Kinetics of excision repair of UV-induced DNA damage, measured using the comet assay

The kinetics of UV- (254 nm) irradiation-induced DNA single-strand breaks (SSBs), generated during the excision repair of UV-induced DNA damage, in leukemic lymphocytes and in normal blood mononuclear cells (MNCs) were studied using the alkaline comet assay. The cells were isolated by density gradient centrifugation from peripheral blood of patients with chronic lymphocytic leukemia (CLL) and from healthy study subjects. The cytotoxicity of UV irradiation was determined in vitro in peripheral blood mononuclear lymphocytes from 36 CLL patients and from eight healthy donors using the incorporation of radioactive leucine in 4-day cultures. A remarkable difference in excision repair capability was observed between normal and leukemic lymphocytes. In contrast to normal lymphocytes, there was always a subpopulation of CLL cells that did not complete the repair of UV-induced DNA damage during the 24-h repair period. Furthermore, differences were also recorded between UV-sensitive and UV-resistant CLL cases. The differences in DNA migration between the maximum increase (59-77 microm) and that at 24 h after irradiation (21-66 microm) was statistically significant in two of three patients exhibiting UV-resistance. Correspondingly, only in one of three patients exhibiting UV-sensitivity was the difference in DNA migration statistically significant (maximum increase: 44-107 microm, vs. 24 h after: 42-100 microm). Our results confirm an abnormal pattern of the CLL cell response to UV irradiation. Furthermore, we identified defective processing of UV-induced DNA damage in CLL versus normal lymphocytes, particularly in UV-sensitive cases.     

Inhibition of DNA repair by deoxyadenosine in resting human lymphocytes

Profound lymphopenia is characteristic of immunodeficient children who lack adenosine deaminase (ADA). When ADA is inactive, deoxyadenosine (dAdo) is phosphorylated by immature T lymphoblasts and inhibits cell division. However, dAdo also causes the slow accumulation of DNA strand breaks in nondividing, mature human peripheral blood lymphocytes. To explore the basis for this phenomenon, we have assessed the effects of dAdo and other deoxynucleosides on the repair of gamma-radiation induced DNA strand breaks in resting normal lymphocyte cultures. As measured by a sensitive DNA unwinding assay, most DNA strand breaks were rejoined within 2 hr after exposure of lymphocytes to 500 rad. In medium supplemented with deoxycoformycin, a tight binding ADA inhibitor, dAdo retarded DNA rejoining in a dose and time dependent manner. The inhibition required dAdo phosphorylation. Over an 8-hr period, 10 microM dAdo gradually rendered peripheral blood lymphocytes incompetent for DNA repair. Among several other compounds tested, 2-chlorodeoxyadenosine, an ADA resistant dAdo congener with anti-leukemic and immunosuppressive activity, was the most powerful inhibitor of DNA repair, exerting significant activity at concentrations as low as 100 nM. Both dAdo and 2-chlorodeoxyadenosine blocked unscheduled DNA synthesis in irradiated resting lymphocytes, as measured by [3H]thymidine uptake. On the basis of this and other data, we suggest that quiescent peripheral blood lymphocytes break and rejoin DNA at a slow and balanced rate. The accumulation of dATP progressively retards the DNA repair process and thereby fosters the time-dependent accretion of DNA strand breaks. By inhibiting DNA repair, dAdo, 2-chlorodeoxyadenosine and related compounds may substantially potentiate the toxicity of DNA damaging agents to normal and malignant lymphocytes.     

5-氮胞苷对贵州小型猪淋巴细胞DNA损伤及修复的影响

目的　研究贵州小型猪淋巴细胞对化学物或药物引起的DNA损伤及修复影响的反应。方法　用单细胞凝胶电泳技术检测比较 5 氮胞苷对PHA刺激和未刺激淋巴细胞的DNA损伤及其修复过程。结果　 5 氮胞苷引起未刺激淋巴细胞明显的DNA泳动 (彗星尾 ) ,经修复孵育 2h后 ,DNA泳动与孵育前比较无显著差异 ,而 5 氮胞苷引起的刺激细胞DNA泳动经 2h修复孵育后与孵育前比较显著减少。结论　 5 氮胞苷引起贵州小型猪未刺激淋巴细胞DNA损伤经 2h孵育未能修复 ,而刺激细胞的DNA损伤明显修复。     

