Time Scale for Rejoining of Bacteriophage λ Deoxyribonucleic Acid Molecules in Superinfected pol+ and polA1 Strains of Escherichia coli After Exposure to 4 MeV Electrons

The time scale for rejoining of radiation-induced deoxyribonucleic acid (DNA) single-strand breaks was measured in the presence and absence of oxygen. The involvement of DNA polymerase I in this repair process was studied. Formation and rejoining of DNA strand breaks were measured in lambda DNA infecting lysogenic pol(+) and polA1 strains of Escherichia coli irradiated by 4 MeV electrons under identical conditions. Irradiation and transfer to alkaline detergent could be completed in less than 180 ms. The initial yields of DNA strand breaks were identical in pol(+) and polA1 host cells and four- to fivefold higher in the presence of oxygen than in nitrogen anoxia. Evidence for the existence of a very fast repair process, independent of DNA polymerase I, was not found, since no rejoining of radiation-induced DNA strand breaks was observed during incubation from 45 ms to 3 s. In pol(+) host cells most of the strand breaks produced in the presence of oxygen were rejoined within the first 30 to 40 s of incubation, whereas no rejoining could be detected within the same period of time in anoxic cells. Since no rejoining of broken lambda DNA molecules was observed in polA1 host cells, it is concluded that the synthetase activity of DNA polymerase I is involved in the rejoining of DNA breaks induced by radiation in the presence of oxygen.     

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.     

Induction and rejoining of gamma-ray-induced DNA single- and double-strand breaks in Chinese hamster AA8 cells and in two radiosensitive clones

The induction and rejoining of gamma-ray-induced DNA strand breaks were measured in a Chinese hamster ovary cell line, AA8, and in two radiosensitive clones (EM9 and NM2) derived from it. The kinetics of recovery from sublethal damage (SLD) and potentially lethal damage (PLD) has previously been characterized in each of these lines [vanAnkeren et al., Radiat. Res., 115, 223-237 (1988)]. No significant differences were observed among the cell lines in the yields of either DNA single-strand breaks (SSBs) or double-strand breaks (DSBs) as assayed by filter elution. Data for SSB rejoining in AA8 and NM2 cells irradiated with 7.5 Gy were fit by a biexponential process (t1/2 values of approximately 4 and 80 min). In comparison, SSB rejoining in EM9 cells was initially slower (t1/2 = 10 min) and a higher level of SSBs was unrejoined 6 h after irradiation. DSB rejoining in AA8 cells assayed at pH 9.6 was also biphasic (t1/2 values of 15 and 93 min), although when assayed at pH 7.0, most (approximately 80%) of the damage was rejoined at a constant rate (t1/2 = 45 min) during the first 2 h. EM9 cells exhibited a slower initial rate of DSB rejoining when assayed at pH 9.6 but showed no difference compared with AA8 cells in DSB rejoining when assayed at pH 7.0. These results indicate that radiosensitive EM9 cells, whose kinetics of recovery from SLD and PLD was the same as that of AA8 cells, have a defect in the fast phase of SSB rejoining but no measurable defect in DSB rejoining. Conversely, NM2 cells, which displayed a reduced shoulder width on their survival curve and decreased recovery from SLD, had no demonstrable defects in the rate or extent of rejoining of DSBs or SSBs. When compared with the SLD and PLD data reported previously, these results suggest that there is no direct correlation between either of these recovery processes and the rejoining of SSBs or DSBs as assayed here.     

Facilitated detection of chromosome break and repair at low levels of ionizing radiation by addition of wortmannin to G1-type PCC fusion incubation

We have measured rejoining kinetics of chromosome breaks using a modified cell fusion-based premature chromosome condensation (PCC) technique in confluent cultures of normal human fibroblasts irradiated at low doses of X-rays. In order to enhance the sensitivity of the fusion-based PCC assay, we added a DNA double strand break (DSB) repair inhibitor wortmannin during the incubation period for PCC/fusion process resulting in a significantly higher yield of G1-type chromosome breaks. The initial number of chromosome breaks (without repair) gave a linear dose response with about 10 breaks per cell per Gy which is about two times higher than the value with the conventional G1-type PCC method. The chromosome rejoining kinetics at 0.5 and 2.0 Gy X-rays reveal a bi-phasic curve with both a fast and a slow component. The fast component (0-30 min) is nearly identical for both doses, but the slow component for 2 Gy kinetics is much slower than that for 0.5 Gy, indicating that the process occurring during this period may be crucial for the ultimate fate of irradiated cells. The chromosome rejoining kinetics obtained here is similar to that of other methods of detecting DNA DSB repair such as the gammaH2AX assay. Our chromosome repair assay is useful for evaluating the accuracy of other assays measuring DNA DSB repair at doses equal or less than 0.5 Gy of ionizing radiation.     

