Radiation-induced strand breaks in phi X174 replicative form DNA: an improved experimental and theoretical approach

To determine the yield of radiation-induced single-strand, double-strand and potential breaks (breaks which are converted into actual breaks by alkali or heat treatment) oxygenated aqueous solutions of phi X174 supercoiled circular double-stranded (RFI) DNA were irradiated with increasing doses of gamma-irradiation and subjected to electrophoresis on agarose gels both before and after heat treatment. A complete separation was obtained of RFI, RFII (relaxed circle due to one or more single-strand breaks) and RFIII (linear DNA due to one double-strand break). A computer-assisted spectrophotometric procedure was developed, which enabled us to measure very accurately the amount of DNA present in the three DNA fractions. The quantitative changes of each fraction of DNA with dose could be fitted to a straightforward statistical model, which described the dose-dependent formation of the different types of breaks and from which the D37-values of single-strand, potential single-strand and double-strand breaks could be calculated to be 0.42 +/- 0.02, 1.40 +/- 0.25 and 57 +/- 36 Gy respectively. Potential double-strand breaks were not formed significantly under our conditions. In addition the maximum distance between two independently introduced single-strand breaks in opposite strands resulting in a double-strand break could be determined. The values before and after heat treatment are shown to be 29 +/- 6 and 102 +/- 13 nucleotides, respectively.     

The influence of oxygen on the survival and yield of DNA double-strand breaks in irradiated yeast cells.

Survival and induction of DNA double-strand breaks were studied in cells of Saccharomyces cerevisiae irradiated under oxic or anoxic conditions with 30 MeV electrons. A linear relationship between DNA double-strand breakage and dose was found in both cases. The o.e.r.-value for colony forming ability was found to be 1.9 +/- 0.2, whereas the o.e.r.-value for DNA double-strand breakage was 3.0 +/- 0.1. These results are not inconsistent with the idea that DNA double-strand breaks are involved in killing of yeast cells. The frequency of induction of DNA double-strand breaks was found to be 0.74 x 10(-11) double-strand breaks per g/mol per Gy when cells were irradiated under oxygen and 0.24 x 10(-11) double-strand breaks per g/mol per Gy under nitrogen.     

Relation of double-stranded DNA breaks and their repair to cell death and recovery after methylnitrosourea exposure

The yield of DNA double-strand breaks (DSB) in the cells of mouse lymphosarcoma treated with nitrosomethylurea (NMU) was registered by means of elastoviscosimetry. It was shown that after short-term (7 min) treatment with NMU the lesions formed in DNA are efficiently repaired both in complete and conditioned media. After long-term (30 min) treatment DNA was only repaired in complete growth medium. The yield of the first fixed DSB after long-term NMU treatment correlated with the mean lethal dose D0. After short-term NMU treatment the first DSBs are registered in the dose range which is 4-fold higher than D0. The nature of lethal and potentially lethal lesions as well as the participation of various repair systems in the elimination of potentially lethal lesions are discussed.     

Comet assay evaluation of DNA single- and double-strand breaks induction and repair in C3H10T1/2 cells

Ionizing radiation is a potent inducer of DNA damage because it causes single- and double-strand breaks, alkali-labile sites, base damage, and crosslinks. The interest in ionizing radiation is due to its environmental and clinical implications. Single-strand breaks, which are the initial damage induced by a genotoxic agent, can be used as a biomarker of exposure, whereas the more biologically relevant double-strand breaks can be analyzed to quantify the extent of damage. In the present study the effects of ¹³⁷Cs γ-radiation at doses of 1, 5, and 10 Gray on DNA and subsequent repair by C3H10T1/2 cells (mouse embryo fibroblasts) were investigated. Two versions of the comet assay, a sensitive method for evaluating DNA damage, were implemented: the alkaline one to detect single-strand breaks, and the neutral one to identify double-strand breaks. The results show a good linear relation between DNA damage and radiation dose, for both single-strand and double-strand breaks. A statistically significant difference with respect to controls was found at the lowest dose of 1 Gy. Heterogeneity in DNA damage within the cell population was observed as a function of radiation dose. Repair kinetics showed that most of the damage was repaired within 2 h after irradiation, and that the highest rejoining rate occurred with the highest dose (10 Gy). Single-strand breaks were completely repaired 24 h after irradiation, whereas residual double-strand breaks were still present. This finding needs further investigation. This revised version was published online in July 2006 with corrections to the Cover Date.     