A 1,4-dihydropyridine derivative reduces DNA damage and stimulates DNA repair in human cells in vitro

Compounds of the 1,4-dihydropyridine (1,4-DHP) series have been shown to reduce spontaneous, alkylation- and radiation-induced mutation rates in animal test systems. Here we report studies using AV-153, the 1,4-DHP derivative that showed the highest antimutagenic activity in those tests, to examine if it modulates DNA repair in human peripheral blood lymphocytes and in two human lymphoblastoid cell lines, Raji and HL-60. AV-153 caused a 50% inhibition of growth (IC50) of Raji and HL-60 cells at 14.9+/-1.2 and 10.3+/-0.8mM, respectively, but did not show a cytotoxic effect at concentrations <100 microM. Alkaline single-cell gel electrophoresis (comet) assays showed that AV-153 reduced the number of DNA strand breaks in untreated cells and also in cells exposed to 2 Gy of gamma-radiation, 100 microM ethylmethane sulfonate (EMS), or 100 microM H2O2. DNA damage was reduced by up to 87% at AV-153 concentrations between 1 and 10nM, and a positive dose-effect relationship was seen between 0.01 and 1 nM. Comparison of the kinetics of DNA strand-break rejoining in the presence and absence of AV-153 revealed a considerable influence on the rate of repair. In view of the resemblance of this compound's structure to that of dihydronicotinamide, a substrate for poly(ADP-rybose)polymerase, the modulation of DNA repair by AV-153 could involve an influence on poly(ADP)ribosylation.     

Quercetin ameliorates gamma radiation-induced DNA damage and biochemical changes in human peripheral blood lymphocytes

We investigated the radioprotective efficacy of quercetin (QN), a naturally occurring flavonoid against gamma radiation-induced damage in human peripheral blood lymphocytes and plasmid DNA. In plasmid study, QN at different concentrations (3, 6, 12, 24 and 48 microM) were pre-incubated with plasmid DNA for 1h followed by exposure of 6 Gy radiation. Among all concentrations of QN used, 24 microM showed optimum radioprotective potential. To establish the most effective protective concentration of QN in lymphocytes, the cells were pre-incubated with 3, 6, 12, 24 and 48 microM of QN for 30 min and then exposed to 4 Gy gamma-radiation. The concentration-dependent effects of QN were evaluated by scoring micronuclei (MN) frequencies. The results showed that QN decreased the MN frequencies dose dependently, but the effect was more pronounced at 24 microM. Thus, 24 microM of QN was selected as the optimum concentration and was further used to evaluate its radioprotective effect in lymphocytes. For that a separate experiment was carried out, in which lymphocytes were incubated with QN (24 microM) for 30 min and exposed to different doses of radiation (1, 2, 3 and 4 Gy). Genetic damage (MN, dicentric aberration and comet attributes) and biochemical changes were measured to evaluate the effect of QN on gamma-radiations (1-4 Gy). Radiation exposed showed significant increases in the genetic damage and thiobarbituric acid reactive substances (TBARS) accompanied by a significant decrease in the antioxidant status. QN pretreatment significantly decreased the genetic damage and TBARS and improved antioxidant status through its antioxidant potential. Altogether, our findings encourage further mechanistic and in vivo studies to investigate radioprotective efficacy of QN.     

Delayed repair of DNA single-strand breaks does not increase cytogenetic damage

DNA damage and cytogenetic effects of ionizing radiation were investigated in Chinese hamster ovary (CHO) cells and unstimulated human peripheral blood lymphocytes. DNA damage and repair were analysed by alkaline elution under conditions that predominantly measured DNA single-strand breaks (ssb). X-radiation (2.5 Gy) induced ssb in both CHO cells and unstimulated lymphocytes, and the breaks were repaired within 30 and 90 min, respectively. This rapid repair was delayed by the poly(ADP-ribose) polymerase inhibitor, 3-aminobenzamide (3AB). The cytogenetic effects of the 3AB-induced delay in DNA repair were examined by analysing sister chromatid exchange (SCE) frequency in CHO cells and fragmentation of prematurely condensed chromosomes (PCC) in unstimulated human lymphocytes after 2.5 Gy of X-rays. Although 3AB delayed the rejoining of DNA ssb, this delay did not result in increased cytogenetic damage manifested as either SCE or fragmentation of PCC. These results indicate that the rapidly rejoining DNA ssb are not important in the production of chromosome damage.     

