Reply to Letter by C. B. Seymour and C. Mothersill

Summary

V79 379A cells were irradiated and then exposed to anisotonic PBS for 20 min. This enhanced the radiation effect resulting from the fixation of potentially lethal damage. The induction of DNA single- and double-strand breaks is not increased by this treatment. Anisotonic treatment delayed the onset of repair of DNA damage. However when cells were returned to normal medium, they repaired the damage to a similar extent as cells not exposed to the anisotonic treatment. We suggest that the fixation of damage by post-irradiation anisotonic treatment is mediated through an increased probability of misrepair of DNA damage due to the delay in the onset of repair. This is supported by the observation that there is a reduced effect of post-irradiation anisotonic treatment on cells that have a markedly reduced ability to repair double-strand breaks.     

Differential DNA double strand break fixation dependence on poly(ADP-ribosylation) in L5178Y and CHO cells

PURPOSE: To investigate the role of poly(ADP-ribosylation) in DNA double-strand break repair and fixation in murine lymphoma L5178Y (LY) sublines, LY-R and LY-S, and a pair of Chinese hamster ovary lines: wild-type and mutant xrs6 cells, that have differences in repair competence and degree of radiosensitization with poly(ADP-ribosylation) inhibitors. MATERIALS AND METHODS: Cells (asynchronous, logarithmic phase) were pre-incubated with 2 mM aminobenzamide at 37 or 25 degrees C, X-irradiated with 10 Gy and allowed to repair DNA breaks for 15, 60 and 120 min at 37 or 25 degrees C. The remaining double-strand break were estimated by the neutral comet assay. RESULTS: At 37 degrees C, no effect of AB treatment on the repair kinetics was observed either in xrs6 or Chinese hamster ovary (wild-type) cells. In contrast, aminobenzamide decreased the repair of double-strand break in the LY-S line but not the LY-R line, in agreement with the previously observed radiosensitization of LY cells by poly(ADP-ribosylation) inhibition. However, double-strand break rejoining in the repair competent cell lines, Chinese hamster ovary and LY-R, also was affected by aminobenzamide when the post-irradiation incubation was carried out at 25 degrees C. Analysis of these results together with earlier data on LY-S cells have been interpreted in terms of Radford's model of radiation damage fixation. CONCLUSION: The reported results indicate that poly(ADP-ribosylation) can be an important modulator of the conversion of DNA damage to lethal events.     

Inhibition of repair of X-ray-induced DNA double-strand breaks in human lymphocytes exposed to sodium butyrate

Purpose : Sodium butyrate is known to inhibit histone deacetylase enzymes and to enhance the frequencies of X-ray-induced dicentrics and rings in human lymphocytes. In this study an investigation was made of the mechanisms underlying this enhancement by assessing the effect of sodium butyrate on the extent of X-ray-induced DNA damage and its repair in human peripheral blood lymphocytes. Methods and materials : Unstimulated G 0 lymphocytes were pre-treated for 24h with sodium butyrate at a final concentration of 5 mM, irradiated with different doses of X-rays and then analysed for different endpoints either immediately or after different repair periods. The frequencies of DNA strand breaks were determined biochemically using nucleoid sedimentation, alkaline elution and immunochemical analysis as well as cytogenetically using the premature chromosome condensation (PCC) technique. Results : The results show that sodium butyrate pre-treatment does not lead to a significant increase of DNA double- or single-strand breaks nor to an increase of alkali labile base damage in G 0 lymphocytes. Moreover, sodium butyrate treatment had no effect on the initial frequency of chromosome breaks. However, PCC analysis clearly showed that the presence of sodium butyrate post-irradiation severely inhibited DNA double-strand break (DSB) repair, which most likely accounts for the increase in X-ray-induced chromosome aberrations. Conclusions : Sodium butyrate treatment leading to changes in histone acetylation and increased accessibility of chromatin had no effect on the initial levels of X-ray-induced DNA damage. However, sodium butyrate may affect either the chromatin configuration or the enzymatic activities that play a key role in the repair of DSB.     