Measurement of prompt DNA double-strand breaks in mammalian cells without including heat-labile sites: results for cells deficient in nonhomologous end joining

Ionizing radiation induces prompt single-strand breaks and double-strand breaks in DNA. In addition, labile sites are induced that can be converted to breaks by heat or mild alkali. When such labile lesions are present within multiply damaged sites, additional double-strand breaks can form. Current protocols for measurement of DNA double-strand breaks involve a lysis step at an elevated temperature, and consequently breaks from heat-labile sites will be generated during lysis and will be included in the measurement. However, such sites may not develop into breaks within the cell and therefore may not need DNA double-strand break repair processes for elimination. We present here a new lysis and pulsed-field gel electrophoresis protocol that is carried out entirely at 0-4 degrees C and thus avoids inclusion of heat-labile sites in the measurement. The new recommended lysis procedure involves two steps: The first step includes proteinase K, which has sufficient activity at 0 degrees C to support lysis, and the second step includes a high-salt buffer to further free the DNA from proteins and other cellular structures. Using various tests, we conclude that lysis is sufficient with this procedure to allow accurate determination of double-strand breaks by pulsed-field gel electrophoresis. Using the new protocol, it was found that heat-labile sites account for 30% of the initial number of double-strand breaks measured by conventional protocols after exposure to low-LET radiation. In addition, we show that heat-labile sites that can be converted to double-strand breaks are repaired with fast kinetics and are almost completely eliminated after 1 h at 37 degrees C. A study of cells deficient in nonhomologous end joining reveals that the residual fast repair response typically seen in such cells is solely due to repair at heat-labile sites and is not due to repair of prompt DSBs.     

Enhancement of radiation-induced cell killing and DNA double-strand breaks in a human tumor cell line using nanomolar concentrations of aclacinomycin A.

Several agents that induce differentiation have previously been shown to induce the terminal differentiation of leukemic cells and enhance the radiosensitivity of certain solid tumor cell lines in vitro using millimolar concentrations. We now report that aclacinomycin A (ACM), a potent inducer of leukemic cell differentiation in vitro, can significantly enhance the radiosensitivity of a human colon tumor cell line (Clone A) at a concentration of 10 nM. Based on colony-forming efficiency, the maximum increase in radiosensitivity was found using 15 nM ACM for 3 days with a dose enhancement factor of 1.4 at a surviving fraction of 0.10. This treatment increased cell doubling time, but had no effect on cell-cycle phase distribution. To gain insight into the mechanisms responsible for this radiosensitization, gamma-ray-induced DNA single- and double-strand breaks were examined. Aclacinomycin A had no effect on the induction of DNA single-strand breaks but significantly enhanced the formation of gamma-ray-induced DNA double-strand breaks. The rate or extent of repair of the induced double-strand breaks was not influenced by ACM treatment. These data suggest that ACM, at achievable plasma concentrations, can enhance the radiosensitivity of a human tumor cell line by increasing the initial level of radiation-induced DNA double-strand breaks.     

Visual quantification of DNA double-strand breaks in bacteria.

In this paper, we describe a method for the visualization of double-strand breaks in a single electrostretched Escherichia coli DNA molecule. We also provide evidence that electrostretched or migrated DNA under neutral microgel electrophoresis conditions is made up of individual chromosomes. Using the neutral microgel electrophoresis technique, DNA migration (stretching) was measured and the number of DNA double-strand breaks were counted following exposure of E. coli cells to 0, 12.5, 25, 50, or 100 rad of X-rays. The use of an intense fluorescent dye, YOYO and custom-made slides have helped us in visualizing individual bacterial DNA molecules. Bacterial DNA appears similar in structure compared to electrostretched DNA from human lymphocytes. We were able to detect changes in DNA migration (stretching) induced by an X-ray dose as low as 12.5 rad and an increase in the number of DNA breaks induced by a dose as low as 25 rad. The extent of DNA migration and number of breaks were directly correlated to X-ray dosage.     

Comparative radiation tolerance based on the induction of DNA double-strand breaks in tobacco BY-2 cells and CHO-K1 cells irradiated with gamma rays

Higher plants are generally more tolerant to ionizing radiation than mammals. To explore the radiation tolerance of higher plants, the induction of DNA double-strand breaks (DSBs) by gamma rays was investigated in tobacco BY-2 cells and compared with that in Chinese hamster ovary (CHO)-K1 cells as a reference. This is the first examination of radiation-induced DSBs in a higher plant cell. The resulting DNA fragments were separated by pulsed-field gel electrophoresis and stained with SYBR Green I. The initial yield of DSBs was then quantified from the fraction of DNA fragments shorter than 1.6 Mbp based on the assumption of random distribution of DSBs. The DSB yield in tobacco BY-2 cells (2.0 +/- 0.1 DSBs Gbp(-1) Gy(-1)) was only one-third of that in CHO-K1 cells. Furthermore, the calculated number of DSBs per diploid cell irradiated with gamma rays at the mean lethal dose was five times greater in BY-2 cells (263 +/- 13) than in CHO-K1 cells. These results suggest that the radiation tolerance of BY-2 cells appears to be due not only to a lower induction of DNA damage but also to a more efficient repair of the induced DNA damage.     