Sister-chromatid exchanges in human lymphocytes after a non-S-phase incubation period to allow excision DNA repair-in vitro exposure to N-acetoxy-2-acetylaminofluorene and ethylene oxide

Sister-chromatid exchanges (SCE) were analyzed in human peripheral blood lymphocytes at the baseline level, after induction of DNA damage by N-acetoxy-2-acetylaminofluorene (NA-AAF) and ethylene oxide (EO), and after a subsequent 18-h DNA-repair incubation period. There was a significant difference between the baseline SCE frequencies as compared to those after 1 h of NA-AAF or EO treatment. There was no significant difference between the SCE frequencies after 1 h of NA-AAF treatment and those after 18 h of DNA-repair incubation, suggesting that only a low level of NA-AAF damage to DNA had been removed. However, there was a significant difference between the SCE frequencies after 1 h of EO treatment and those after 18 h of DNA-repair incubation, indicating that a significant level of EO induced DNA lesions had been repaired. Thus, it seems likely that the EO induced DNA damage is more easily recognized, and hence more rapidly repaired than the NA-AAF induced damage. The reason for this may be the different chemical nature of the DNA lesions induced, which, in turn, leads to different kinetics of DNA repair.     

Repair of DNA damage induced by oxygen radicals in human non-proliferating and proliferating lymphocytes.

Repair of DNA lesions induced by oxygen radicals, generated by xanthine/xanthine oxidase (X/XO), was studied in human peripheral blood lymphocytes and in PHA-stimulated proliferating lymphocytes from 4 healthy subjects. The lesions included DNA-strand breaks (SSB) and other lesions that are converted to SSB under alkaline conditions. The frequencies of SSB were estimated by fluorometric analysis of DNA unwinding. Maximum production of SSB occurred within 10 min of incubation with X/XO at 22 degrees C; with 0.5 mM or higher concentrations of xanthine; and with 0.1-0.5 units/ml of xanthine oxidase. Proliferating lymphocytes repaired X/XO-induced SSB about 4 times more rapidly than lymphocytes. Lymphocytes repaired X/XO-induced SSB more slowly than SSB caused by gamma-radiation. These findings are consistent with the evidence that a number of DNA-repair enzymes have greater activity in proliferating cells than in resting cells. These findings also support the view that there are differences between the DNA damage due to oxygen radicals and that due to ionizing radiation.     

X射线对人外周血淋巴细胞DNA损伤修复和凋亡的影响

目的 研究不同时间诱导X射线照射的淋巴细胞进入细胞周期DNA损伤修复与凋亡的影响.方法 X射线（0.5 Gy）作用于正常人外周血淋巴细胞,以照射后不同时间点（0、4 h）分别加入PHA并分成两组,即照射后0 h加PHA组（A组）和照射后4 h加PHA组（B组）,再分别培养0、0.5、2 h,用流式细胞术和免疫印迹法检测A组和B组γ-H2AX蛋白的表达,Annexin-V/PI法分析A、B两组的细胞凋亡率.结果 流式细胞术及免疫印迹结果均显示A组的γ-H2AX蛋白表达高于B组（P＜0.05）,且均先升高后降低.A组细胞凋亡率亦大于B组.结论 不同时间诱导被打击的淋巴细胞进入周期其可能发生DNA修复并同时伴随细胞凋亡的发生.     

In vivo repair of rat liver DNA damaged by dimethylnitrosamine or diethylnitrosamine.

