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.     

Double-strand break repair and G2 block in Chinese hamster ovary cells and their radiosensitive mutants

Two X-ray-sensitive mutants of the CHO K1 cell line were examined for their cell-cycle progression after irradiation with gamma-rays, and for their ability to rejoin double-strand breaks (DSBs) as detected by neutral filter elution. Both mutants were impaired in DSB rejoining and both were irreversibly blocked in the G2 phase of the cell cycle as determined by cytofluorometry. From one mutant we have isolated several revertants. The revertants stem from genomic DNA transfection experiments and may have been caused by gene uptake. All revertants survived gamma-irradiation as did the wild-type CHO line. One of them has been examined for its ability to rejoin DSBs and was found to be similar to the wild type.     

Evidence to support the existence of efficient DNA double-strand break rejoining in a radiosensitive mutant of V79-4 following irradiation with 250 kVp X-rays or neutrons

The repair of ionising-radiation-induced DNA double-strand break type damage was measured by Kohn neutral elution in an X-ray-sensitive mutant of V79-4, irs1. This was done in order to investigate further the likelihood that irs1 carries a defect which leads to error-prone repair of DNA damage, and not simply a reduced ability to rejoin DNA double-strand breaks. The mutant displayed an equal increase in sensitivity to the lethal effects of neutrons, as compared to X-rays. Both irs1 and V79-4 showed an increased sensitivity to the killing effects of neutrons of around 2 at 10% survival. irs1 also showed an exponential survival after either X-rays or neutrons. The induction of DNA double-strand breaks was measured in both cell lines over a dose range of 10-40 Gy using Kohn neutral filter elution. Induction of breaks by X-rays in irs1 seemed to increase slightly with dose, relative to induction in V79-4, so that at 40 Gy 1.5 times more DNA double-strand breaks were measured in irs1 cells than in V79-4. Neutron irradiation resulted in a more similar level of induction in either strain after 10-40 Gy. This difference in induction of damage may be due to a different cell-cycle composition in either cell line. The rejoining of X-ray induced double-strand breaks showed a very similar pattern (on a percentage rejoined basis) in both cell lines, although from the induction data at 40 Gy, the dose at which rejoining was measured, fewer breaks were rejoined in V79-4 but also fewer breaks remained unsealed. Neutron-induced breaks, however, were rejoined more efficiently in irs1 again on a percentage basis, but also in absolute terms since similar induction was seen after 40 Gy. This data, together with the differences seen in the rejoining of X-ray compared to neutron induced breaks, may indirectly support the proposal that irs1 is a misrepair mutant.     

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

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

A fourth complementation group among ionizing radiation-sensitive Chinese hamster cell mutants defective in DNA double-strand break repair.

The XR-V9B mutant of Chinese hamster V79 cells which exhibits hypersensitivity to ionizing radiation was isolated by the replica plating technique. The increased sensitivity of XR-V9B cells to X rays (approximately 4-fold, as judged by the D10) was accompanied by increased sensitivity to other DNA-damaging agents such as bleomycin (approximately 17-fold), VP16 (approximately 6-fold), and adriamycin (approximately 5-fold). Only a slightly increased sensitivity was observed after exposure to UV radiation, MMS, or mitomycin C (1.4-, 1.7-, and 2-fold, respectively). As measured by neutral elution after exposure to X rays, XR-V9B cells showed a defect in the rejoining of double-strand breaks (DSBs); after 4 h of repair more than 50% of DSBs remained in comparison to 5% in wild-type cells. No difference was observed in the kinetics of single-strand break rejoining between XR-V9B and wild-type cells, as measured by alkaline elution. To determine whether XR-V9B represents a new complementation group among ionizing radiation-sensitive Chinese hamster cell mutants defective in DSB repair, XR-V9B cells were fused with XR-V15B, XR-1, and V-3 cells, which have impaired DSB rejoining and belong to three different complementation groups. In all cases, the derived hybrids regained the sensitivity of wild-type cells when exposed to X rays, indicating that the XR-V9B mutant represents a new fourth complementation group among X-ray-sensitive Chinese hamster cell mutants defective in DSB repair.     

