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.     

Defective repair of DNA single- and double-strand breaks in the bleomycin- and X-ray-sensitive Chinese hamster ovary cell mutant, BLM-2

Using filter elution techniques, we have measured the level of induced single- and double-strand DNA breaks and the rate of strand break rejoining following exposure of two Chinese hamster ovary (CHO) cell mutants to bleomycin or neocarzinostatin. These mutants, designated BLM-1 and BLM-2, were isolated on the basis of hypersensitivity to bleomycin and are cross-sensitive to a range of other free radical-generating agents, but exhibit enhanced resistance to neocarzinostatin. A 1-h exposure to equimolar doses of bleomycin induces a similar level of DNA strand breaks in parental CHO-K1 and mutant BLM-1 cells, but a consistently higher level is accumulated by BLM-2 cells. The rate of rejoining of bleomycin-induced single- and double-strand DNA breaks is slower in BLM-2 cells than in CHO-K1 cells. BLM-1 cells show normal strand break repair kinetics. The level of single- and double-strand breaks induced by neocarzinostatin is lower in both BLM-1 and BLM-2 cells than in CHO-K1 cells. The rate of repair of neocarzinostatin-induced strand breaks is normal in BLM-1 cells but retarded somewhat in BLM-2 cells. Thus, there is a correlation between the level of drug-induced DNA damage in BLM-2 cells and the bleomycin-sensitive, neocarzinostatin resistant phenotype of this mutant. Strand breaks induced by both of these agents are also repaired with reduced efficiency by BLM-2 cells. The neocarzinostatin resistance of BLM-1 cells appears to be a consequence of a reduced accumulation of DNA damage. However, the bleomycin-sensitive phenotype of BLM-1 cells does not apparently correlate with any alteration in DNA strand break induction or repair, as analysed by filter elution techniques, suggesting an alternative mechanism of cell killing.     

Role of Ku80-dependent end-joining in delayed genomic instability in mammalian cells surviving ionizing radiation

Ionizing radiation induces delayed destabilization of the genome in the progenies of surviving cells. This phenomenon, which is called radiation-induced genomic instability, is manifested by delayed induction of radiation effects, such as cell death, chromosome aberration, and mutation in the progeny of cells surviving radiation exposure. Previously, there was a report showing that delayed cell death was absent in Ku80-deficient Chinese hamster ovary (CHO) cells, however, the mechanism of their defect has not been determined. We found that delayed induction of DNA double strand breaks and chromosomal breaks were intact in Ku80-deficient cells surviving X-irradiation, whereas there was no sign for the production of chromosome bridges between divided daughter cells. Moreover, delayed induction of dicentric chromosomes was significantly compromised in those cells compared to the wild-type CHO cells. Reintroduction of the human Ku86 gene complimented the defective DNA repair and recovered delayed induction of dicentric chromosomes and delayed cell death, indicating that defective Ku80-dependent dicentric induction was the cause of the absence of delayed cell death. Since DNA-PKcs-defective cells showed delayed phenotypes, Ku80-dependent illegitimate rejoining is involved in delayed impairment of the integrity of the genome in radiation-survived cells.     

Transfection of a human gene for the repair of X-ray- and EMS-induced DNA damage

EM9 cells are a line of Chinese hamster ovary cells that are sensitive to killing by ethylmethanesulfonate (EMS) and X ray, since they are unable to repair the DNA damage inflicted by these agents. Through DNA-mediated gene transfer, human DNA and a selectable marker gene, pSV2neo, were transfected into EM9 cells. Resistant clones of transfected cells were selected for by growth in EMS and G418 (an antibiotic lethal to mammalian cells not containing the transfected neo gene). One primary clone (APEX1) and one secondary clone (TEMS2) were shown to contain both marker and human DNA sequences by Southern blot. In cell survival studies, APEX1 was shown to be as resistant to EMS and X ray as the parental cell type AA8 (CHO cells). TEMS2 cells were found to be partially resistant to EMS and X ray, displaying an intermediate phenotype more sensitive than AA8 cells but more resistant than EM9 cells. Alkaline elution was used to assess the DNA strand-break rejoining ability of these cells at 23 degrees C. APEX1 cells showed DNA repair capacity equal to that of AA8 cells; 75% of the strand breaks were repaired with a rejoining T 1/2 of 3 min. TEMS2 showed similar levels of repair but a T 1/2 for repair of 9 min. EM9 cells repaired only 25% of the breaks and showed a T 1/2 for repair of 16 min. The DNA repair data are consistent with the survival data in that the more resistant cell lines showed a greater capacity for DNA repair. The data support the conclusion that APEX1 and TEMS2 cells contain a human DNA repair gene.     

