage

DNA damage and cytogenetic effects of ionizing radiation were investigated in Chinese hamster ovary (CHO) cells and unstimulated human peripheral blood lymphocytes. DNA damage and repair were analysed by alkaline elution under conditions that predominantly measured DNA single-strand breaks (ssb). X-radiation (2.5 Gy) induced ssb in both CHO cells and unstimulated lymphocytes, and the breaks were repaired within 30 and 90 min, respectively. This rapid repair was delayed by the poly(ADP-ribose) polymerase inhibitor, 3-aminobenzamide (3AB). The cytogenetic effects of the 3AB-induced delay in DNA repair were examined by analysing sister chromatid exchange (SCE) frequency in CHO cells and fragmentation of prematurely condensed chromosomes (PCC) in unstimulated human lymphocytes after 2.5 Gy of X-rays. Although 3AB delayed the rejoining of DNA ssb, this delay did not result in increased cytogenetic damage manifested as either SCE or fragmentation of PCC. These results indicate that the rapidly rejoining DNA ssb are not important in the production of chromosome damage.     

Glutathione requirement for the rejoining of radiation-induced DNA breaks in misonidazole-treated cells

The role of glutathione (GSH) in the rejoining of radiation-induced single-strand DNA breaks (ssb) was studied in human fibroblast cultures sensitized to radiation by a 30 min treatment with 1 mM misonidazole (MISO). Hypoxically irradiated cells, deficient in GSH, either inherently, or due to a 16 h incubation with 1 mM buthionine sulphoximine (BSO), rejoined the breaks after MISO treatment at a lower rate and to a lesser extent than did GSH-proficient cells. Without MISO treatment, the hypoxically induced ssb were rejoined in the GSH-deficient cells as effectively as in the proficient cells. It is concluded that a large proportion of the breaks which arise after hypoxic irradiation in the presence of MISO are of a different type to those which arise in the absence of the drug, and require a particular GSH-dependent, enzymatic repair system. This requirement for rejoining in hypoxically irradiated, MISO-treated cells is similar to that seen earlier in MISO-untreated, oxically irradiated cells, and suggests that the ssb induced by radiation in the presence of MISO or oxygen are of a similar nature.     

Differences in repair profiles of interstitial telomeric sites between normal and DNA double-strand break repair deficient Chinese hamster cells

Interstitial Telomeric Repeat Sequence (ITRS) blocks are recognized as hot spots for spontaneous and ionizing radiation-induced chromosome breakage and recombination. Background and ionizing radiation-induced DNA breaks in large blocks of ITRS from Chinese hamster cell lines were analyzed using the DNA Breakage Detection-Fluorescence In Situ Hybridization (DBD-FISH) procedure. Our results indicate an extremely alkali-sensitivity of ITRS. Furthermore, it appears that ITRS blocks exhibit a particular chromatin structure, being enriched in short unpaired DNA segments. These segments could be liable to severe topological stress in highly compacted areas of the genome resulting in their spontaneous fragility and thus explaining their alkali-sensitivity. The induction and repair kinetics of DNA single-strand breaks (ssb) and DNA double-strand breaks (dsb) induced by ionizing radiation were assessed by DBD-FISH on neutral comets using Chinese hamster cells deficient in either DNA-PKcs or Rad51C. Our results indicate that the initial rejoining rate of dsb within ITRS is slower than that in the whole genome, in wild-type cells, demonstrating an intragenomic heterogeneity in dsb repair. Interestingly, in the absence of DNA-PKcs activity, the rejoining rate of dsb within ITRS is not modified, unlike in the whole genome. This was also found in the case of Rad51C mutant cells. Our results suggest the possibility that different DNA sequences or chromatin organizations may be targeted by specific dsb repair pathways. Furthermore, it appears that additional unknown dsb repair pathways may be operational in mammalian cells.     

Radiation-sensitive irs mutants rejoin DNA double-strand breaks with efficiency similar to that of parental V79 cells but show altered response to radiation-induced G2 delay.