Effects of hepatocarcinogens dimethylnitrosamine (DMN) and diethylnitrosamine (DEN) on the sedimentation pattern of rat liver DNA in alkaline sucrose gradients were studied with regard to time and dose dependency. Both DMN (10 mg/kg body weight) and den (13.4 or 134 mg/kg) induced appreciably decreased DNA sedimentation rates at 24 h after injection. DMN at 10 mg/kg was as effective in decreasing the DNA sedimentation rate at 24 h after injection as was the higher dose of DEN (134 mg/kg). Sedimentation patterns at 1, 6 and 14 days after injection indicated that damage induced by DEN (134 mg/kg) was repaired at a substantially lower rate than DMN (10 mg/kg) induced damage. When effects of equimolar doses of DMN (10 mg/kg) and DEN (13.4 mg/kg) were compared at 1, 6 and 14 days after injection, it was observed that the more pronounced damage of rat liver DNA induced by DMN was repaired at a faster rate than was the DEN-induced damage. At the molecular level this difference in repair between damage induced by the two nitrosamines is probably related to different DNA alkylation patterns. The relatively persistent nitrosamine-induced DNA lesions (observed especially after DEN administration) are thought to represent phosphotriesters which give rise to single strand DNA breaks at strongly alkaline conditions of lysis on top of the gradient. The results are discussed in relation to the possible significance of alkylation and repair of DNA in the formation of (pre)cancerous lesions in rat liver.     

DNA repair after gamma irradiation in lymphocytes exposed to low-frequency pulsed electromagnetic fields

The effect of exposure to extremely low-frequency pulsed electromagnetic fields (EMFs) on DNA repair capability and on cell survival in human lymphocytes damaged in vitro with gamma rays was studied by two different micromethods. In the first assay, which measures DNA repair synthesis (unscheduled DNA synthesis, UDS), lymphocyte cultures were stimulated with phytohemagglutinin (PHA) for 66 h and then treated with hydroxyurea (which blocks DNA replication), irradiated with 100 Gy of 60Co, pulsed with [3H]thymidine ([3H]TdR), and then exposed to pulsed EMFs for 6 h (the period in which cells repaired DNA damage). In the second assay, which measures cell survival after radiation or chemical damage, lymphocytes were first irradiated with graded doses of gamma rays or treated with diverse antiproliferative agents, and then stimulated with PHA, cultured for 72 h, and pulsed with [3H]TdR for the last 6 h of culture. In this case, immediately after the damage induced by either the radiation or chemicals, cultures were exposed to pulsed EMFs for 72 h, during which cell proliferation took place. Exposure to pulsed EMFs did not affect either UDS or cell survival, suggesting that this type of nonionizing radiation--to which humans may be exposed in the environment, and which is used for both diagnostic and therapeutic purposes--does not affect DNA repair mechanisms.     

Influence of the culture time on DNA damage and repair in isolated rat hepatocytes exposed to nitrochlorobenzene derivatives

The induction of DNA damage on 1.5- and 24-h cultured hepatocytes was tested after a 3-h exposure to 5 and 50 microM mono-, di-, and trinitrochlorobenzene (100-00-5; 97-00-7; 88-88-0). DNA-repair synthesis, elicited by nitrochlorobenzene treatment, was also estimated 24 and 48 h after the withdrawal of the nitro-aryl halides. DNA damage and repair were evaluated by determining the DNA elution rate in alkali. A dose-related rate of DNA damage was obtained by exposure of 1.5-h-cultured hepatocytes to 5 and 50 microM nitrochlorobenzenes . DNA of 24-h-cultured cells was not affected by nitrochlorobenzene treatment. The data obtained by exposure to 5 microM methyl methanesulfonate (66-27-3) and nitrosodimethylamine (62-75-9), direct and indirect methylating agents, suggest that 24-h-cultured liver cells are still able to transform nitrosodimethylamine but not nitrochlorobenzenes . Isolated hepatocytes maintain their capability of repairing the induced DNA damage when cultured for 24 and 48 h in fresh medium. The system offers an interesting model to investigate the perturbations related to the metabolism of xenobiotics.     

Hyperthermia can differentially modulate the repair of doxorubicin-damaged DNA in normal and cancer cells

Hyperthermia can modulate the action of many anticancer drugs, and DNA repair processes are temperature-dependent, but the character of this dependence in cancer and normal cells is largely unknown. This subject seems to be worth studying, because hyperthermia can assist cancer therapy. A 1-h incubation at 37 degrees C of normal human peripheral blood lymphocytes and human myelogenous leukemia cell line K562 with 0.5 microM doxorubicin gave significant level of DNA damage as assessed by the alkaline comet assay. The cells were then incubated in doxorubicin-free repair medium at 37 degrees C or 41 degrees C. The lymphocytes incubated at 37 degrees C needed about 60 min to remove completely the damage to their DNA, whereas at 41 degrees C the time required for complete repair was shortened to 30 min. There was also a difference between the repair kinetics at 37 degrees C and 41 degrees C in cancer cells. Moreover, the kinetics were different in doxorubicin-sensitive and resistant cells. Therefore, hyperthermia may significantly affect the kinetics of DNA repair in drug-treated cells, but the magnitude of the effect may be different in normal and cancer cells. These features may be exploited in cancer chemotherapy to increase the effectiveness of the treatment and reduce unwanted effects of anticancer drugs in normal cells and fight DNA repair-based drug resistance of cancer cells.     