Pulsed-field gel electrophoresis in the measurement of DNA double-strand break repair in xrs-6 and CHO cell lines: DNA degradation under some conditions interferes with the assessment of double-strand break rejoining.

Pulsed-field gel electrophoresis (PFGE) is a sensitive assay for DNA double-strand breaks (DSBs). The application of PFGE to the measurement of DSB rejoining requires attention to conditions after irradiation. When cells are irradiated and incubated while encapsulated in agarose, DNA DSB rejoining appears incomplete or absent due to DNA degradation artifacts. Using PFGE we have measured the DSB rejoining defect in xrs-6 cells and shown how DNA degradation can affect the results.     

Repair of radiation-induced heat-labile sites is independent of DNA-PKcs, XRCC1 and PARP

Ionizing radiation induces a variety of different DNA lesions; in addition to the most critical DNA damage, the DSB, numerous base alterations, SSBs and other modifications of the DNA double-helix are formed. When several non-DSB lesions are clustered within a short distance along DNA, or close to a DSB, they may interfere with the repair of DSBs and affect the measurement of DSB induction and repair. We have shown previously that a substantial fraction of DSBs measured by pulsed-field gel electrophoresis (PFGE) are in fact due to heat-labile sites within clustered lesions, thus reflecting an artifact of preparation of genomic DNA at elevated temperature. To further characterize the influence of heat-labile sites on DSB induction and repair, cells of four human cell lines (GM5758, GM7166, M059K, U-1810) with apparently normal DSB rejoining were tested for biphasic rejoining after gamma irradiation. When heat-released DSBs were excluded from the measurements, the fraction of fast rejoining decreased to less than 50% of the total. However, the half-times of the fast (t(1/2) = 7-8 min) and slow (t(1/2) = 2.5 h) DSB rejoining were not changed significantly. At t = 0, the heat-released DSBs accounted for almost 40% of the DSBs, corresponding to 10 extra DSBs per cell per Gy in the initial DSB yield. These heat-released DSBs were repaired within 60-90 min in all cells tested, including M059K cells treated with wortmannin and DNA-PKcs-defective M059J cells. Furthermore, cells lacking XRCC1 or poly(ADP-ribose) polymerase 1 (PARP1) rejoined both total DSBs and heat-released DSBs similarly to normal cells. In summary, the presence of heat-labile sites has a substantial impact on DSB induction and DSB rejoining rates measured by pulsed-field gel electrophoresis, and heat-labile sites repair is independent of DNA-PKcs, XRCC1 and PARP.     

Misrejoining of DNA double-strand breaks in primary and transformed human and rodent cells: a comparison between the HPRT region and other genomic locations.

Many studies of radiation response and mutagenesis have been carried out with transformed human or rodent cell lines. To study whether the transfer of results between different cellular systems is justified with regard to the repair of radiation-induced DNA double-strand breaks (DSBs), two assays that measure the joining of correct DSB ends and total rejoining in specific regions of the genome were applied to primary and cancer-derived human cells and a Chinese hamster cell line. The experimental procedure involves Southern hybridization of pulsed-field gel electrophoresis blots and quantitative analysis of specific restriction fragments detected by a single-copy probe. The yield of X-ray-induced DSBs was comparable in all cell lines analyzed, amounting to about 1 x 10(-2) breaks/Mbp/Gy. For joining correct DSB ends following an 80 Gy X-ray exposure all cell lines showed similar kinetics and the same final level of correctly rejoined breaks of about 50%. Analysis of all rejoining events revealed a considerable fraction of unrejoined DSBs (15-20%) after 24 h repair incubation in the tumor cell line, 5-10% unrejoined breaks in CHO cells and complete DSB rejoining in primary human fibroblasts. To study intragenomic heterogeneity of DSB repair, we analyzed the joining of correct and incorrect break ends in regions of different gene density and activity in human cells. A comparison of the region Xq26 spanning the hypoxanthine guanine phosphoribosyl transferase locus with the region 21q21 revealed identical characteristics for the induction and repair of DSBs, suggesting that there are no large variations between Giemsa-light and Giemsa-dark chromosomal bands.     