Induction and repair of DNA double-strand breaks (dsb) was investigated in plateau phase Chinese hamster V79 cells and three radiosensitive mutant cell lines derived from them, irs-1, irs-2 and irs-3, using a pulsed-field gel electrophoresis assay, Asymmetric Field Inversion Gel Electrophoresis (AFIGE). There was no difference in the induction of DNA dsb per Gy and dalton between the radiosensitive mutant cells and wild-type V79 cells despite the wide differences in their radiosensitivity. Also, repair of DNA dsb proceeded in all cell lines with similar kinetics. In contrast to these observations at the DNA level, irradiation of exponentially growing cells showed a prolonged delay in G2 for irs-2 cells and a shortened delay in G2 for irs-1 cells, as compared to wild-type V79 cells. These results confirm previous observations suggesting that a deficiency in the rejoining of DNA dsb is unlikely to be the cause of the increased radiosensitivity of irs cells, and implicate alterations in postirradiation cell cycle progression as a possible cause for this phenomenon, although the mechanism is not known.     

Repair of DNA single-strand and double-strand breaks in the Chinese hamster xrs 5 mutant cell line as determined by DNA unwinding

The DNA unwinding technique has been used to measure the induction and repair of DNA strand breaks by X-rays in the X-ray-sensitive (xrs 5) mutant and its parent CHO K1 line of Chinese hamster cells. Results show that frequency of induction of DNA strand breaks was the same for both cell lines. The repair of single-strand breaks was found to be slightly slower in xrs 5 over the first 20 min after X-ray exposure, but the level of repair of ssb reached after an incubation of 1h following X-ray exposure in xrs 5 was the same as in CHO K1. Our results also show that the rate of repair of DNA double-strand breaks in xrs 5 cells was clearly slower than that in CHO K1, supporting the conclusion of Kemp et al. (1984) who used the neutral elution technique, that xrs 5 is defective in the repair pathway of DNA double-strand breaks.     

DNA-break repair, radioresistance of DNA synthesis, and camptothecin sensitivity in the radiation-sensitive irs mutants: comparisons to ataxia-telangiectasia cells

Induction and rejoining of DNA single-strand breaks (ssb) and double-strand breaks (dsb) after gamma-irradiation were measured, respectively, by alkaline and neutral sucrose gradient sedimentation methods. The radiosensitive mutants irs1, irs2, and irs3 showed no significant difference from wild-type V79 hamster cells in ability to rejoin either ssb or dsb, while the previously-described xrs-1 mutant showed the expected defect in rejoining dsb. The resistance of DNA synthesis to gamma-irradiation was measured in the 3 irs mutants and, for comparative purposes, in transformed human cell lines from normal and ataxia-telangiectasia (A-T) individuals. The irs2 mutant was found to be very similar in response to the A-T lines, showing a marked decrease in inhibition of DNA synthesis, compared to V79 cells, in both time-course and dose-response experiments. However, irs1 also had some decrease in inhibition at the higher doses used, while irs3 was similar to the wild-type V79 cells. Both irs1 and irs2 were found to be considerably more sensitive to the DNA topoisomerase I-inhibitor camptothecin, while irs3 was only slightly more sensitive than the parent V79 line. These data place the irs mutants in a similar category of radiosensitive phenotype to A-T cells, but we view this as only the beginning of a useful classification of this type of mutant. The irs2 mutant has the strongest links to A-T cells, through its sensitivity profile to DNA-damaging agents and radioresistant DNA synthesis, but irs1 in particular has other similarities to A-T.     

Combined effect of misonidazole and glutathione depletion by buthionine sulphoximine on cellular radiation response

Chinese hamster cells (V79) and glutathione-proficient (GSH+/+) and glutathione-deficient (GSH-/-) human fibroblasts were treated with a glutathione (GSH)-depleting agent buthionine sulphoximine (BSO) and the hypoxic radiosensitizer misonidazole (MISO), separately or in combination. Subsequently, the cells were exposed to X-rays. Determination of the yield of single-strand DNA breaks (ssb) immediately after irradiation indicated no effect of BSO or MISO treatment when radiation exposure was made aerobically. Assuming that ssb determined immediately after irradiation reflects mainly the effect of radical processes, the results obtained with BSO and MISO, singly and in combination, agreed well with the predictions of a modified version of the 'competition model' using V79 and GSH+/+ cells. Some results obtained with GSH-/- cells could not be so explained.     