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.     

Increased chromosomal radiosensitivity of a Chinese hamster ovary cell line that inducibly expresses the Eco RI restriction endonuclease

We have transfected a Chinese hamster ovary cell line (CHO 6) with a plasmid that inducibly expresses the Eco RI restriction endonuclease gene in the presence of cadmium sulfate (CdSO4). Expression of Eco RI results in DNA double-strand breaks, which can lead to chromosome aberrations. The new line, designated CHO 10, also has a low level of constitutive expression of Eco RI in the absence of CdSO4 without any cytogenetic effect. This suggested that these cells may be efficient at repairing low levels of DNA double-strand breaks. To test this, both cell lines were exposed to ionizing radiation, and aberration yields were analyzed with or without induction of Eco RI. CHO 10 cells showed increased radiosensitivity after G1 irradiation, but after G2 exposure, only doses greater than or equal to 0.4 Gy caused more damage in CHO 10 cells. We conclude that CHO 10 cells can tolerate constitutive expression of Eco RI, but that when the cells are subjected to additional stress, in this case ionizing radiation, they become very sensitive to DNA double-strand breaks.     

Repair of DNA double-strand breaks in Escherichia coli, which requires recA function and the presence of a duplicate genome.

A method was devised for extracting, from cells of Escherichia coli K12, DNA molecules which sedimented on neutral sucrose gradients as would be expected for free DNA molecules approaching the genome in size. Gamma ray irradiation of oxygenated cells produced 0.20 DNA double-strand breaks per kilorad per 10⁹ daltons. Incubation after irradiation of cells grown in K medium, with four to five genomes per cell, showed repair of the double-strand breaks. No repair of double-strand breaks was found in cells grown in aspartate medium, with only 1.3 genomes per cell, although DNA single-strand breaks were still efficiently repaired. Cells which were recA^? or recA^?recB^? also did not repair double-strand breaks. These results suggest that repair of DNA double-strand breaks may occur by a recombinational event involving another DNA double helix with the same base sequence.     

Mechanism of radiosensitization by halogenated pyrimidines: effect of BrdU on repair of DNA breaks, interphase chromatin breaks, and potentially lethal damage in plateau-phase CHO cells.

There is evidence suggesting that radiosensitization induced in mammalian cells by substitution in the DNA of thymidine with BrdU has a component that relies on inhibition of repair and/or fixation of radiation damage. Here, experiments designed to study the mechanism of this phenomenon are described. The effect of BrdU incorporation into DNA was studied on cellular repair capability, rejoining of interphase chromosome breaks, as well as induction and rejoining of DNA double- and single-stranded breaks (DSBs and SSBs) in plateau-phase CHO cells exposed to X rays. Repair of potentially lethal damage (PLD), as measured by delayed plating of plateau-phase cells, was used to assay cellular repair capacity. Rejoining of interphase chromosome breaks was assayed by means of premature chromosome condensation (PCC); induction and rejoining of DNA DSBs were assayed by pulsed-field gel electrophoresis and induction and rejoining of DNA SSBs by DNA unwinding. A decrease was observed in the rate of repair of PLD in cells grown in the presence of BrdU, the magnitude of which depended upon the degree of thymidine replacement. The relative increase in survival caused by PLD repair was larger in cells substituted with BrdU and led to a partial loss of the radiosensitizing effect compared to cells tested immediately after irradiation. A decrease was also observed in the rate of rejoining of interphase chromosome breaks as well as in the rate of rejoining of the slow component of DNA DSBs in cells substituted with BrdU. The time constants measured for the rejoining of the slow component of DNA DSBs and of interphase chromosome breaks were similar both in the presence and in the absence of BrdU, suggesting a correlation between this subset of DNA lesions and interphase chromosome breaks. It is proposed that a larger proportion of radiation-induced potentially lethal lesions becomes lethal in cells grown in the presence of BrdU. Potentially lethal lesions are fixed via interaction with processes associated with cell cycle progression in cells plated immediately after irradiation, but can be partly repaired in cells kept in the plateau-phase. It is hypothesized that fixation of PLD is caused by alterations in chromatin conformation that occur during normal progression of cells throughout the cell cycle.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Repair of DNA damage induced by accelerated heavy ions in mammalian cells proficient and deficient in the non-homologous end-joining pathway