Correlation between non-repairable DNA lesions and fixation of cell damage by hypertonic solutions in Chinese hamster cells

In Chinese hamster HA-1 cells, killing induced by gamma-rays was enhanced by post-irradiation treatment with hypertonic solution (0.5 mol/l NaCl in phosphate buffered saline, pH 7.2) for 20 min. The initial DNA double-strand breaks (dsb) induced by gamma-rays were repaired during post-irradiation treatment with hypertonic solution. However, hypertonic treatment following gamma-irradiation enhanced the frequency of non-repairable dsb, as compared with the frequency after incubation at 37 degrees C following gamma-irradiation. Hypertonic treatment did not affect the initial half-time for rejoining of dsb. Hypertonic treatment did not enhance cell killing, nor did it enhance the non-repairable dsb when the irradiated cells were incubated at 37 degrees C for 2 h. These results suggest that fixation of gamma-ray-induced potentially lethal damage by hypertonic treatment results from inhibition of the rejoining of dsb.     

Reduction of Intracellular Glutathione Content and Radiosensitivity

Summary

The intracellular glutathione (GSH) content of HeLa, CHO and V79 cells was reduced by incubating the cells in growth medium containing buthionine sulphoximine or diethyl maleate (DEM). Clonogenicity, single-strand DNA breaks (ssb) and double-strand DNA breaks (dsb) were used as criteria for radiation-induced damage after X- or γ-irradiation. In survival experiments, DEM gave a slightly larger sensitization although it gave a smaller reduction of the intracellular GSH. In general, sensitization was larger for dsb than for ssb, also the reduction of the o.e.r. was generally larger for dsb than for ssb. This may be due to the higher dose rate in case of dsb experiments resulting in a higher rate of radiochemical oxygen consumption. In general, no effect was found on post-irradiation repair of ssb and dsb.     

Inhibition of repair of X-ray-induced DNA double-strand breaks in human lymphocytes exposed to sodium butyrate

PURPOSE: Sodium butyrate is known to inhibit histone deacetylase enzymes and to enhance the frequencies of X-ray-induced dicentrics and rings in human lymphocytes. In this study an investigation was made of the mechanisms underlying this enhancement by assessing the effect of sodium butyrate on the extent of X-ray-induced DNA damage and its repair in human peripheral blood lymphocytes. METHODS AND MATERIALS: Unstimulated G0 lymphocytes were pretreated for 24h with sodium butyrate at a final concentration of 5 mM, irradiated with different doses of X-rays and then analysed for different endpoints either immediately or after different repair periods. The frequencies of DNA strand breaks were determined biochemically using nucleoid sedimentation, alkaline elution and immunochemical analysis as well as cytogenetically using the premature chromosome condensation (PCC) technique. RESULTS: The results show that sodium butyrate pretreatment does not lead to a significant increase of DNA double- or single-strand breaks nor to an increase of alkali labile base damage in G0 lymphocytes. Moreover, sodium butyrate treatment had no effect on the initial frequency of chromosome breaks. However, PCC analysis clearly showed that the presence of sodium butyrate post-irradiation severely inhibited DNA double-strand break (DSB) repair, which most likely accounts for the increase in X-ray-induced chromosome aberrations. CONCLUSIONS: Sodium butyrate treatment leading to changes in histone acetylation and increased accessibility of chromatin had no effect on the initial levels of X-ray-induced DNA damage. However, sodium butyrate may affect either the chromatin configuration or the enzymatic activities that play a key role in the repair of DSB.     