Age-dependent decline in rejoining of X-ray-induced DNA double-strand breaks in normal human lymphocytes

Unstimulated human peripheral blood lymphocytes (HPBL), separated by density centrifugation from anticoagulated whole blood, were X-irradiated (30 Gy) on ice and incubated in medium at 37 degrees C for repair times of 15, 30, and 120 min. Blood donors were 18 normotensive, non-smoking Caucasians aged 23-78, free from overt pathology and not taking any medications. Neutral filter elution was used to assay DNA double-strand break (DSB) induction and completeness of DSB rejoining (plus rejoining of any X-ray-induced alkali-labile sites converted to DSBs in vitro at pH 9.6). After 30 or 120 min repair incubation, the percentage of DSBs rejoined by cells from older donors (aged 66-78 years) was less than half the percentage of DSBs rejoined by cells from younger donors (aged 23-39 and 42-57). When data from the 3 age groups were pooled, the age-related decline in percent DSBs rejoined was significant for repair times 30 min (r = -0.63, p less than 0.005) and 120 min (r = -0.64, p less than 0.005) but not for 15 min (r = -0.04). These age-related declines were observed even though DNA from older donors sustained fewer strand breaks as demonstrated by the negative correlation between donor age and DSB induction (r = -0.65, p less than 0.005). These results suggest that the efficacy of X-ray-induced DSB repair diminishes with in vivo age in unstimulated HPBL.     

Repair of Radiation Damage to Deoxyribonucleic Acid in Germinating Spores of Bacillus subtilis

The repair of deoxyribonucleic acid (DNA) in germinating spores was studied in comparison with that in vegetative cells. Radiation-induced single-strand breaks in the DNA of spores and of vegetative cells of Bacillus subtilis were rejoined during postirradiation incubation. The molecular weight of single-stranded DNA was restored to the level of nonirradiated cells. The rate of the rejoining of DNA strand breaks in irradiated spores was essentially equal to that in irradiated vegetative cells. The rejoining in spores germinating in nutrient medium occurred in the absence of detectable DNA synthesis. In this state, normal DNA synthesis was not initiated. Very little DNA degradation occurred during the rejoining process. On the other hand, in vegetative cells the rejoining process was accompanied by a relatively large amount of DNA synthesis and DNA degradation in nutrient medium. The rejoining occurred in phosphate buffer in vegetative cells but not in spores in which germination was not induced. Chloramphenicol did not interfere with the rejoining process in either germinating spores or vegetative cells, indicating that the rejoining takes place in the absence of de novo synthesis of repair enzyme. In the radiation-sensitive strain uvs-80, the capacity for rejoining radiation-induced strand breaks was reduced both in spores and in vegetative cells, suggesting that the rejoining mechanism of germinating spores is not specific to the germination process.     

Two-lesion kinetic model of double-strand break rejoining and cell killing

Radiobiological models, such as the lethal and potentially lethal (LPL) model and the repair-misrepair (RMR) model, have been reasonably successful at explaining the cell killing effects of radiation. However, the models have been less successful at relating cell killing to the formation, repair and misrepair of double-strand breaks (DSBs), which are widely accepted as the main type of DNA damage responsible for radiation-induced cell killing. A fully satisfactory model should be capable of predicting cell killing for a wide range of exposure conditions using a single set of model parameters. Moreover, these same parameters should give realistic estimates for the initial DSB yield, the DSB rejoining rate, and the residual number of unrepaired DSBs after all repair is complete. To better link biochemical processing of the DSB to cell killing, a two-lesion kinetic (TLK) model is proposed. In the TLK model, the family of all possible DSBs is subdivided into simple and complex DSBs, and each kind of DSB may have its own repair characteristics. A unique aspect of the TLK model is that break ends associated with both kinds of DSBs are allowed to interact in pairwise fashion to form irreversible lethal and nonlethal damages. To test the performance of the TLK model, nonlinear optimization methods are used to calibrate the model based on data for the survival of CHO cells for an extensive set of single-dose and split-dose exposure conditions. Then some of the postulated mechanisms of action are tested by comparing measured and predicted estimates of the initial DSB yield and the rate of DSB rejoining. The predictions of the TLK model for CHO cell survival and the initial DSB yield and rejoining rate are all shown to be in good agreement with the measured data. Studies suggest a yield of about 25 DSBs Gy(-1) cell(-1). About 20 DSBs Gy(-1) cell(-1) are rejoined quickly (15-min repair half-time), and 4 to 6 DSBs Gy(-1) cell(-1) are rejoined very slowly (10- to 15-h repair half-time). Both the slowly and fast-rejoining DSBs make substantial contributions to the killing of CHO cells by radiation. Although the TLK model provides a much more satisfactory formalism to relate biochemical processing of DSBs to cell killing than did the earlier kinetic models, some small differences among the measured and predicted CHO cell survival and DSB rejoining data suggest that additional factors and processes not considered in the present work may affect biochemical processing of DSBs and hence cell killing.     