DNA double-strand break repair in eukaryotic cell lines having radically different radiosensitivities

TN-368 lepidopteran insect cells are on the order of 100 times more resistant to the lethal effects of ionizing radiation than cultured mammalian cells. DNA double-strand breaks (DSB) are believed by many to be the critical molecular lesion leading to cell death. We have therefore compared the rejoining of DSB in TN-368 and V79 Chinese hamster cells. Cells were irradiated on ice with 137Cs gamma rays at a dose rate of 2.5 Gy/min, incubated for various periods of time, and assayed for DNA DSB using the method of neutral elution. The kinetics of DSB rejoining following a dose of 90.2 Gy is similar for both cell lines with 50% of the rejoining completed in about 12 min. Approximately 83 and 87% of the DSB are rejoined in the TN-368 and V79 cells, respectively, by 1 h postirradiation. However, no further rejoining occurs in the TN-368 cells through at least 6 h postirradiation, whereas approximately 92% of the DSB are rejoined in the V79 cells by 2 h postirradiation. Other studies (from 22.6 to 226 Gy) demonstrate that the amount of rejoining of DSB varies inversely with dose for both cell lines, but this relationship is not as pronounced for the TN-368 cells. In general, these findings do not support the hypothesis that unrejoined DNA DSB represent the critical molecular lesion responsible for cell death.     

The p53 status of Chinese hamster V79 cells frequently used for studies on DNA damage and DNA repair.

Chinese hamster lung fibroblast V79 cells have been widely used in studies of DNA damage and DNA repair. Since the p53 gene is involved in normal responses to DNA damage, we have analyzed the molecular genetics and functional status of p53 in V79 cells and primary Chinese hamster embryonic fibroblast (CHEF) cells. The coding product of the p53 gene in CHEF cells was 76 and 75% homologous to human and mouse p53 respectively, and was 95% homologous to the Syrian hamster cells. The V79 p53 sequence contained two point mutations located within a presumed DNA binding domain, as compared with the CHEF cells. Additional immunocytochemical and molecular studies confirmed that the p53 protein in V79 cells was mutated and nonfunctional. Our results indicate that caution should be used in interpreting studies of DNA damage, DNA repair and apoptosis in V79 cells.     

Reduction of intracellular glutathione content and radiosensitivity

The intracellular glutathione (GSH) content of HeLa, CHO and V79 cells was reduced by incubating the cells in growth medium containing buthionine sulphoximine or diethyl maleate (DEM). Clonogenicity, single-strand DNA breaks (ssb) and double-strand DNA breaks (dsb) were used as criteria for radiation-induced damage after X- or gamma-irradiation. In survival experiments, DEM gave a slightly larger sensitization although it gave a smaller reduction of the intracellular GSH. In general, sensitization was larger for dsb than for ssb, also the reduction of the o.e.r. was generally larger for dsb than for ssb. This may be due to the higher dose rate in case of dsb experiments resulting in a higher rate of radiochemical oxygen consumption. In general, no effect was found on post-irradiation repair of ssb and dsb.     

Induction and repair of radiation-induced DNA double-strand breaks in human fibroblasts are not affected by terminal differentiation

It was studied for human skin fibroblasts, whether the induction or repair of DNA double-strand breaks (dsb) depend on the differentiation status. These studies were performed (a) with a fibroblast strain (HSF1) kept in progenitor state (mitotic fibroblasts, MF) or triggered to premature terminal differentiation (postmitotic fibrocytes, PMF) by exposure to mitomycin C or (b) with 20 fibroblast strains differing intrinsically in their differentiation status. The differentiation status was quantified by determining the fraction of postmitotic fibrocytes by light microscopy. DNA dsb were measured by constant-field gel electrophoresis, and the fraction of apoptotic cells by comet assay. MF and PMF cultures of HSF1 cells were irradiated with X-ray doses up to 160 Gy, and dsb were measured either immediately after irradiation or after a repair incubation of 4 or 24 h. There were a difference neither in the number of initial nor residual dsb. PMF cultures, however, showed a slightly higher number of dsb already present in non-irradiated cells, which was measured to result from a small fraction of 5% apoptotic cells. The 20 analysed fibroblast strains showed a substantial variation in the fraction of postmitotic fibrocytes (9-51%) as well as in the number of dsb remaining at 24 h after irradiation (1.9-4.9%), but there was no correlation between these two parameters. These data demonstrate that for fibroblasts the terminal differentiation has an effect neither on the induction nor the repair of radiation-induced dsb. This result indicates that the variation in dsb-repair capacity previously observed for fibroblast strains and which was considered to be the main cause for the variation in the cellular radiosensitivity, cannot be ascribed to differences in the differentiation status.     