Repair of Single-Strand Deoxyribonucleic Acid Breaks in Ultraviolet Light-Irradiated Haemophilus influenzae

The wild-type strain and mutants of Haemophilus influenzae, sensitive or resistant to ultraviolet light (UV) as defined by colony-forming ability, were examined for their ability to perform the incision and rejoining steps of the deoxyribonucleic acid (DNA) dark repair process. Although UV-induced pyrimidine dimers are excised by the wild-type Rd and a resistant mutant BC200, the expected single-strand DNA breaks could not be detected on alkaline sucrose gradients. Repair of the gap resulting from excision must be rapid when experimental conditions described by us are employed. Single-strand DNA breaks were not detected in a UV-irradiated sensitive mutant (BC100) incapable of excising pyrimidine dimers, indicating that this mutant may be defective in a dimer-recognizing endonuclease. No single-strand DNA breaks were detected in a lysogen BC100(HP1c1) irradiated with a UV dose large enough to induce phage development in 80% of the cells.     

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.     

The use of integrating DNA vectors to analyse the molecular defects in ionising radiation-sensitive mutants of mammalian cells including ataxia telangiectasia

Integrating DNA vectors, encoding selectable recombinant genes, were used to assess rejoining and recombination in wild-type mammalian cells and their ionising radiation-sensitive mutants. To provide a simple model of an important radiation-induced lesion - the DNA double-strand break - the vectors were cut with restriction endonucleases at specific single sites. If these breaks were made in the coding sequence of a selectable gene, the fidelity of the rejoin/recombination process could be measured by survival of vector-transformed cells in selective medium. Rejoining was assessed using vectors without internal homologies, while recombination was measured using pairs of fragments or deletion vectors carrying homologous regions. Initial experiments were made with vectors carrying a single selectable gene but, to overcome potential artefacts, 2-gene vectors were then constructed where one gene acts as a linked marker and (unbroken) control for the other (broken) gene. Available data are reviewed to show that, compared to their respective wild-type counterparts: (1) an ataxia telangiectasia (A-T) cell line and the hamster irs1 mutant show a consistent reduction in the fidelity of rejoining double-strand breaks (while the hamster mutants irs2, irs3, xrs series, and EM9 show wild-type fidelity); (2) the hamster EM9 mutant shows a reduction in ability to recombine homologous vector fragments (while the A-T line and probably the xrs mutants show show wild-type abilities); and (3) the xrs mutants show a reduction in overall transformation frequency with vector DNA, whether broken or not, while the other mutants tested show approximately wild-type frequencies. A critical account of the techniques and data is given, together with speculations on the molecular nature of the processes which are defective in these mutants, leading to radiosensitivity.     

No change in DNA damage or repair of single- and double-strand breaks as human diploid fibroblasts age in vitro

Using the in vitro human diploid fibroblast model, we tested theories of aging which hypothesize that either accumulation of DNA damage or decreased DNA repair capacity is causally related to cellular senescence. Between population doubling level (PDL) 32 and 71, fetal lung-derived normal diploid human fibroblasts (IMR 90) were assayed for both DNA single-strand breaks (SSBs, spontaneous and induced by 6 Gy) and DNA double-strand breaks (DSBs, spontaneous and induced by 100 Gy). After gamma-irradiation cells were kept on ice unless undergoing repair incubation at 37 degrees C for 7.5-120 min or 18-24 h. To assay DNA strand breaks we used the filter elution technique in conjunction with a fluorometric determination of DNA which is not biased in favor of proliferating aging cells as are radioactive labelling methods. We found no change with in vitro age in the accumulation of spontaneous SSBs or DSBs, nor in the kinetics or completeness of DNA strand rejoining after gamma-irradiation. Cells at varying PDLs rejoined approx. 90% of SSBs and DSBs after 60 min repair incubation and 100% after 18-24 h repair incubation. We conclude that aging and senescence as measured by proliferative lifespan in IMR 90 cells are neither accompanied nor caused by accumulation of DNA strand breaks or by diminished capacity to rejoin gamma-radiation-induced SSBs or DSBs in DNA.     