Evidence for complexity at the nanometer scale of radiation-induced DNA DSBs as a determinant of rejoining kinetics

The rejoining kinetics of double-stranded DNA fragments, along with measurements of residual damage after postirradiation incubation, are often used as indicators of the biological relevance of the damage induced by ionizing radiation of different qualities. Although it is widely accepted that high-LET radiation-induced double-strand breaks (DSBs) tend to rejoin with kinetics slower than low-LET radiation-induced DSBs, possibly due to the complexity of the DSB itself, the nature of a slowly rejoining DSB-containing DNA lesion remains unknown. Using an approach that combines pulsed-field gel electrophoresis (PFGE) of fragmented DNA from human skin fibroblasts and a recently developed Monte Carlo simulation of radiation-induced DNA breakage and rejoining kinetics, we have tested the role of DSB-containing DNA lesions in the 8-kbp-5.7-Mbp fragment size range in determining the DSB rejoining kinetics. It is found that with low-LET X rays or high-LET alpha particles, DSB rejoining kinetics data obtained with PFGE can be computer-simulated assuming that DSB rejoining kinetics does not depend on spacing of breaks along the chromosomes. After analysis of DNA fragmentation profiles, the rejoining kinetics of X-ray-induced DSBs could be fitted by two components: a fast component with a half-life of 0.9+/-0.5 h and a slow component with a half-life of 16+/-9 h. For alpha particles, a fast component with a half-life of 0.7+/-0.4 h and a slow component with a half-life of 12+/-5 h along with a residual fraction of unrepaired breaks accounting for 8% of the initial damage were observed. In summary, it is shown that genomic proximity of breaks along a chromosome does not determine the rejoining kinetics, so the slowly rejoining breaks induced with higher frequencies after exposure to high-LET radiation (0.37+/-0.12) relative to low-LET radiation (0.22+/-0.07) can be explained on the basis of lesion complexity at the nanometer scale, known as locally multiply damaged sites.     

Different oxygen enhancement ratios for induced and unrejoined DNA double-strand breaks in eukaryotic cells

DNA double-strand breaks (DSBs) are 2.9 times more frequently induced in yeast cells exposed to sparsely ionizing 30-MeV electrons under oxic compared to anoxic conditions. The rejoining of DSBs induced under anoxic conditions was investigated under conditions allowing repair of potentially lethal damage and compared to the rejoining of DSBs induced in oxic cells. In contrast to the biphasic rejoining kinetics of DSBs induced in oxic cells, the rejoining kinetics of DSBs induced in anoxic cells is complicated by the formation of secondary DSBs. These arise during postirradiation incubation of cells, presumably as a consequence of repair processes acting on radiation-induced lesions other than DSBs. These secondary DSBs may at least partially explain the finding that a greater fraction of unrejoinable DSBs is present in cells irradiated under anoxic compared to oxic conditions. As a consequence, the oxygen enhancement ratio of the yield of the remaining DSBs is decreasing in the course of DSB rejoining.     

Tying up loose ends: nonhomologous end-joining in Saccharomyces cerevisiae

The ends of chromosomal DNA double-strand breaks (DSBs) can be accurately rejoined by at least two discrete pathways, homologous recombination and nonhomologous end-joining (NHEJ). The NHEJ pathway is essential for repair of specific classes of DSB termini in cells of the budding yeast Saccharomyces cerevisiae. Endonuclease-induced DSBs retaining complementary single-stranded DNA overhangs are repaired efficiently by end-joining. In contrast, damaged DSB ends (e.g., termini produced by ionizing radiation) are poor substrates for this pathway. NHEJ repair involves the functions of at least 10 genes, including YKU70, YKU80, DNL4, LIF1, SIR2, SIR3, SIR4, RAD50, MRE11, and XRS2. Most or all of these genes are required for efficient recombination-independent recircularization of linearized plasmids and for rejoining of EcoRI endonuclease-induced chromosomal DSBs in vivo. Several NHEJ mutants also display aberrant processing and rejoining of DSBs that are generated by HO endonuclease or formed spontaneously in dicentric plasmids. In addition, all NHEJ genes except DNL4 and LIF1 are required for stabilization of telomeric repeat sequences. Each of the proteins involved in NHEJ appears to bind, directly or through protein associations, with the ends of linear DNA. Enzymatic and/or structural roles in the rejoining of DSB termini have been postulated for several proteins within the group. Most yeast NHEJ genes have homologues in human cells and many biochemical activities and protein:protein interactions have been conserved in higher eucaryotes. Similarities and differences between NHEJ repair in yeast and mammalian cells are discussed.     