Transient DNA Double-Strand Breakage in 4-Hydroperoxyifosfamide-Treated Mammalian Cells in Vitro Does Not Interact with the Rejoining of Radiation-Induced Double-Strand Breaks

BACKGROUND: 4-Hydroxyifosfamide is the primary metabolite in vivo of the bifunctional alkylating cytostatic ifosfamide. DNA interstrand cross-linking induced by bifunctional alkylators may be repaired through an intermediate with unligated repair patches on both strands which should uncover analytically as DNA double-strand breaks and allow to measure the rejoining kinetic of this repair intermediate. Additionally, the combined effects of drug and radiation treatment on rejoining of double-strand breaks was investigated with two different mammalian cell lines. MATERIAL AND METHODS: V79 (rodent fibroblasts) and Widr (human colon carcinoma) cells were treated for 2 hours with 4-hydroperoxyifosfamide which rapidly decays to 4-hydoxyifosfamide in aqueous solution or were exposed in combination with ionizing radiation followed by incubation for repair with or without the drug. DNA double-strand breakage was measured by pulsed-field electrophoresis. RESULTS: The 2 hours 4-hydroperoxyifosfamide treatment (30 micrograms/ml) resulted in a pronounced DNA fragmentation that, 2-4 hours after drug removal, declined with an estimated half-live of about 4 hours for both cell lines. When the cells were additionally irradiated with 10 Gy given in the middle of drug exposure, the residual fragmentation after 12 or 24 hours incubation for repair was only marginally increased, roughly corresponding to the respective value after radiation, alone. A continuous drug exposure of 6 hours (at 10 micrograms/ml) resulted in a fragmentation that was independent of a preirradiation with a high dose of 30 Gy, immediately before drug addition. CONCLUSIONS: The present data support the idea that unligated/unrejoined double-stranded DNA ends are generated during the repair of lesions from bifunctional alkylators. The rate of subsequent rejoining is in the order of magnitude of the slow rejoining of radiation-induced double-strand breaks. Processing of double-stranded DNA damage from either 4-hydroperoxyifosfamid or radiation exposure is apparently unaffected in combined treatments.     

Role for non-homologous end-joining in the repair of UVA-induced DNA damage

PURPOSE: The biological significance of long-wavelength ultraviolet (UV) light, UVA, is increasingly realized, but the precise nature of the cellular damage responsible for the effects of this radiation is still not clear. It has been reported that UVA can induce double-strand breaks in DNA, but the biological significance of these is not known. We have therefore examined the UVA sensitivity of a cell line deficient in non-homologous end-joining, the major pathway for the repair of DNA double-strand breaks in mammalian cells in order to determine the biological importance of UVA-induced DSB. MATERIALS AND METHODS: Xrs-6, a Chinese hamster ovary cell line mutant for XRCC5 (Ku80) was compared with its parental CHO-K1 cell line for its sensitivity to UVA radiation (365 nm) using both a clonogenic assay and the micronucleus assay. RESULTS: Xrs-6 cells were sensitive to the cytotoxic effects of UVA. This resulted in the formation of chromosome damage, as measured by the micronucleus assay, which this cell line was unable to repair. CONCLUSIONS: Owing to the nature of the repair defect in these cells, these results imply that DNA double-strand breaks are produced in cells following UVA irradiation, that the non-homologous end-joining repair pathway is involved in their repair and that they are produced with sufficient frequency to have biological significance.     

Role for non-homologous end-joining in the repair of UVA-induced DNA damage

Purpose : The biological significance of long-wavelength ultraviolet (UV) light, UVA, is increasingly realized, but the precise nature of the cellular damage responsible for the effects of this radiation is still not clear. It has been reported that UVA can induce double-strand breaks in DNA, but the biological significance of these is not known. We have therefore examined the UVA sensitivity of a cell line deficient in non-homologous end-joining, the major pathway for the repair of DNA double-strand breaks in mammalian cells in order to determine the biological importance of UVA-induced DSB. Materials and methods : Xrs-6, a Chinese hamster ovary cell line mutant for XRCC5 (Ku80) was compared with its parental CHO-K1 cell line for its sensitivity to UVA radiation (365 nm) using both a clonogenic assay and the micronucleus assay. Results : Xrs-6 cells were sensitive to the cytotoxic effects of UVA. This resulted in the formation of chromosome damage, as measured by the micronucleus assay, which this cell line was unable to repair. Conclusions : Owing to the nature of the repair defect in these cells, these results imply that DNA double-strand breaks are produced in cells following UVA irradiation, that the non-homologous end-joining repair pathway is involved in their repair and that they are produced with sufficient frequency to have biological significance.     