A technique for the measurement of breakage and repair of DNA alkylated in vivo.

The alkaline elution technique has been adapted for use in the assessment of DNA damage induced in the livers and lungs of mice after administration of an alkylating agent, methylemthanesulfonat (MMS). At 4 h after administration of MMS, damage ot DNA was readily demonstrable; the damage was repaired in liver by 24 h. The lung, particularly of the A/J mouse, exhibited an increased alkaline elution rate when compared to C57BL/6J, and repair was not entirely complete (as judged from the rate of alkaline elution of DNA) by 24 h. The rate of elution was dependent upon temperature. It is believed that this adaptation should have great utility in examining DNA repair in vivo.     

Basal, oxidative and alkylative DNA damage, DNA repair efficacy and mutagen sensitivity in breast cancer

Impaired DNA repair may fuel up malignant transformation of breast cells due to the accumulation of spontaneous mutations in target genes and increasing susceptibility to exogenous carcinogens. Moreover, the effectiveness of DNA repair may contribute to failure of chemotherapy and resistance of breast cancer cells to drugs and radiation. The breast cancer susceptibility genes BRCA1 and BRCA2 are involved in DNA repair. To evaluate further the role of DNA repair in breast cancer we determined: (1) the kinetics of removal of DNA damage induced by hydrogen peroxide and the anticancer drug doxorubicin, and (2) the level of basal, oxidative and alkylative DNA damage before and during/after chemotherapy in the peripheral blood lymphocytes of breast cancer patients and healthy individuals. The level of DNA damage and the kinetics of DNA repair were evaluated by alkaline single cell gel electrophoresis (comet assay). Oxidative and alkylative DNA damage were assayed with the use of DNA repair enzymes endonuclease III (Endo III) and formamidopyrimidine-DNA glycosylase (Fpg), recognizing oxidized DNA bases and 3-methyladenine-DNA glycosylase II (AlkA) recognizing alkylated bases. We observed slower kinetics of DNA repair after treatment with hydrogen peroxide and doxorubicin in lymphocytes of breast cancer patients compared to control individuals. The level of basal, oxidative and alkylative DNA damage was higher in breast cancer patients than in the control and the difference was more pronounced when patients after chemotherapy were engaged, but usually the level of DNA damage in these patients was too high to be measured with our system. Our results indicate that peripheral blood lymphocytes of breast cancer patients have more damaged DNA and display decreased DNA repair efficacy. Therefore, these features can be considered as risk markers for breast cancer, but the question whether they are the cause or a consequence of the illness remains open. Nevertheless, our results suggest that research on the mutagen sensitivity and efficacy of DNA repair could impact the development of new diagnostic and screening strategies as well as indicate new targets to prevent and cure cancer. Moreover, the comet assay may be applied to evaluate the suitability of a particular mode of chemotherapy to a particular cancer patient.     

DNA damage and repair with age in individual human lymphocytes

Previous biochemical studies on DNA repair competence and aging have been limited to techniques, such as alkaline elution or nucleoid sedimentation, involving mass cell populations. These techniques provide no information about the distribution of DNA damage and repair among individual cells and are unlikely to detect age-dependent changes affecting a minor fraction of the cell population. We have recently described a microgel electrophoretic assay (Singh et al., 1988) that measures, at the level of the individual cell, single-strand DNA breaks and alkali-sensitive sites. Here, we employ this method to analyze DNA damage and repair in lymphocytes isolated from the peripheral blood of 31 subjects (23 males and 8 females aged 25-91 years) and exposed in vitro to 200 rads of X-irradiation. While basal (pre-irradiation) levels of damage were independent of the age of the donor, an age-dependent increase in DNA damage was observed immediately following irradiation. For all subjects, the mean level of DNA damage was restored to pre-irradiation control levels within 2 h of incubation at 37 degrees C. However, a distribution analysis of DNA damage among cells within each sample indicated the presence of a few highly damaged cells (4-16%) in the 2-h sample, the occurrence of which was significantly more common among aged individuals. These data indicate an age-related decline in DNA repair competence among a small subpopulation of lymphocytes.     