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.     

Comparative studies on induction and rejoining of DNA single-strand breaks by radiation and chemical carcinogen in mammalian cells in vitro

This study, using the 5–20% alkaline sucrose gradient method, indicated that single-strand breaks of DNA in cultured mammalian cells were induced as a linear function of the dose of X-ray and chemical carcinogen (4-HAQO). The rejoining of broken single-strand of DNA induced by these agents seems to consist of two processes: an initial rapid rejoining process and a late slow rejoining process. Single-strand breaks of cellular DNA induced by these two agents rejoin at nearly the same rate for each of the two processes during incubation.     

DNA strand break and rejoining in cultured human fibroblasts exposed to fast neutrons or gamma rays

The production and rejoining of DNA single-strand and double-strand breaks have been monitored in monolayer cultures of proliferating human skin fibroblasts by means of sensitive techniques. Cells were irradiated with low doses of either 60Co gamma-rays or 14.6 MeV neutrons at 0 degrees C (0-5 Gy for measurement of single-strand breaks by alkaline elution and 0-50 Gy for double-strand breaks measured by neutral elution). The yield of single-strand breaks induced by neutrons was 30 per cent of that produced by the same dose of gamma-rays; whilst in the induction of double-strand breaks neutrons were 1.6 times as effective as gamma-rays. Upon post-irradiation incubation of cells at 37 degrees C, neutron-induced single-strand and double-strand breaks were rejoined with a similar time-course to gamma-induced breaks. Rejoining followed biphasic kinetics; of the single-strand breaks, 50 per cent disappeared within 2 min after gamma-rays and 6-10 min after neutrons. Fifty per cent of the double-strand breaks disappeared within 10 min, after gamma-rays and neutrons. Cells derived from patients suffering from ataxia-telangiectasia showed the same capacity for repair of single- and double-strand breaks induced by 14.6 MeV neutrons, as cells established from normal donors. The comparison of neutrons and gamma-rays in the induction of DNA breaks did not explain the elevated r.b.e. on high LET radiation. However, a study of the variation in the spectrum of lesions induced by different radiation sources will probably contribute to the clarification of the relative importance of other radio products.     

Repair of MMS-induced DNA double-strand breaks in haploid cells of Saccharomyces cerevisiae, which requires the presence of a duplicate genome.

Summary The formation and repair of double-strand breaks induced in DNA by MMS was studied in haploid wild type and MMS-sensitive rad6 mutant strains of Saccharomyces cerevisiae with the use of the neutral and alkaline sucrose sedimentation technique. A similar decrease in average molecular weight of double-stranded DNA from 5–6x10⁸ to 1–0.7x10⁸ daltons was observed following treatment with 0.5% MMS in wild type and mutant strains. Incubation of cells after MMS treatment in a fresh drug-free growing medium resulted in repair of double-strand breaks in the wild type strain, but only in the exponential phase of growth. No repair of double-strand breaks was found when cells of the wild type strain were synchronized in G-1 phase by treatment with factor, although DNA single-strand breaks were still efficiently repaired. Mutant rad6 which has a very low ability to repair MMS-induced single-strand breaks, did not repair double-strand breaks regardless of the phase of growth.These results suggest that (1) repair of double-strand breaks requires the ability for single-strand breaks repair, (2) rejoining of double-strand breaks requires the availability of two homologous DNA molecules, this strongly supports the recombinational model of DNA repair.     