Repair of DNA strand breaks at hyperthermic temperatures in Chinese hamster ovary cells.

The repair of DNA double-strand breaks was measured by pH 7.2 filter elution in cells incubated at 25-45 degrees C either before or after X-irradiation. Exposure to 45 degrees C for 15 minutes immediately prior to X-irradiation significantly increased both the half-time for DNA double-strand break closure and the number of DNA double-strand breaks remaining in nuclear DNA 180 minutes after irradiation. Exposure to temperatures between 41 and 45 degrees C immediately after X-irradiation accelerated DNA double-strand break closure and resulted in no increase in the number of DNA double-strand breaks remaining in the cell's genome 180 minutes after irradiation. The results indicate either that the radiosensitization produced by the administration of hyperthermic temperatures before and after irradiation result from two characteristically different molecular mechanisms, or that neither the rate of DNA strand break closure nor the number of DNA strand breaks remaining in nuclear DNA after irradiation accurately predict hyperthermic radiosensitization. These conclusions assume that no DNA strand breaks are below the resolution of this DNA damage assay and that a comparison between cytotoxicity and DNA repair after exposure to high radiation doses is valid.     

Increased sensitivity to sparsely ionizing radiation due to excessive base excision in clustered DNA damage sites in Escherichia coli

PURPOSE: In order to clarify the cellular processing and repair mechanisms for radiation-induced clustered DNA damage, we examined the correlation between the levels of DNA glycosylases and the sensitivity to ionizing radiation in Escherichia coli. MATERIALS AND METHODS: The lethal effects of gamma-rays, X-rays, alpha-particles and H2O2 were determined in E. coli with different levels of DNA glycosylases. The formation of double-strand breaks by post-irradiation treatment with DNA glycosylase was assayed with gamma-irradiated plasmid DNA in vitro. RESULTS: An E. coli mutM nth nei triple mutant was less sensitive to the lethal effect of sparsely ionizing radiation (gamma-rays and X-rays) than the wild-type strain. Overproduction of MutM (8-oxoguanine-DNA glycosylase), Nth (endonuclease III) and Nei (endonulease VIII) increased the sensitivity to gamma-rays, whereas it did not affect the sensitivity to alpha-particles. Increased sensitivity to gamma-rays also occurred in E. coli overproducing human 8-oxoguanine-DNA glycosylase (hOgg1). Treatment of gamma-irradiated plasmid DNA with purified MutM converted the covalently closed circular to the linear form of the DNA. On the other hand, overproduction of MutM conferred resistance to H2O2 on the E. coli mutM nth nei mutant. CONCLUSIONS: The levels of DNA glycosylases affect the sensitivity of E. coli to gamma-rays and X-rays. Excessive excision by DNA glycosylases converts nearly opposite base damage in clustered DNA damage to double-strand breaks, which are potentially lethal.     

DNA damage in cultured skin microvascular endothelial cells exposed to gamma rays and treated by the combination pentoxifylline and alpha-tocopherol