Split-dose recovery is due to the repair of DNA double-strand breaks

DNA double-strand breaks are the molecular lesions the repair of which leads to the reappearance of the shoulder observed in split-dose experiments. This conclusion is based on results obtained with the help of a diploid yeast mutant rad 54-3 which is temperature-conditional for the repair of DNA double-strand breaks. Two repair steps must be met to yield the reappearance of the shoulder on a split-dose survival curve: the repair of double-strand breaks during the interval between two doses and on the nutrient agar plate after the second dose. In yeast lethality may be attributable to either an unrepaired double-strand break (i.e. a double-strand break is a potentially lethal lesion) or to the interaction of two double-strand breaks (misrepair of double-strand breaks). Evidence is presented that the two cellular phenomena of liquid holding recovery (repair of potentially lethal damage) and of split-dose recovery (repair of sublethal damage) are based on the repair of the same molecular lesion, the DNA double-strand break.     

Enhancement of radiation-induced DNA double-strand breaks and micronuclei in human colon carcinoma cells by N-methylformamide

The differentiation-inducing agent N-methylformamide (NMF) enhances the sensitivity of some cell lines to ionizing radiation. To elucidate the mechanism of NMF-mediated radiosensitization, we examined the effects of this agent on gamma-ray-induced DNA double-strand breaks and micronuclei in two cell lines, clone A (human colon carcinoma) and HCA-1 (murine hepatocarcinoma). Both cell lines form a better differentiated phenotype upon exposure to NMF, yet only clone A is radiosensitized. The neutral (pH 9.6) elution assay was used to evaluate the effects of this maturational agent on radiation-induced double-strand breaks in these cell lines. Exposure of HCA-1 cells to NMF had no effect on the level of DNA double-strand breaks induced by gamma rays. In clone A cells, however, exposure to NMF enhanced the initial formation of gamma-ray-induced double-strand breaks at each dose tested. The repair of double-strand breaks in both cell lines was not influenced by NMF. As a measure of chromosome fragmentation after irradiation, we evaluated micronuclei using the cytokinesis block method. Exposure to NMF had no effect on radiation-induced micronuclei formation in HCA-1 cells yet significantly enhanced the frequency of micronuclei induced by radiation in clone A cells. In clone A cells, the increases in radiation-induced double-strand breaks and micronuclei as a function of NMF exposure time reached maximums by approximately 72 h. These data suggest that NMF-mediated radiosensitization is the result of an increase in the initial level of radiation-induced DNA double-strand breaks.     

Induction and rejoining of DNA double-strand breaks in human cervix carcinoma cell lines of differing radiosensitivity

Five recently established cell lines of human carcinoma of the cervix of varying radiosensitivity have been used to determine whether the induction or rejoining of DNA double-strand breaks (dsb) shows any correlation with radiosensitivity or radiation recovery capacity. Double-strand DNA breaks have been measured using neutral filter elution at pH 9.6. The number of breaks induced immediately after irradiation with doses of 10 to 40 Gy 60Co gamma rays appeared to show some correlation with radiosensitivity particularly after 10 Gy; the two more radiosensitive lines incurred more breaks than the more radioresistant lines. In addition, the shape of the induction curve with dose was linear for the two sensitive lines but curvilinear for the resistant lines. Despite the dose scales being different, this mirrored their respective cell survival curve shapes. After 30 or 50 Gy irradiation, rejoining of breaks appeared to be rapid and almost complete within 60 min at 37 degrees C for the three resistant lines. However, for the sensitive lines, one line (HX160c) in particular exhibited a reduced rate of dsb rejoining. In addition, a residual level of dsb was present in this line even after allowing rejoining for 3 h. While induction and rejoining of DNA dsb therefore appears to be a factor in determining radiosensitivity, at doses relevant to cellular survival (up to 10 Gy), the greater induction of DNA dsb in radiosensitive lines may play a significant role in determining the cellular response to ionizing radiation.     

Molecular mechanisms of the formation of DNA double-strand breaks and induction of genomic rearrangements.

