Relationship between double strand break rejoining and G2 block formation in V79 cells

Summary Caffeine and hypertonicity affect the survival of-irradiated Chinese Hamster V79 cells in different ways: while caffeine reduces the shoulder of the dose effect curve, hypertonic treatment mainly affects its final slope suggesting that different types of damage and (or) repair mechanisms are involved. Rejoining of DNA double strand breaks (dsb), as measured by neutral filter elution technique, exhibits a fast and a slow component, indicating that dsb rejoining consists of two different processes. Hypertonicity causes a temporary inhibition of the fast rejoining step but has no effect on the overall rejoining efficiency. Thus, it appears that its sensitizing effect on survival is not correlated with impaired dsb rejoining. Caffeine was found to inhibit the rejoining of dsb even after 6 h but the length of G2 phase was normal. By contrast, hypertonically treated cells are blocked in G2 but rejoining of dsb was normal. From these results we conclude that successful rejoining of part of the dsb involves arresting the cells reversibly in G2.Dedicated to Prof. G. Hotz on his 60^th birthday     

Acceleration of DNA-double strand rejoining during the adaptive response of Chlamydomonas reinhardtii

Newly developed constant-field low voltage electrophoresis (adapted for algae cells by us) was applied to quantify the induction and repair of nuclear DNA double-strand breaks, by measuring the movement of DNA out of the starting wells into the electrophoresis gel using a UV-gel scan and computer analysis of DNA-ethidium bromide fluorescense (Syngene; Gene tools). A cell-wall-less mutant strain of Chlamydomonas reinhardtii (CW15) was used; the DNA and proteins are easily accessible because of the lack of an outer cell wall. Our results showed that giving a small priming dose (50 Gy) led to a small acceleration of dsb rejoining. When the magnitude of the priming dose was progressively increased, there was a corresponding decrease in the fraction of damage remaining at 4 hours after radiation exposure (to a test dose of 500 Gy). This indicates an upregulated rejoining of dsb following exposure of cells to the priming dose, which may be related to the strong adaptive response in this organism. Protein synthesis inhibitors were found to reduce the rate of rejoining of dsb, and from earlier results are known to inhibit the adaptive response. Thus, the adaptive response is likely to be dependent on increased dsb rejoining and depends on de novo protein synthesis. The nature of these proteins has not yet been established. C. reinhardtii CW15 is an attractive model system in which to study the underlying mechanisms of the adaptive response to ionizing radiation, and its underlying link with dsb rejoining. The results are interesting both from a basic biological point of view, and as a means to further understand the response of tumour cells to radiation therapy since the adaptive response has been postulated to determine the shape of the "shoulder" region of the survival curve of cells at low doses of radiation.     

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.     

Cell inactivation and DNA single- and double-strand breaks in cultured mammalian cells irradiated by a thermal neutron beam

The effects on the cellular viability and induction and repair kinetics of DNA strand breaks in HeLa cells were examined after exposure to a thermal neutron beam and compared with those after gamma-irradiation. The thermal neutron survival curve had no initial shoulder. The relative biological effectiveness (r.b.e.) value of the neutron beam was determined to be 2.2 for cell killing (ratio of D0 values), 1.8 and 0.89 for single strand breakage (ssb) by alkaline sedimentation and alkaline elution respectively, and for double strand breakage (dsb) 2.6 by neutral elution. No difference was observed between thermal neutrons and gamma-rays in the repair kinetics of ssb and dsb. It is suggested that the effect induced by the intracellular nuclear reaction, 14N(n,p)14C is mainly responsible for the high r.b.e. values observed.     

Elevated levels of DNA double-strand breaks (dsb) in restriction endonuclease-treated xrs5 cells correlate with the reduced capacity to repair dsb.