Oxidative Stress-Induced DNA Damage and Repair in Human Peripheral Blood Mononuclear Cells: Protective Role of Hemoglobin

Background

DNA repair is a cellular defence mechanism responding to DNA damage caused in large part by oxidative stress. There is a controversy with regard to the effect of red blood cells on DNA damage and cellular response.

Aim

To investigate the effect of red blood cells on H₂O₂-induced DNA damage and repair in human peripheral blood mononuclear cells.

Methods

DNA breaks were induced in peripheral blood mononuclear cells by H₂O₂ in the absence or presence of red blood cells, red blood cells hemolysate or hemoglobin. DNA repair was measured by ³H-thymidine uptake, % double-stranded DNA was measured by fluorometric assay of DNA unwinding. DNA damage was measured by the comet assay and by the detection of histone H2AX phosphorylation.

Results

Red blood cells and red blood cells hemolysate reduced DNA repair in a dose-dependent manner. Red blood cells hemolysate reduced % double-stranded DNA, DNA damage and phosphorylation of histone H2AX. Hemoglobin had the same effect as red blood cells hemolysate on % double-stranded DNA.

Conclusion

Red blood cells, via red blood cells hemolysate and hemoglobin, reduced the effect of oxidative stress on peripheral blood mononuclear cell DNA damage and phosphorylation of histone H2AX. Consequently, recruitment of DNA repair proteins diminished with reduction of DNA repair. This suggests that anemia predisposes to increased oxidative stress induced DNA damage, while a higher hemoglobin level provides protection against oxidative-stress-induced DNA damage.     

Exposure of mammalian cells to 60-Hz magnetic or electric fields: analysis of DNA repair of induced, single-strand breaks

DNA damage was induced in isolated human peripheral lymphocytes by exposure at 5 Gy to 60Co radiation. Cells were permitted to repair the DNA damage while exposed to 60-Hz fields or while sham-exposed. Exposed cells were subjected to magnetic (B) or electric (E) fields, alone or in combination, throughout their allotted repair time. Repair was stopped at specific times, and the cells were immediately lysed and then analyzed for the presence of DNA single-strand breaks (SSB) by the alkaline-elution technique. Fifty to 75 percent of the induced SSB were repaired 20 min after exposure, and most of the remaining damage was repaired after 180 min. Cells were exposed to a 60-Hz ac B field of 1 mT; an E field of 1 or 20 V/m; or combined E and B fields of 0.2 V/m and 0.05 mT, 6 V/m and 0.6 mT, or 20 V/m and 1 mT. None of the exposures was observed to affect significantly the repair of DNA SSB.     

Recovery of tobacco cells from cadmium stress is accompanied by DNA repair and increased telomerase activity

It has been shown previously that apoptosis of tobacco cells induced by cadmium ions shows a relatively long lag period between exposure and cell death. This lag phase lasts for 3 d in TBY-2 cell cultures and is characterized by the maintenance of full cell viability despite extensive fragmentation of DNA into pieces of chromatin loop size. Experiments reported here demonstrate that cell death can be prevented if 50 micro M CdSO(4) is removed from the growth medium during the lag phase, suggesting that an irreversible apoptotic trigger is delivered within 24 h, between the third and fourth days of cadmium treatment. The post-cadmium recovery phase was characterized by DNA repair at the level of 50-200 kb and increased telomerase activity. Analysis of high-molecular-weight DNA by pulsed-field-gel electrophoresis revealed that the majority of DNA strand breaks was repaired within 48 h after cadmium withdrawal. Telomerase activity increased 2.5-fold in the recovery phase, but elevated levels were also found in cell extracts from apoptotic cells suggesting that telomerase might be associated with DNA repair, but it is not capable of inhibiting ongoing apoptosis. Limited exposure of TBY-2 cells to cadmium elicits non-random DNA damage of relatively high magnitude that can be repaired. It is proposed that plants might have developed a highly efficient DNA repair system to cope with transient genotoxic stress.