Vector-mediated DNA double-strand break repair analysis in normal, and radiation-sensitive, Chinese hamster V79 cells

DNA double-strand break repair was assessed in 2 new radiation-sensitive V79 hamster cell lines (irs1 and irs2) by their ability to rejoin restriction endonuclease cuts in a transferred selectable SV40--E. coli gpt recombinant gene. The studied gene was carried in the vector pPMH16 which also contained a second selectable HSVtk-neo recombinant gene which acted as a control for DNA transformation. The parental V79 cells showed correct rejoining of KpnI and EcoRV double-strand breaks in approximately 18% and 36% of transformants respectively (correcting for the expression of undamaged gpt in neo+ transformants). irs1 shows a significantly reduced (approximately 3-fold) ability to rejoin correctly such double-strand scissions. However, irs2 rejoined such lesions as correctly as the V79 cells. The data are discussed in the context of the assay and the possible repair deficiencies of these radiosensitive mutant cells.     

Inhibition and recovery of DNA synthesis in human tumor cell lines following radiation exposure

Eight human tumor cell lines with radiosensitivities (D0) ranging from 1 to 3 Gy were analyzed for their response to radiation-induced inhibition of DNA synthesis. These cell lines differ in their sensitivity to induction of DNA double-strand breaks and in the rate at which they rejoin DNA double-strand breaks. Fifty-gray doses of gamma rays induced between 35 and 75% inhibition in rates of DNA synthesis. The magnitude of the inhibition was not related to cellular radiosensitivity, frequency of initial DNA double-strand breaks, or the rate of rejoining of DNA double-strand breaks. All the cell lines studied had similar kinetics of recovery from inhibition of DNA synthesis following radiation exposure. These results suggest that factors other than or in addition to frequency of DNA double-strand breaks are important in the control of DNA synthesis following exposure to ionizing radiation in human tumor cell lines.     

Escherichia coli radC is deficient in the recA-dependent repair of X-ray-induced DNA strand breaks

Escherichia coli K-12 cells incubated in buffer can repair most of their X-ray-induced DNA single-strand breaks, but additional single-strand breaks are repaired when the cells are incubated in growth medium. While the radC102 mutant was proficient at repairing DNA single-strand breaks in buffer (polA-dependent repair), it was partially deficient in repairing the additional single-strand breaks (or alkali-labile lesions) that the wild-type strain can repair in growth medium (recA-dependent repair), and this repair deficiency correlated with the X-ray survival deficiency of the radC strain. In studies using neutral sucrose gradients, the radC strain consistently showed a small deficiency in rejoining X-ray-induced DNA double-strand breaks, and it was deficient in restoring the normal sedimentation characteristics of the repaired DNA.     

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.     

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.     

An examination of the repair saturation hypothesis for describing shouldered survival curves

The hypothesis that after irradiation a competition exists between fixation of radiation damage and its repair and that this competition determines cell survival was to be tested. Postirradiation temperature of holding was employed as a means of modulating rate of damage repair, and the postirradiation rates of repair of DNA strand breaks (both single and double) were monitored using elution assays. At temperatures below 37 degrees C following irradiation the rates of rejoining were decreased markedly, although rejoining of single-strand breaks was seen even at 10 degrees C and rejoining of double-strand breaks still occurred at 16 degrees C. However, 3 h incubation of cells at these lowered temperatures had no observable effect on cell survival parameters. It is concluded that either damage fixation and damage repair have the same dependence on temperature, or simple measurements of rejoining of breaks are insufficient to detect the details of the competition between repair and fixation (some measure of fidelity of repair is needed).     

Occurrence and elimination of single- and double-stranded DNA breaks in the fibroblasts of xeroderma pigmentosum patients exposed to gamma radiation

A defect in ability to rejoin gamma-induced single-strand DNA breaks, earlier found in the lymphocytes of a patient with form II of xeroderma pigmentosum, has been also shown for cultured skin fibroblasts. In successive subcultivation the ability to rejoin DNA breaks gradually increases. Elimination of double-strand DNA breaks occurs with the same fullness and rate as in the cells of patients with classic form of XP and healthy donors. The subcultivation does not influence this process. Possible causes of the phenomena discovered are discussed.