Recently we have reported the kinetics of DNA double-strand breaks (dsb) induced in electroporated mammalian (CHO) cells that had been treated with the restriction endonuclease PvuII, as measured by the filter elution assay at the non-denaturing pH of 9.6. A gradual accumulation of dsb was observed over a 24-h incubation period following the restriction endonuclease (RE) treatment and this was attributed to a competition between incision of the DNA by PvuII and dsb repair. In order to test this 'competition' hypothesis we have carried out similar experiments in the radiosensitive xrs5 mutant cell line, which has been shown to be deficient in dsb repair. The levels of dsb monitored by the non-denaturing filter elution assay in the xrs5 cell line treated with PvuII was found to be 3-4 times higher than that found for the wild-type CHO K1 cell line. Levels of dsb were also significantly raised in xrs5 cells treated with BamHI, as compared with the background levels observed in the CHO line. These data lend strong support to the competition hypothesis of simultaneous incision and repair of RE-induced dsb.     

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.     

SYBR Green I staining of pulsed field agarose gels is a sensitive and inexpensive way of quantitating DNA double-strand breaks in mammalian cells.

Pulsed field gel electrophoresis (PFGE) is widely used to measure DNA double strand breaks (dsb). The DNA of cultured cells can be prelabelled with radioactivity, which helps greatly in detection and quantitation of DNA dsb. However, this approach cannot be used with non-cycling cells from biopsy material. We describe a method which uses SYBR Green I to stain DNA in dried agarose gels. DNA is detected and analysed using readily available camera equipment and image analysis software. This method is as sensitive as [3H]thymidine prelabelling of cells and allows DNA dsb to be measured simply and economically in non-cycling cells.     

Differences in accumulation of blunt- and cohesive-ended double-strand breaks generated by restriction endonucleases in electroporated CHO cells.

Restriction endonucleases (RE) have been used in cytogenetic studies to mimic the DNA double-strand break (dsb)-inducing action of radiation. In the experiments presented here, we have treated electroporated CHO cells with RE and have measured the resulting dsb using the filter elution technique under non-denaturing conditions (pH 9.6). PvuII, which generates blunt-ended dsb, gave rise to a significant number of measurable dsb. The frequency of the dsb induced by PvuII is shown to increase over a 3-12-h post-treatment incubation period, which implies that the RE is active in the cell for a considerable length of time. We postulate that the accumulation of dsb reflects a competition between enzymatic incision and repair of the DNA. The presence of araA, a known inhibitor of DNA synthesis, did not affect the frequency of PvuII-induced breaks indicating a lack of an inhibitory effect of araA on the repair of RE-induced dsb. Two RE which cause cohesive-ended dsb, namely BamHI and EcoRI, were found to be ineffective in giving rise to measurable dsb. Our interpretation of this is that for cohesive-ended dsb (caused by BamHI and EcoRI) the rate at which these breaks are rejoined matches or exceeds the rate of enzymatic incision and hence no dsb were observed. In the case of PvuII, the possibly slower rate of repair of blunt-ended termini would on this hypothesis result in the observed net accumulation of dsb.     

Oxidative damage of Chinese hamster fibroblasts induced by t-butyl hydroperoxide and by X-rays

The aim of this study was to investigate the mechanism(s) of X-ray-mediated cell damage in comparison to mechanism(s) of organic hydroperoxide cytotoxicity and to find the main targets for the two different kinds of cell inactivation. Damage of Chinese hamster fibroblasts induced by tert-butyl hydroperoxide (t-BHP) or X-irradiation was measured by the colony-formation assay and the average single colony volume. DNA double-strand breaks (dsb) were determined by constant-field gel electrophoresis. The contents of peroxides, of SH-groups and the size of inactivated cells were tested for oxidative modifications.Oxidative damage of fibroblasts induced by t-BHP or by X-rays inhibits cell proliferation. Simultaneously, irradiation causes an increase of DNA dsb with the dose, while incubation with t-BHP yields only a very few DNA dsb. Neither chemically induced oxidation nor irradiation significantly changed the amount of membrane lipid peroxides. Oxidation with t-BHP but not irradiation leads to a loss of the membrane SH-groups and to an increase of cell diameter.The similar decrease of cell proliferation can be caused by DNA dsb without detectable membrane damage (X-radiation) as by membrane damage with nearly no DNA dsb (chemically induced oxidative stress).     