The relationship between radiation-induced DNA double-strand breaks and cell kill in hamster V79 fibroblasts irradiated with 250 kVp X-rays, 2.3 MeV neutrons or 238Pu alpha-particles

Using the neutral filter elution technique, the induction of DNA double-strand breaks (dsb) has been measured in 250 kVp X-irradiated V79-379A Chinese hamster cells irradiated under air or nitrogen. The dose-effect curves for induced dsb were curvilinear, mirroring cell survival curves, such that there was an approximately linear relationship between induced dsb and lethal lesions (-In (cell survival)) which was independent of oxygen. With cells irradiated with 2.3 MeV neutrons or 238Pu alpha-particles the correlations between lethal events and dsb, although also approximately linear, do not match those for X-rays. With neutrons there is approximately a 2.5-fold reduction in the level of dsb induction per lethal event. Thus either the apparently linear relationships found are spurious, and there is no general correlation between induced dsb and lethal effect, or there are qualitative differences between neutron, alpha-particle and X-ray induced dsb that give them differing probabilities of cell kill.     

Effects of iron chelators and glutathione depletion on the induction and repair of chromosomal aberrations by tert-butyl hydroperoxide in cultured Chinese hamster cells

The effects of iron chelators and glutathione (GSH) depletion on the induction of chromosomal aberrations by tert-butyl hydroperoxide (t-BuOOH) were investigated in cultured Chinese hamster V79 cells. t-BuOOH in a concentration range of 0.1-1.0 mM induced chromosomal structural aberrations, consisting mainly of chromatid gaps and breaks, in a dose-dependent fashion. The divalent iron chelator o-phenanthroline almost completely suppressed the formation of chromosomal aberrations while the trivalent chelator desferrioxamine was less effective. GSH depletion did not affect the formation of chromosomal aberrations and DNA single-strand breaks (ssb) by t-BuOOH. DNA ssb by 0.5 mM t-BuOOH were repaired within 60 min of treatment in both GSH-depleted (GSH-) and non-depleted (GSH+) cells. In contrast, chromosomal aberrations increased a little during the 60 min after treatment in both GSH- and GSH+ cells. The aberrations were then repaired in GSH+ cells but those in GSH- cells were maintained to a great extent during 20 h of post-treatment incubation. These results indicate that divalent iron mediates the induction of chromosomal aberrations by t-BuOOH. That t-BuOOH-induced chromosomal aberrations remain even after DNA ssb were repaired suggests involvement of other lesions than DNA ssb in the formation of chromosomal aberrations by the hydroperoxide.     

High chromosomal sensitivity of Chinese hamster xrs 5 cells to restriction endonuclease induced DNA double-strand breaks

The cytogenetic effects of restriction endonucleases (RE) and X-rays were examined in the radiosensitive mutant Chinese hamster cell line xrs 5 and its normal parental line CHO K1. Cells were permeabilized with Sendai virus and exposed to Pvu II and Eco RV which induce blunt-ended double-strand breaks (dsb) in the DNA of cells, or Bam H1 and Eco R1 which induce cohesive-ended dsb with a four-base overlap. Treated cells were then assayed for the presence of metaphase chromosomal aberrations by sampling at multiple fixation times and in experiments where cells were exposed to graded series of RE concentrations. Exposure to X-rays or RE causing blunt-ended dsb was found to be between two and three times more effective in xrs 5 than in CHO K1 cells. We interpret this higher chromosomal sensitivity of xrs 5 cells as reflecting the reported defect in dsb repair in xrs 5. Both xrs 5 and CHO K1 cells yielded less aberrations after exposure to Bam H1 or Eco R1 than after exposure to Pvu II or Eco RV, confirming our previous results and demonstrating that cohesive-ended dsb are less damaging than blunt-ended dsb. Multiple fixation time experiments showed that the higher sensitivity of xrs 5 was evident at several different sampling times after treatment. Similarly the low yield of aberrations after exposure of cells to Bam H1 was evident at all sampling times. Overdispersion of chromosomal aberrations was observed in samples exposed to RE. This is thought to be due to a non-uniform permeabilization of the cell population to RE. Our results indicate that RE-induced dsb are handled by cells in a similar way to those arising during X-ray exposure.     