Human and rodent cells proficient and deficient in non-homologous end joining (NHEJ) were irradiated with X rays, 70 keV/microm carbon ions, and 200 keV/microm iron ions, and the biological effects on these cells were compared. For wild-type CHO and normal human fibroblast (HFL III) cells, exposure to iron ions yielded the lowest cell survival, followed by carbon ions and then X rays. NHEJ-deficient xrs6 (a Ku80 mutant of CHO) and 180BR human fibroblast (DNA ligase IV mutant) cells showed similar cell survival for X and carbon-ion irradiation (RBE = approximately 1.0). This phenotype is likely to result from a defective NHEJ protein because xrs6-hamKu80 cells (xrs6 cells corrected with the wild-type KU80 gene) exhibited the wild-type response. At doses higher than 1 Gy, NHEJ-defective cells showed a lower level of survival with iron ions than with carbon ions or X rays, possibly due to inactivation of a radioresistant subpopulation. The G(1) premature chromosome condensation (PCC) assay with HFL III cells revealed LET-dependent impairment of repair of chromosome breaks. Additionally, iron-ion radiation induced non-repairable chromosome breaks not observed with carbon ions or X rays. PCC studies with 180BR cells indicated that the repair kinetics after exposure to carbon and iron ions behaved similarly for the first 6 h, but after 24 h the curve for carbon ions approached that for X rays, while the curve for iron ions remained high. These chromosome data reflect the existence of a slow NHEJ repair phase and severe biological damage induced by iron ions. The auto-phosphorylation of DNA-dependent protein kinase catalytic subunits (DNA-PKcs), an essential NHEJ step, was delayed significantly by high-LET carbon- and iron-ion radiation compared to X rays. This delay was further emphasized in NHEJ-defective 180BR cells. Our results indicate that high-LET radiation induces complex DNA damage that is not easily repaired or is not repaired by NHEJ even at low radiation doses such as 2 Gy.     

Biochemical evidence for two different mechanisms for bleomycin-induced cell killing.

Using pulsed-field gel electrophoresis, we have measured the ability of two bleomycin-sensitive mutants, XR-1 and BL-10, to repair DNA double-strands breaks (DSB). XR-1 was originally isolated by its hypersensitivity to killing with ionizing radiation, but we have also shown that it is sensitive to killing with bleomycin. In contrast, BL-10 was isolated by its extreme sensitivity to killing with bleomycin, and it is not cross-sensitive to other DNA breaking agents. A 1-h treatment of bleomycin induces a similar number of DNA double-strand breaks in XR-1, BL-10 and CHO cells. However, XR-1 is unable to repair bleomycin-induced DNA double-strand breaks, whereas BL-10 possesses the same kinetics of repair as parental CHO. These data lead us to conclude that at least two mechanisms of killing exist for bleomycin; one of them is DNA DSB-dependent, and the other seems to be DNA DSB-independent.     