PURPOSE: This in vitro study aims at evaluating the effect of the combination of pentoxifylline (PTX) and trolox (Tx), the water-soluble analogue of alpha-tocopherol, on the oxidative state and DNA damage in dermal microvascular endothelial cells exposed to doses up to 10 Gy of ionizing radiation. MATERIALS AND METHODS: Confluent primary cultures of dermal endothelial cells were gamma irradiated at 3 and 10 Gy, and 0.5 mM of both drugs, PTX and Tx, was added either before (15 min) or after (30 min or 24 h) irradiation. Reactive oxygen species (ROS), measured by the dichlorodihydrofluorescein diacetate assay, and DNA damage, assessed by the comet and micronucleus assays, were measured at different times after exposure (0 - 21 days). RESULTS: The PTX/Tx treatment decreased the early and delayed peak of ROS production by a factor of 2.8 in 10 Gy-irradiated cells immediately after irradiation and the basal level by a factor of 2 in non-irradiated control cells. Moreover, the level of DNA strand breaks, as measured by the comet assay, was shown to be reduced by half immediately after irradiation when the PTX/Tx treatment was added 15 min before irradiation. However, unexpectedly, it was decreased to a similar extent when the drugs were added 30 min after radiation exposure. This reduction was accompanied by a 2.2- and 3.6-fold higher yield in the micronuclei (MN) frequency observed on days 10 and 14 post-irradiation, respectively. CONCLUSION: These results suggest that oxidative stress and DNA damage induced in dermal microvascular endothelial cells by radiation can be modulated by early PTX/Tx treatment. These drugs acted not only as radical scavengers, but they were also responsible for the increased MN frequency in 10 Gy-irradiated cells. Thus, these drugs may cause a possible interference with DNA repair processes.     

Induction and Repair of DNA Strand Breaks in Cultured Mammalian Cells Following Fast Neutron Irradiation

Summary

Induction and repair of DNA breaks following irradiation with NIRS cyclotron neutrons were studied in cultured mammalian cells (L5178Y) in comparison to those following γ-rays.

The yield of the total single-strand breaks, 3′OH terminals and sites susceptible to S₁ endonuclease following fast neutrons was found to be approximately 50 per cent of that following γ-irradiation. On the other hand, the yield of double-strand breaks was slightly higher after fast neutrons than after γ-rays. The percentage of the total single-strand breaks remaining unrejoined at 3 hours after post-irradiation incubation was found to be distinctly higher after the fast neutrons than after γ-rays. The neutron-induced damage appears to carry a higher proportion of alkali-labile lesions compared to γ-rays.

It was concluded that the increase in the yield of double-strand breaks and of unrejoinable breaks is responsible for a high r.b.e. of the cyclotron neutrons.     

Effect of heat on induction and repair of DNA strand breaks in X-irradiated CHO cells.

Chinese hamster ovary cells were exposed to various heat treatments followed by X-irradiation, and the induction and repair of DNA strand breaks was studied using the alkaline unwinding technique. Heat treatments alone were found to cause DNA strand breakage only for temperatures greater than or equal to 43 degrees C, whereas the number of radiation-induced strand breaks was unaffected by additional heating. Strand break repair was studied for irradiated cells preheated at temperatures ranging from 42 degrees C to 45 degrees C. The total repair curve could be separated into three phases, a fast (t = 0-15 min), an intermediate (t = 15-120 min) and a slow (t greater than or equal to 120 min) phase. All phases were altered when cells were heated either prior to or after irradiation. The fast and the intermediate phase could be well interpreted by the assumption that irradiation leads to both primary and secondary single-strand breaks, the latter being generated by enzymatic incision at sites of damaged bases. For irradiation alone, the ratio of all secondary strand breaks to all primary breaks was fsec = 1.5 +/- 0.5. This ratio was not altered by preceding heat treatments (mean fsec = 1.7 +/- 0.2). The main effect of heating on the repair kinetics of single-strand breaks was an increase in the repair half-time of primary and secondary breaks (maximum increase by a factor of 3.4), whereas the generation of secondary breaks was only slightly retarded (factor 1.3). The slow repair phase, which is assumed to represent the repair of DNA double-strand breaks, was best described by a single exponential component. The half-time of this component was found to increase from tau slow = 170 +/- 70 min for non-heated cells to tau slow = 345 +/- 80 min for cells heated at 45 degrees C for 20 min, indicating that heat inhibited the repair of double-strand breaks. For irradiation alone, the initial fraction of the slow component was fslow = 0.065 +/- 0.004. This fraction was enhanced by additional heating, with a maximum increase by a factor of 2.7 for cells heated at 45 degrees C for 20 min. This elevation cannot be the result of an enhanced induction of double-strand breaks, but must be associated with an additional formation of slowly repaired strand breaks during repair incubation. These additional strand breaks must arise from strand breaks which in non-heated cells are repaired during the fast or intermediate phase.(ABSTRACT TRUNCATED AT 400 WORDS)     