Measurements of DNA double-strand break yields in E. coli after rapid irradiation and cell inactivation: the effects of inactivation technique and anoxic radiosensitizers

A study has been made of methods for rapidly inactivating cells of E. coli at neutral pH to prevent enzymatic, chemical, or physical modification to DNA damaged by irradiation. The radiation was delivered in a fraction of a second using an electron accelerator. Cell inactivation was with ethanol or a solution (CSE) containing detergent, EDTA, and chloroform. It was found that DNA could be released from irradiated and inactivated cells simply by incubating them with the protease Pronase, and this DNA appeared to be in a form suitable for centrifugational analysis in neutral sucrose gradients. When cells were irradiated in the presence of oxygen, inactivation with ethanol gave a radiation-induced double-strand break (dsb) yield 1.8-fold higher than when inactivation was with CSE. Possible explanations of this are discussed. Using CSE inactivation, an oxygen enhancement ratio for dsb formation of 4.3 was observed and yields of dsb per Gray were in good agreement with results from other laboratories. At concentrations which enhanced cell killing 2.6-fold the "electron-affinic" type anoxic radiosensitizer misonidazole enhanced dsb formation 2.0-fold, whereas the nitroxyl free radical anoxic radiosensitizer norpseudopelletierine-N-oxyl had no significant effect on dsb yield although there was a possible slight enhancement at the higher doses used.     

The level of induced DNA double-strand breakage correlates with cell killing after X-irradiation

The neutral filter elution technique has been used to examine the relationship between X-ray-induced DNA double-strand breakage (dsb) and lethal lesions. The ratios of the different lesions produced by X-irradiation were varied by irradiation in the presence of different radiomodifiers, and in each case the same linear relationship between lethal lesions and induced DNA dsb was found. This relationship also held for cells given a hyperthermic treatment before irradiation. It is concluded that DNA dsb is probably the lethal lesion induced by ionizing radiation.     

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.     

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.     

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.     

An effect of elevated postirradiation pH on the yield of double-strand breaks in DNA from irradiated bacterial cells

Exposure of DNA isolated from irradiated cells of Escherichia coli to a pH of 9.6 caused a marked increase in the yield of double-strand breaks (dsb). The dsb were measured by sedimentation analysis of E. coli chromosomal DNA using neutral sucrose gradients. After incubation for 4 hr at 37 degrees C and pH 9.6 the dsb yields were 95% and 71% higher than when incubation was at pH 7.0 for irradiation under oxic and anoxic conditions, respectively. This effect was not apparent when dsb were induced enzymatically and it was linearly related to radiation dose. After oxic irradiation, the increase in dsb at pH 9.6 was consistent with first-order kinetics over greater than 2 half-lives (t1/2 = 1.6 hr at 37 degrees C). The effect of elevated pH was largely additive to a previously reported increase in dsb yield caused by ethanol. It is proposed that the effects of elevated pH and of ethanol revealed the presence in intracellularly irradiated DNA of previously unidentified sites where both strands of the DNA were damaged as a result of single radiation events. The possible nature of the proposed sites and the relevance of these findings to the "neutral" elution technique are discussed.     

The level of induced DNA double-strand breaks does not correlate with cell killing in X-irradiated mitotic and G1-phase CHO cells

The neutral (pH 9.6) filter elution technique was used to evaluate DNA damage induced in CHO cells irradiated at mitosis or in G1-phase under various incubation and postirradiation treatment conditions. Mitotic and G1/S border cells were more sensitive to radiation than G1 cells with respect to cell killing, but showed similar (G1/S) or lower (M) DNA elution dose--response curves. Similar cell survival and DNA/elution dose--response curves were obtained with plateau-phase cultures containing mainly G1-cells, as well as with G1 cells obtained after division of mitotic cells in either fresh or conditioned medium. However, survival of plateau-phase cells could be modified substantially by delayed-plating or postirradiation treatment with araA. These results, together with previously published observations, indicate that induction of DNA dsb cannot be invoked as an explanation for the variations in radiosensitivity observed through the cycle, or as an explanation for the formation of the survival curve shoulder. It is proposed that repair and fixation of radiation-induced DNA damage, expressed at the cell survival level as repair and fixation of alpha-PLD, are responsible for these effects.     