Rejoining kinetics of DNA single- and double-strand breaks in normal and DNA ligase-deficient cells after exposure to ultraviolet C and gamma radiation: an evaluation of ligating activities involved in different DNA repair processes

The repair kinetics for rejoining of DNA single- and double-strand breaks after exposure to UVC or gamma radiation was measured in cells with deficiencies in DNA ligase activities and in their normal counterparts. Human 46BR cells were deficient in DNA ligase I. Hamster EM9 and EM-C11 cells were deficient in DNA ligase III activity as a consequence of mutations in the XRCC1 gene. Hamster XR-1 cells had mutation in the XRCC4 gene, whose product stimulates DNA ligase IV activity. DNA single- and double-strand breaks were assessed by the comet assay in alkaline conditions and by the technique of graded-field gel electrophoresis in neutral conditions, respectively. 46BR cells, which are known to re-ligate at a reduced rate the DNA single-strand breaks incurred during processing of damage induced by UVC but not gamma radiation, were shown to have a normal repair of radiation-induced DNA double-strand breaks. EM9 cells exhibited a reduced rate of rejoining of DNA single-strand breaks after exposure to ionizing radiation, as reported previously, as well as UVC radiation. EM-C11 cells were deficient in the repair of radiation-induced-DNA single-strand breaks but, in contrast to EM9 cells, demonstrated the same kinetics as the parental cell line in the resealing of DNA breaks resulting from exposure to UVC radiation. Both EM9 and EM-C11 cells displayed a significant defect in rejoining of radiation-induced-DNA double-strand breaks. XR-1 cells were confirmed to be highly deficient in the repair of radiation-induced DNA double-strand breaks but appeared to rejoin DNA single-strand breaks after UVC and gamma irradiation at rates close to normal. Taken together these results indicate that: (1) DNA ligase I is involved only in nucleotide excision repair; (2) DNA ligase IV plays an important role only in repair of DNA double-strand breaks; and (3) DNA ligase III is implicated in base excision repair and in repair of DNA double-strand breaks, but probably not in nucleotide excision repair.     

Repair of gamma-ray induced DNA strand breaks in the radiation-sensitive mutant rad18-2 of Saccharomyces cerevisiae

The repair of gamma-ray induced DNA single and double-strand breaks was looked at in wild type and rad18-2 strains of the yeast Saccharomyces cerevisiae using sucrose gradient centrifugation. It was found that rad18-2 diploid cells could repair single and double-strand breaks induced by gamma-rays. It was also found that rad18-2 cells experienced a breakup of their DNA during post-irradiation incubation to a size smaller than seen in cells just receiving irradiation. This breakup of DNA in rad18-2 cells is not degradation due to cell death since wild type cells irradiated to similar low survival levels do not show this breakup of DNA with 8 h incubation. The breakup of DNA in rad18-2 cells is not due to replication gaps being formed by synthesis on a damaged template since treatment of rad18-2 a mating type cells with alpha factor, to prevent initiation of DNA synthesis, does not prevent breakup of the DNA.     

Characterization of an X-ray-hypersensitive mutant of V79 Chinese hamster cells

A V79 Chinese hamster cell line XR-V15B exhibiting hypersensitivity to X-ray has been isolated and characterized. Additionally to increased X-ray-sensitivity (approximately 8-fold, as judged by D10 values), cross-sensitivity to bleomycin (3-fold increase), 4NQO (3-fold), H2O2, EMS, MMS (2-fold) were observed also. No increased sensitivity to UV and MMC was found. Genetic complementation analysis indicates that XR-V15B belongs to the same complementation group as the X-ray-sensitive (xrs) mutants of Chinese hamster ovary (CHO) cells described by Jeggo (1985). Biochemical analysis of XR-V15B confirms this finding: the mutant showed a decreased ability to rejoin double-strand breaks induced by X-ray as measured by neutral elution. After 4 h of repair more than 50% of the double-strand breaks remain in comparison to 3% in V79 cells. No difference was observed between wild-type and XR-V15B cells in the initial number of single-strand breaks induced, in the kinetics of their rejoining and in the final level of unrejoined single-strand breaks. Treatment with 5-azacytidine did not have an effect on the reversion frequency of XR-V15B, contrary to the results obtained with the xrs mutants. XR-V15B has been grown in continuous culture for more than 3 months without evidence of reversion. The mutation induction by X-ray irradiation at the HPRT locus is not significantly increased in the mutant, but at doses giving the same degree of cell killing, XR-V15B cells are hypomutable.     