The probability that damage occurs in closely opposed sites on complementary DNA strands increases when DNA is heavily modified with mutagenic agents. Enzymatic excision of the opposite lesions produces DNA double-strand breaks which give rise to genomic rearrangements (deletions, insertions, etc.). Plasmid systems were developed for studying chemical lesions leading to double-strand breaks and the fate of broken plasmid molecules within bacterial cells. Deletions result from the base-pairing of fortuitously located direct repeats flanking the DNA broken ends; as a consequence, the latter are joined, while the DNA fragment between the direct repeats is deleted. Genomic rearrangements arise during the repair of the DNA double-strand breaks, and both events are due to similar repair enzymes which maintain the integrity of the DNA primary structure when conditions are not stressful. A number of genomic rearrangements and point mutations seem to be predetermined by the DNA primary structure.     

Induction of DNA double-strand breaks in Chinese hamster V79 cells by 2-chlorodeoxyadenosine

2-Chlorodeoxyadenosine was found to induce DNA double-strand breaks as well as cell death in log-phase Chinese hamster V79 cells. The induction of DNA double-strand breaks, measured by a neutral elution technique, was observed after a 2-h incubation of the cells in the presence of 5 microM of 2-chlorodeoxyadenosine, but these breaks were almost rejoined by a subsequent 1-h incubation, even though this drug was present in the medium during incubation. This repair was prevented by the addition of nicotinamide, which is known to inhibit poly(ADP-ribose) synthesis that is strongly associated with the DNA ligation, but not prevented by the addition of 9-beta-D-arabinofuranosyladenine (araA), which is known to inhibit DNA polymerization. These results suggest that the repair of CdA-induced double-strand breaks is achieved by ligation alone without DNA polymerization. When 35 microM of cycloheximide and 1.3 mM of dibutyryl cAMP were added to the medium, it was found that the induction of double-strand breaks by 2-chlorodeoxyadenosine was suppressed, while the cytotoxicity of 2-chlorodeoxyadenosine measured by colony-forming ability was not interfered with. These results suggest that the induction of DNA double-strand breaks is not associated with the cytotoxicity of this drug.     

Duplex-duplex interactions catalyzed by recA protein allow strand exchanges to pass double-strand breaks in DNA

Using gapped circular DNA and homologous duplex DNA cut with restriction nucleases, we show that E. coli RecA protein promotes strand exchanges past double-strand breaks. The products of strand exchange are heteroduplex DNA molecules that contain nicks, which can be sealed by DNA ligase, thereby effecting the repair of double-strand breaks in vitro. These results show that RecA protein can promote pairing interactions between homologous DNA molecules at regions where both are duplex. Moreover, pairing leads to strand exchanges and the formation of heteroduplex DNA. In contrast, strand exchanges are unable to pass a double-strand break in the gapped substrate. This apparent paradox is discussed in terms of a model for RecA-DNA interactions in which we propose that each RecA monomer contains two nonequivalent DNA-binding sites.     

Postreplicational formation and repair of DNA double-strand breaks in UV-irradiated Escherichia coli uvrB cells

The number of DNA double-strand breaks formed in UV-irradiated uvrB recF recB cells correlates with the number of unrepaired DNA daughter-strand gaps, and is dependent on DNA synthesis after UV-irradiation. These results are consistent with the model that the DNA double-strand breaks that are produced in UV-irradiated excision-deficient cells occur as the result of breaks in the parental DNA opposite unrepaired DNA daughter-strand gaps. By employing a temperature-sensitive recA200 mutation, we have devised an improved assay for studying the formation and repair of these DNA double-strand breaks. Possible mechanisms for the postreplication repair of DNA double-strand breaks are discussed.     

Megabase chromatin domains involved in DNA double-strand breaks in vivo.

The loss of chromosomal integrity from DNA double-strand breaks introduced into mammalian cells by ionizing radiation results in the specific phosphorylation of histone H2AX on serine residue 139, yielding a specific modified form named gamma-H2AX. An antibody prepared to the unique region of human gamma-H2AX shows that H2AX homologues are phosphorylated not only in irradiated mammalian cells but also in irradiated cells from other species, including Xenopus laevis, Drosophila melanogaster, and Saccharomyces cerevisiae. The antibody reveals that gamma-H2AX appears as discrete nuclear foci within 1 min after exposure of cells to ionizing radiation. The numbers of these foci are comparable to the numbers of induced DNA double-strand breaks. When DNA double-strand breaks are introduced into specific partial nuclear volumes of cells by means of a pulsed microbeam laser, gamma-H2AX foci form at these sites. In mitotic cells from cultures exposed to nonlethal amounts of ionizing radiation, gamma-H2AX foci form band-like structures on chromosome arms and on the end of broken arms. These results offer direct visual confirmation that gamma-H2AX forms en masse at chromosomal sites of DNA double-strand breaks. The results further suggest the possible existence of units of higher order chromatin structure involved in monitoring DNA integrity.     