Incomplete rejoining of DNA double-strand breaks in unstimulated normal human lymphocytes

We investigated the repair kinetics of DNA single-strand breaks (SSBs) and double-strand breaks (DSBs) in unstimulated normal human peripheral blood lymphocytes (HPBL). SSBs and DSBs induced by gamma-irradiation (at 0 degree C) were assayed without radiolabel by alkaline and neutral filter elution, respectively. Incubation of irradiated cells at 37 degrees C for various lengths of time demonstrated that the percent DNA rejoined increased until it reached a plateau at approximately 60 min; this repair plateau underwent no substantial change when incubation continued for 20-24 h. The level of the plateau indicated how closely the elution profile of DNA from cells irradiated and incubated (experimental) resembled the elution profile of DNA from unirradiated cells (control). After 6 Gy and 60 min incubation, the alkaline elution profile of DNA from experimental cells from 5 donors was indistinguishable from that seen in DNA from control cells, suggesting that rejoining of SSBs was complete. In contrast after 100 Gy and 60 min incubation the neutral elution profile of DNA from cells from the same donors demonstrated that, compared to DNA from control cells, rejoining of DSBs was approximately two-thirds complete. In the range of 2-8 Gy, 85-104% of SSBs were rejoined after 60 min incubation; in the range of 30-120 Gy, 46-80% of DSBs were rejoined after 60 min incubation. These unexpected results stand in contrast to our previous studies with confluent normal human diploid fibroblasts (HDF), in which rejoining of both SSBs and DSBs was greater than 90% complete by 60 min repair incubation and 100% complete after 18-24 h.     

Differential effects of glutathione depletion and metallothionein induction on the induction of DNA single-strand breaks and cytotoxicity by tert-butyl hydroperoxide in cultured mammalian cells

Induction of DNA single-strand breaks (ssb), their resealing and cytotoxicity by tert-butyl hydroperoxide (t-BuOOH) were investigated in cultured Chinese hamster V79 cells. The effect of the depletion of cellular glutathione (GSH), iron chelation and induction of metallothionein (MT) on these parameters was studied. t-BuOOH in a concentration range of 0.02-0.5 mM induced DNA ssb in a dose-dependent fashion. Strand breakage increased as a function of time up to 1 h. Divalent iron chelator o-phenanthroline suppressed markedly the induction of DNA ssb while the trivalent iron chelator desferrioxamine had no effect. GSH-depletion increased cytotoxicity of t-BuOOH. In contrast, the depletion of GSH did not affect the efficiency of formation of DNA ssb by t-BuOOH and the rate of resealing of the DNA damage. The induction of MT did not influence the efficiency of formation of DNA ssb by t-BuOOH. In summary, while GSH depletion and MT induction affected the formation of DNA ssb and cytotoxicity differently divalent iron was required for both. Therefore, appears likely that DNA breakage and cytotoxicity by t-BuOOH are caused by independent mechanisms.     

Effect of radiomodifying agents on the ratios of X-ray-induced lesions in cellular DNA: use in lethal lesion determination

The effect of three radiomodifying agents, cysteamine, hyperthermia, and hypoxia, on the induction of the major classes of X-ray-induced DNA lesions, was studied using mouse L cells and Chinese hamster V79 cells. The use of filter elution techniques allowed most of these studies to be conducted at X-ray doses within the survival-curve range. Cysteamine was found to protect against DNA single-strand breakage (ssb), DNA base damage, and DNA-protein crosslinkage. Hyperthermia had no effect on the level of DNA ssb or DNA base damage, but in L cells (but not in V79 cells) it increased the level of DNA-protein crosslinkage relative to DNA ssb. Hypoxia protected against DNA ssb, had no significant effect on the level of DNA base damage, and enhanced the level of DNA-protein crosslinkage relative to DNA ssb. These results support the previous suggestion that the X-ray-induced lethal lesion is DNA double-strand breakage. Implications of these findings for the mechanisms of formation of X-ray-induced DNA lesions are also discussed.     

Inhibition of repair of radiation-induced DNA double-strand breaks by nickel and arsenite

The effect of arsenite or nickel on the repair of DNA double-strand breaks (DSBs) was studied in gamma-irradiated Chinese hamster ovary cells using pulsed-field gel electrophoresis. After treatment with nickel chloride or arsenite for 2 h, cells were irradiated with gamma rays at a dose of 40 Gy, and the numbers of DNA DSBs were measured immediately after irradiation as well as at 30 min postirradiation. Both arsenite and nickel(II) inhibited repair of DNA DSBs in a concentration-dependent manner; 0.08 mM arsenite significantly inhibited the rejoining of DSBs, while 76 mM nickel was necessary to observe a clear inhibition. The mean lethal concentrations for the arsenite and nickel(II) treatments were approximately 0.12 and 13 mM, respectively. This indicates that the inhibition of repair by arsenite occurred at a concentration at which appreciable cell survival occurred, but that nickel(II) inhibited repair only at cytotoxic concentrations at which the cells lost their proliferative ability. These novel observations provide insight into the mechanisms underlying the effects of combined exposure to arsenite and ionizing radiation in our environment.