Induction and repair of double- and single-strand DNA breaks in bacteriophage lambda superinfecting Escherichia coli

Induction and repair of double- and single-strand DNA breaks have been measured after decays of 125I and 3H incorporated into the DNA and after external irradiation with 4 MeV electrons. For the decay experiments, cells of wild type Escherichia coli K-12 were superinfected with bacteriophage lambda DNA labelled with 5'-(125I)iodo-2'-deoxyuridine or with (methyl-3H)thymidine and frozen in liquid nitrogen. Aliquots were thawed at intervals and lysed at neutral pH, and the phage DNA was assayed for double- and single-strand breakage by neutral sucrose gradient centrifugation. The gradients used allowed measurements of both kinds of breaks in the same gradient. Decays of 125I induced 0.39 single-strand breaks per double-strand break. No repair of either break type could be detected. Each 3H disintegration caused 0.20 single-strand breaks and very few double-strand breaks. The single-strand breaks were rapidly rejoined after the cells were thawed. For irradiation with 4 MeV electrons, cells of wild type E. coli K-12 were superinfected with phage lambda and suspended in growth medium. Irradiation induced 42 single-strand breaks per double-strand break. The rates of break induction were 6.75 x 10(-14) (double-strand breaks) and 2.82 x 10(-12) (single-strand breaks) per rad and per dalton. The single-strand breaks were rapidly repaired upon incubation whereas the double-strand breaks seemed to remain unrepaired. It is concluded that double-strand breaks in superinfecting bacteriophage lambda DNA are repaired to a very small extent, if at all.     

Homozygous mutation of MTPAP causes cellular radiosensitivity and persistent DNA double-strand breaks

The study of rare human syndromes characterized by radiosensitivity has been instrumental in identifying novel proteins and pathways involved in DNA damage responses to ionizing radiation. In the present study, a mutation in mitochondrial poly-A-polymerase (MTPAP), not previously recognized for its role in the DNA damage response, was identified by exome sequencing and subsequently associated with cellular radiosensitivity. Cell lines derived from two patients with the homozygous MTPAP missense mutation were radiosensitive, and this radiosensitivity could be abrogated by transfection of wild-type mtPAP cDNA into mtPAP-deficient cell lines. Further analysis of the cellular phenotype revealed delayed DNA repair, increased levels of DNA double-strand breaks, increased reactive oxygen species (ROS), and increased cell death after irradiation (IR). Pre-IR treatment of cells with the potent anti-oxidants, α-lipoic acid and n-acetylcysteine, was sufficient to abrogate the DNA repair and clonogenic survival defects. Our results firmly establish that mutation of the MTPAP gene results in a cellular phenotype of increased DNA damage, reduced repair kinetics, increased cell death by apoptosis, and reduced clonogenic survival after exposure to ionizing radiation, suggesting a pathogenesis that involves the disruption of ROS homeostasis.     

The repair of double-strand DNA breaks correlates with radiosensitivity of L5178Y-S and L5178Y-R cells

To better understand the basis for the difference in radiosensitivity between the variant murine leukemic lymphoblast cell lines L5178Y-R (resistant) and L5178Y-S (sensitive), the production and repair of DNA damage after X irradiation were measured by the DNA alkaline and neutral elution techniques. The initial yield of single-strand DNA breaks and the rates of their repair were found to be the same in both cell lines by the DNA alkaline elution technique. Using the technique of neutral DNA elution, L5178Y-S cells exhibited slightly increased double-strand breakage immediately after irradiation, most significantly at lower doses (i.e., less than 10 Gy). Nevertheless, even at doses that yielded equal initial double-strand breakage of both cell lines, the survival of L5178Y-S cells was significantly less than that of L5178Y-R cells. When the technique of neutral DNA elution was employed to measure the kinetics of DNA double-strand break repair, both cell lines exhibited biphasic fast and slow components of repair. However, the double-strand repair rate was much lower in the radiosensitive L5178Y-S cells than in the L5178Y-R cells (T1/2 of 60 vs 16 min). This difference was more pronounced in the fast-repair component. These results suggest that the repair of double-strand DNA breaks is an important factor determining the radiosensitivity of L5178Y cells.     

Less repair of pyrimidine dimers and single-strand breaks in genes by scid cells.