Radiation-induced DNA damage and repair in quiescent and proliferating human tumor cells in vitro

The purpose of this study was to examine radiation-induced DNA strand breakage and repair in quiescent and proliferating human tumor cells in vitro and determine their relationship to radiation sensitivity and potentially lethal damage repair (PLDR). Using centrifugal elutriation we have isolated from fed plateau-phase cultures of HEp-3 human squamous carcinoma cells, relatively pure populations of quiescent and proliferating cells. This was confirmed by both [3H]-thymidine labelling and acridine orange (AO) staining with flow cytometry. Quiescent cells were more sensitive to ionizing radiation (Do = 0.97 Gy) than were proliferating cells (Do = 1.28 Gy). However, quiescent cells showed higher repair of potentially lethal damage (PLDR) than did proliferating cells. Repair of single-strand breaks (ssb) and double-strand breaks (dsb) as measured by filter elution did not differ significantly between quiescent and proliferating cells. For both populations, ssb and dsb repair kinetics and final damage remaining were the same, suggesting that repair of DNA strand breaks is not entirely responsible for the difference in radiation sensitivity between quiescent and proliferating cells.     

Cellular Responses to Ionizing Radiation: Effects of Interrupting DNA Repair with Chemical Agents

Summary

This review is concerned with the influence of different classes of chemical agents on cellular repair of DNA damage induced by ionizing radiation. Single-strand break rejoining is little affected by inhibitors of DNA synthesis; however, such inhibitors do lead to a persistence of double-strand breaks in the DNA, and this correlates with an enhancement of chromosome aberrations and cell killing. Experiments with antagonists of topoisomerase II suggest an intriguing role for this DNA unwinding enzyme in double-strand break repair. Interference with poly(ADP-ribose) synthesis, by means of the inhibitor 3-aminobenzamide, does not have a clear-cut effect on recovery from ionizing radiation damage. Various substances (for example, caffeine and trypsin) affect DNA repair via a modulation of the cell cycle, altering the time available to the cell for repairing potentially lethal DNA damage before such damage is ‘fixed’ by the process of DNA replication. Finally, disturbing cellular energy metabolism, and depressing the level of ATP, can inhibit the repair of radiation damage.     

CHEF electrophoresis, a sensitive technique for the determination of DNA double-strand breaks

It has been demonstrated that clamped homogeneous electrical field (CHEF) electrophoresis is a suitable method for the determination of DNA double-strand breaks in Chinese hamster ovary (CHO) cells. It allows the separation of DNA molecules up to 10 Mbp. The fraction of DNA fragments of this size is correlated with the number of radiation induced double-strand breaks. The resolution limit of the technique is equivalent to the effect of about 1 Gy (gamma-rays). Double-strand break repair was monitored after irradiation with Co-60 gamma rays and the repair time constant determined to t1/2 = 30-35 min. In combination with the detection of DNA by fluorescence, CHEF electrophoresis provides an easy and sensitive method for the determination of double-strand break repair which does not require the radioactive labelling of cells.     

Effects of aphidicolin on cell recovery and repair of DNA damage in irradiated human fibroblasts]

The effect of aphidicolin, a specific inhibitor of DNA polymerases alpha and delta, on recovery and repair of X-irradiated human fibroblasts was investigated. Aphidicolin concentrations from 0.5 to 5 micrograms/ml reduce DNA synthesis in exponentially growing cells after short incubation periods (1 h), longer incubation times (24 h) enhance this effect. Colony forming ability of unirradiated fibroblasts, treated in confluent growth state with aphidicolin, was not reduced. After incubation with aphidicolin contact-inhibited fibroblasts show reduced PLD recovery. For the short preincubation time (1 microgram/ml) the effect depends on aphidicolin concentration, for the long preincubation period the effect is independent of concentration. DNA double-strand break induction and rejoining was investigated after combined action of aphidicolin and X-rays using the neutral filter elution technique. The yield of initial DNA double-strand breaks was not affected by aphidicolin. After a 90-min recovery time, however, DNA double-strand break rejoining was markedly reduced. This effect was dependent on concentration for the short incubation time (1 h) but not for the long preincubation (24 h).     