Assessment of radiation-induced DNA strand breaks and their repair in unlabeled cells.

Radiation induced damage, i.e., the induction of DNA strand breaks, was studied on the level of single, unlabeled cells. DNA strand breaks were determined by direct partial alkaline unwinding in intact cell nuclei followed by staining with acridine orange, a development of a proposal first described by B. Rydberg (Int J Radiat Biol 46:521-527, 1984). The ratio of green fluorescence (double-stranded DNA) to red fluorescence (single-stranded DNA) in single cells was taken as a measure of DNA strand breaks. CHO-K1 and M3-1 cells irradiated with X-rays show a dose dependent induction of DNA strand breaks. Incubation at 37 degrees C after irradiation leads to repair of breaks. A repair halflife of about 10-11 min can be determined. Cell cycle specific differences in the induction of DNA strand breaks or repair behavior are not detectable at the resolution achieved so far. This new method offers two major advantages: the resolution of DNA damage and repair on the level of single cells and no need for labeling, thereby allowing for DNA damage and repair to be assessed in biopsy material from tumor patients.     

A role for endogenous and radiation-induced DNA double-strand breaks in p53-dependent apoptosis during cortical neurogenesis

Prenatal exposure to low-dose radiation increases the risk of microcephaly and/or mental retardation. Microcephaly is also associated with genetic mutations that affect the non-homologous end-joining pathway of DNA double-strand break repair. To examine the link between these two causal factors, we characterized the neural developmental effects of acute radiation exposure in mouse littermate embryos harboring mutations in the Ku70 and p53 genes. Both low-dose radiation exposure and Ku70 deficiency induced morphologically indistinguishable cortical neuronal apoptosis. Irradiated Ku70-deficient embryos displayed anatomical damage indicative of increased radiosensitivity in the developing cerebral cortex. Deleting the p53 gene not only rescued cortical neuronal apoptosis at all levels but also restored the in vitro growth of Ku70-deficient embryonic fibroblasts despite the presence of unrepaired DNA/chromosomal breaks. The results confirm the role of DNA double-strand breaks as a common causative agent of apoptosis in the developing cerebral cortex. Furthermore, the findings suggest a disease mechanism by which the presence of endogenous DNA double-strand breaks in the newly generated cortical neurons becomes radiomimetic when DNA end joining is defective. This in turn activates p53-dependent neuronal apoptosis and leads to microcephaly and mental retardation.     

Repair of DNA single-strand breaks in X-irradiated yeast. I. Use of the DNA-unwinding method to measure DNA strand breaks

The DNA-unwinding method developed by Ahnstr?m and his coworkers to measure DNA strand breaks in mammalian cells was used to measure single-strand breaks (SSB) in the DNA of intact yeast cells. DNA unwinding, which took place inside the rigid cell wall of yeast, was investigated as a function of time, radiation dose, and of pH and salt concentration of the alkaline solution. After DNA unwinding had taken place, the cell wall was destroyed by partial enzymatic digestion and sonication in the presence of detergents. Fragments of single- and double-stranded DNA were separated using hydroxylapatite chromatography. In this way the most suitable conditions for DNA unwinding within the cell wall were established. The results show that SSB and double-strand breaks (DSB) give rise to different kinetics of DNA unwinding.     

Induction of double-strand breaks by S1 nuclease, mung bean nuclease and nuclease P1 in DNA containing abasic sites and nicks.

Defined DNA substrates containing discrete abasic sites or paired abasic sites set 1, 3, 5 and 7 bases apart on opposite strands were constructed to examine the reactivity of S1, mung bean and P1 nucleases towards abasic sites. None of the enzymes acted on the substrate containing discrete abasic sites. Under conditions where little or no non-specific DNA degradation was observed, all three nucleases were able to generate double-strand breaks when the bistranded abasic sites were 1 and 3 base pairs apart. However, when the abasic sites were further apart, the enzymes again failed to cleave the DNA. These results indicate that single abasic sites do not cause sufficient denaturation of the DNA to allow incision by these single-strand specific endonucleases. The reactivity of these enzymes was also investigated on DNA substrates that were nicked by DNasel or more site-specifically by endonuclease III incision at the discrete abasic sites. The three nucleases readily induced a strand break opposite such nicks.