Severe combined immunodeficient (Scid) mice have a mutation in the catalytic subunit of the DNA binding protein kinase that is involved in repair of double-strand breaks in DNA. To determine if the protein also influences repair of single-strand breaks, we examined the ability of Scid cells to repair lesions introduced by ultraviolet light and gamma-ray irradiation. DNA repair was measured both in total genomic DNA and in specific genes from murine Scid and wildtype fibroblast cell lines. The removal of pyrimidine dimers and repair of strand breaks in genes was measured using quantitative Southern blot analyses. After ultraviolet irradiation, there was no significant difference in the repair of photoproducts in bulk DNA between Scid and wildtype cells, as measured by cellular survival and unscheduled DNA synthesis. However, deficient repair was evident in genes, where Scid cells had 25-50% less repair in the c-myc and dihydrofolate reductase genes. After gamma-irradiation, Scid fibroblasts had 20-35% less repair of DNA breaks in immunoglobulin kappa and heavy constant genes than wildtype cells. The data suggest that intact DNA-PK enzyme is needed for the efficient operation of cellular repair of pyrimidine dimers and single-strand breaks in genes, as well as in its established role in rejoining double-strand breaks.     

Biochemical and cytogenetical characterization of Chinese hamster ovary X-ray-sensitive mutant cells xrs 5 and xrs 6. V. The correlation of DNA strand breaks and base damage to chromosomal aberrations and sister-chromatid exchanges induced by X-irradiation

The X-ray-sensitive Chinese hamster ovary (CHO) mutant cell lines xrs 5 and xrs 6 were used to study the relation between X-ray-induced DNA lesions and biological effects. The frequencies of chromosomal aberrations and sister-chromatid exchanges (SCE) were determined in wild-type CHO-K1 as well as mutants xrs 5 and xrs 6 cells following X-irradiation under aerobic and anaerobic conditions. Furthermore, we used a newly developed immunochemical method (based on the binding of a monoclonal antibody to single-stranded DNA) to assay DNA single-strand breaks (SSBs) induced by gamma-rays in these CHO cells, after a repair time of up to 4 h. For all cell lines tested the frequency of X-ray-induced chromosomal aberrations was strongly increased after irradiation in air compared with hypoxic conditions. When compared to the wild-type line, the xrs mutants known to have a defect in repair of DNA double-strand breaks (DSBs) exhibited a markedly enhanced sensitivity to aerobic irradiation, and a high OER (oxygen enhancement ratio) of 2.8-3.5, compared with 1.8-2 in CHO-K1 cells. The induction of SCE by X-rays was relatively little affected in CHO-K1 irradiated in air compared with hypoxic conditions (OER = 0.8), and in xrs 5 (OER = 0.7). A dose-dependent increase in the frequency of SCEs was obtained in xrs 6 cells treated with X-rays in air, and a further increase by a factor of 2 was evident under hypoxic conditions (OER = 0.4). With the immunochemical assay of SSB following gamma-irradiation, no difference was found between wild-type and mutant strains in the number of SSBs induced. The observed rate of rejoining of SSBs was also the same for all cell lines studied.     

Exponential or shouldered survival curves result from repair of DNA double-strand breaks depending on postirradiation conditions

The yeast mutant rad54-3 is temperature conditional for the rejoining of DNA double-strand breaks, but cells do proliferate at both the restrictive and permissive temperatures. Thus, after irradiation with 30 MeV electrons, survival curves can be obtained which may or may not involve double-strand break rejoining under certain experimental conditions. Because of this special property of rad54-3 cells, it was possible to demonstrate that rejoining of radiation-induced double-strand breaks under nongrowth conditions yields exponential survival curves the slopes of which decrease as a function of the rejoining time. These survival data suggest that, under nongrowth conditions, the rejoining of double-strand breaks is an unsaturated process and lacks binary misrepair. In contrast, whenever rejoining of double-strand breaks occurs under growth conditions, shouldered survival curves are observed. This is true for immediate plating as well as for delayed plating survival curves. It is proposed that it is the unsaturated rejoining of double-strand breaks under nongrowth conditions, lacking binary misrepair, which is responsible for potentially lethal damage repair.