DNA repair in the context of chromatin: new molecular insights by the nanoscale detection of DNA repair complexes using transmission electron microscopy

The recognition and repair of DNA double-strand breaks (DSBs) occurs in the context of highly structured chromatin. Here, we established a transmission electron microscopy (TEM) approach to localize gold-labeled DSB repair components in different chromatin environments within the intact nuclear architecture of cells in irradiated mouse tissues. The ultra-high resolution of TEM offers the intriguing possibility of detecting core components of the DNA repair machinery at the single-molecule level and visualizing their molecular interactions with specific histone modifications. By labeling phosphorylated Ku70, which binds directly to broken DNA ends in preparation for rejoining, this TEM approach can monitor formation and repair of actual DSBs in euchromatic versus heterochromatic regions. While DNA lesions in euchromatin are detected and rejoined without any delay, DNA packaging in heterochromatin appears to retard DSB processing, leading to slower repair kinetics. Of significance, the assembly of γH2AX, MDC1, and 53BP1 occurs exclusively at DSBs in heterochromatic (characterized by H3K9me3), but not euchromatic domains, suggesting involvement in localized chromatin decondensation (which increases heterochromatic DNA accessibility). Collectively, this TEM approach provides fascinating insights into the dynamic events of the DSB repair process that depend decisively upon the actual chromatin structure around the break.     

Noncomplementary DNA double-strand-break rejoining in bacterial and human cells.

We examined the rejoining of noncomplementary restriction enzyme-produced DNA double-strand breaks in Escherichia coli and in cultured human cells. The enzymes used in this study, ClaI, BamHI and SalI, produce double-strand breaks with 5 protruding single strands. The joining of a ClaI-produced DNA end to a BamHI-produced end or to a SalI-produced end was examined at the DNA sequence level. End rejoining in E.coli was studied by transforming cultures with linear plasmid DNA that was gel purified from restriction digests, and end rejoining in cultured human cells was studied by introducing enzymes into the cells by electroporation. The human cells used contain an Epstein-Barr virus (EBV)-based shuttle vector, pHAZE, that was recovered and introduced into E.coli for further analysis. The major products of DNA end-joining processes observed in linear plasmid-transformed E.coli and in the human cells exposed to restriction enzymes were identical. Furthermore, the deletions observed in both systems and in the spontaneous mutant plasmids in untreated human cells had a common underlying feature: short stretches of directly repeated DNA at the junction sites.     

DNA strand breaking and rejoining in response to ultraviolet light in normal human and xeroderma pigmentosum cells.

We describe a reproducible technique for measuring DNA strand breaking and rejoining in cells after treatment with U.V.-light. Results obtained with normal human cells, xeroderma pigmentosum cells (XP, complementation group A) and XP variant cells suggest that all three of these cell-types can carry out single-strand incision with equal rapidity. However, the breaks so induced appeared to be only slowly rejoined in the XP variant cells and rejoined not at all in XP complementation group A cells. Furthermore, parental strand rejoining was inhibited by caffeine in XP variant cells but not in normal cells.     

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.     

Repair of cross-linked DNA and survival of Escherichia coli treated with psoralen and light: effects of mutations influencing genetic recombination and DNA metabolism.

Repair of cross-linked DNA was studied in Escherichia coli strains carrying mutations affecting DNA metabolism. In wild-type cells, DNA strands cut during cross-link removal were rejoined during a subsequent incubation into high-molecular-weight molecules. This rejoining was dependent on gene products involved in genetic recombination. A close correlation was found relating recombination proficiency, the rate of strand rejoining, and formation of viable progeny after DNA cross-linking by treatment with psoralen and light. Wild-type cells and other mutants which were Rec+ (sbcB, recL, recL sbcB, recB recC sbcA, recB recC sbcB, xthA1, and xthA11) rejoined cut DNA strands at a rate of 0.8 +/- 0.1 min -1 at 37 degrees C and survived 53 to 71 cross-links per chromosome. recB, recC, recB recC, recF, or polA strains showed reduced rates of strand rejoining and survived 4 to 13 cross-links per chromosome. Recombination-deficient strains (recA, recB recC sbcB recF, recB recL) and lexA failed to rejoin DNA strands after crosslink removal and were unable to form colonies after treatments producing as few as one to two cross-links per chromosome. Strand rejoining occurred normally in cells with mutations affecting DNA replication (dnaA, danB, dnaG, and dnaE) under both permissive and nonpermissive conditions for chromosome replication. In a polA polB dnaE strain strand rejoining occurred at 32 degree C but not at 42 degree C, indicating that some DNA synthesis was required for formation of intact recombinant molecules.     

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.     

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.