Low-dose hyper-radiosensitivity of progressive and regressive cells isolated from a rat colon tumour: impact of DNA repair

PURPOSE: To ask whether highly metastatic sublines show more marked low-dose hyper-radiosensitivity (HRS) response than poorly metastatic ones. MATERIALS AND METHODS: The progressive (PRO) subline showing tumourigenicity and metastatic potential and the regressive (REG) subline showing neither tumourigenicity nor metastatic potential were both isolated from a parental rat colon tumour. Clonogenic survival, micronuclei and apoptosis, cell cycle distribution, DNA single- (SSB) and double-strand breaks (DSB) induction and repair were examined. RESULTS: HRS phenomenon was demonstrated in PRO subline. Before irradiation, PRO cells show more spontaneous damage than REG cells. After 0.1 Gy, PRO cells displayed: (i) More DNA SSB 15 min post-irradiation, (ii) more unrepaired DNA DSB processed by the non-homologous end-joining (NHEJ) and by the RAD51-dependent recombination pathways, (iii) more micronuclei, than REG cells while neither apoptosis nor p53 phosphorylation nor cell cycle arrest was observed in both sublines. CONCLUSIONS: HRS response of PRO subline may be induced by impairments in NHEJ repair that targets G(1) cells and RAD51-dependent repair that targets S-G(2)/M cells. The cellular consequences of such impairments are a failure to arrest in cell cycle, the propagation of damage through cell cycle, mitotic death but not p53-dependent apoptosis. Tumourigenic cells with high metastatic potential may preferentially show HRS response.     

Mechanism of protection against radiation-induced DNA damage in plasmid pBR322 by caffeine

PURPOSE: Caffeine (1,3,7-trimethyl xanthine), a dietary component, has been shown to have widely varying effects on DNA damage induced by UV and ionizing radiation, depending upon pre- or post-irradiation administration and its concentration. Caffeine administered post-UV irradiation is known to inhibit enzymatic repair of DNA lesions, leading to potentiation of damage, whereas its presence before or during irradiation elicits protection in a wide range of test systems: bacteria, cultured human cells, plant seeds and mouse. The purpose of this study is to test whether caffeine present during gamma-irradiation of plasmid DNA, a system devoid of replication and repair, could elicit protection by scavenging free radicals. MATERIALS AND METHODS: Plasmid pBR322 DNA was exposed to gamma-radiation in the presence or absence of caffeine at a dose-rate of 1.20 Gy min(-1) and damage measured as single-strand breaks. To understand the mechanisms of the observed protection, especially under oxic conditions, reaction of caffeine with superoxide radical (O(2)(-)), hydrogen peroxide (H(2)O(2)) and the deoxyribose peroxyl radical (ROO(*)) were studied. RESULTS: Irradiation of pBR322 was observed to induce a dose-dependent increase in single-strand breaks. Caffeine itself did not induce strand breaks but reduced radiation-induced strand breaks at micromolar to millimolar concentrations. Caffeine has been shown to react with the radiation-derived oxidants. The reaction rate constants observed were 7.5x10(1) M(-1) s(-1) with O(2)(-) 1.05x10(8) M(-1) s(-1) with ROO(*) and 8.8x10(1) M(-1) s(-1) with H(2)O(2). CONCLUSIONS: Caffeine effectively protects DNA against ionizing radiation in a system devoid of repair and replication machinery. Thus, DNA protection shown by caffeine is possibly due to the scavenging of radiation-derived primary as well as secondary reactive oxygen species, and this physicochemical protective pathway possibly pre-empts any subsequent inhibitory effect of caffeine on the enzymatic repair of DNA.