Coping with DNA double strand breaks

The repair of DNA double strand breaks (dsb) is important for maintaining the physical and genetic integrity of the genome. Moreover, in humans it is associated with the prevention of diseases such as immune deficiencies and cancer. This review briefly explores the fundamental strategies for repairing dsb, examines how cells maximize the fidelity of dsb repair in the cell cycle and discusses the requirements for dsb repair in the context of chromatin.     

2-Chlorodeoxyadenosine inhibits the repair of DNA double-strand breaks and does not inhibit the repair of DNA single-strand breaks in X-irradiated Chinese hamster V79 cells.

The exposure of log-phase Chinese hamster V79 cells to 2-chlorodeoxyadenosine (CdA) for 3 h after X irradiation enhanced the lethal effects of X-rays in a concentration-dependent manner. The enhancement of the killing efficiency of X-rays by CdA was mainly observed in the reduction of quasi-threshold doses (Dq) of the dose-response curves. When the ability of CdA to inhibit the repair of X-ray-induced double- and single-strand breaks (dsb and ssb) of DNA was investigated by neutral- and alkaline-filter elution techniques, respectively, it was observed that 90% of dsb were rejoined in the absence of CdA within 30 min after X irradiation and 15-40% of dsb rejoining was suppressed by co-incubation of the cells with 5-10 microM of CdA for 3 h after X irradiation, whereas almost 100% of ssb were rejoined within 15 min regardless of the presence or absence of CdA. From these results it was concluded that CdA interfered exclusively with the repair of DNA dsb in X-irradiated Chinese hamster V79 cells and thereby increased the lethality of X-rays.     

Rejoining of double strand breaks in normal human and ataxia-telangiectasia fibroblasts after exposure to 60Co gamma-rays, 241Am alpha-particles or bleomycin

The rejoining of DNA double strand breaks (dsb) induced by 60Co gamma-rays, 241Am alpha-particles or bleomycin was measured by neutral filter elution. In agreement with their colony-forming ability, ataxia-telangiectasia cells (AT2BE) and normal fibroblasts exhibited similar dsb rejoining capacity following alpha-irradiation, but showed marked differences in the rejoining kinetics of dsb induced by gamma-rays or bleomycin.     

Mouse but not human embryonic stem cells are deficient in rejoining of ionizing radiation-induced DNA double-strand breaks

Mouse embryonic stem (mES) cells will give rise to all of the cells of the adult mouse, but they failed to rejoin half of the DNA double-strand breaks (dsb) produced by high doses of ionizing radiation. A deficiency in DNA-PK(cs) appears to be responsible since mES cells expressed <10% of the level of mouse embryo fibroblasts (MEFs) although Ku70/80 protein levels were higher than MEFs. However, the low level of DNA-PK(cs) found in wild-type cells appeared sufficient to allow rejoining of dsb after doses <20Gy even in G1 phase cells. Inhibition of DNA-PK(cs) with wortmannin and NU7026 still sensitized mES cells to radiation confirming the importance of the residual DNA-PK(cs) at low doses. In contrast to wild-type cells, mES cells lacking H2AX, a histone protein involved in the DNA damage response, were radiosensitive but they rejoined double-strand breaks more rapidly. Consistent with more rapid dsb rejoining, H2AX(-/-) mES cells also expressed 6 times more DNA-PK(cs) than wild-type mES cells. Similar results were obtained for ATM(-/-) mES cells. Differentiation of mES cells led to an increase in DNA-PK(cs), an increase in dsb rejoining rate, and a decrease in Ku70/80. Unlike mouse ES, human ES cells were proficient in rejoining of dsb and expressed high levels of DNA-PK(cs). These results confirm the importance of homologous recombination in the accurate repair of double-strand breaks in mES cells, they help explain the chromosome abnormalities associated with deficiencies in H2AX and ATM, and they add to the growing list of differences in the way rodent and human cells deal with DNA damage.