Repair of chromatin damage in glutathione-depleted V-79 cells: comparison of oxic and hypoxic conditions

We have assessed the effects of two radiomodifying conditions, glutathione (GSH) depletion and hypoxia, on the formation and repair of radiation-induced chromatin damage, specifically DNA-protein cross-links (DPC). As measured by a nitrocellulose filter-binding assay, untreated V79 cells contain a low level of DPC (1-1.5% of the cellular DNA). The background level of DPC is elevated in cells treated with L-buthionine sulfoximine (BSO), in hypoxic cells, and in cells treated with BSO and made hypoxic (2.98%, 2.82%, and 7.71%, respectively). The dose response for production of radiation-induced DPC is approximately 6.0% DNA bound per 100 Gy for cells irradiated in air, and the dose response is not significantly different for BSO-treated cells but increases by a factor of about 1.4 for hypoxic cells and 1.7 for BSO-pretreated hypoxic cells. DPC were also assayed by alkaline elution with or without proteinase K treatment. By this analysis, the yield of DPC appears to be elevated in irradiated hypoxic and irradiated GSH-depleted cells. It is not possible to assay for background DPC alone in unirradiated cells by alkaline elution. Cells not exposed to BSO repair 70-80% of the radiation-induced DPC in 4 h. BSO-treated cells are considerably less efficient in repair of DPC. As analyzed by alkaline elution, GSH depletion had little or no effect on the yield of radiation-induced single-strand breaks (SSB) but slowed their repair. The data suggest that depletion of GSH impairs an enzyme system(s) responsible for the turnover of both background and radiation-induced DPC and that hypoxia elevates both the background level of DPC and the ratio of radiation-induced DPC to SSB.     

Binding of radiation-induced phenylalanine radicals to DNA: influence on the biological activity of the DNA and on its sensitivity to the induction of breaks by gamma-rays.

When an aqueous solution of double-stranded DNA of bacteriophage PM2 containing phenylalanine and saturated with N2O is irradiated with gamma-rays, radiation-induced phenylalanine radicals are bound covalently. Under the conditions used, about 25 phenylalanine molecules may be bound per lethal hit. For single-stranded PM2 DNA, most of the phenylalanine radicals bound are non-lethal. Evidence is presented that, in double-stranded DNA, an appreciable fraction of the single-strand breaks is induced by phenylalanine radicals. Radiation products of phenylalanine and the phenylalanine bound to the DNA decrease the sensitivity of the DNA to the induction of single-strand breaks. There are indications that the high efficiency of protection by radiation products of phenylalanine is due to their positive charge, which will result in a relatively high concentrations fo these compounds in the vicinity of the negatively-charged DNA molecules.     

Large T-antigen mutants define multiple steps in the initiation of simian virus 40 DNA replication.

The biochemical activities of a series of transformation-competent, replication-defective large T-antigen point mutants were examined. The assays employed reflect partial reactions required for the in vitro replication of simian virus 40 (SV40) DNA. Mutants which failed to bind specifically to SV40 origin sequences bound efficiently to single-stranded DNA and exhibited nearly wild-type levels of helicase activity. A mutation at proline 522, however, markedly reduced ATPase, helicase, and origin-specific unwinding activities. This mutant bound specifically to the SV40 origin of replication, but under certain conditions it was defective in binding to both single-stranded DNA and the partial duplex helicase substrate. This suggests that additional determinants outside the amino-terminal-specific DNA-binding domain may be involved in nonspecific binding of T antigen to single-stranded DNA and demonstrates that origin-specific DNA binding can be separated from binding to single-stranded DNA. A mutant containing a lesion at residue 224 retained nearly wild-type levels of helicase activity and recognized SV40 origin sequences, yet it failed to function in an origin-specific unwinding assay. This provides evidence that origin recognition and helicase activities are not sufficient for unwinding to occur. The distribution of mutant phenotypes reflects the complex nature of the initiation reaction and the multiplicity of functions provided by large T antigen.     

Biochemical alterations in human cells irradiated with alpha particles delivered by macro- or microbeams

Irradiation of individual cell nuclei with charged-particle microbeams requires accurate identification and localization of cells using Hoechst staining and UV illumination before computer-monitored localization of each cell. Using Fourier-transform infrared microspectroscopy (FT-IRM), we investigated whether the experimental conditions used for cell recognition induce cellular changes prior to irradiation and compared biochemical changes and DNA damage after targeted and nontargeted irradiation with alpha particles delivered by macro- or microbeams, using gamma radiation as a reference. Molecular damage in single HaCaT cells was studied by means of FT-IRM and comet assay (Gault et al., Int. J. Radiat. Biol. 81, 767-779, 2005). Hoechst 33342-stained HaCaT cells were exposed to single doses of 2 Gy (239)Pu alpha particles from a broad-beam irradiator, five impacted alpha particles from a microbeam irradiator, or 6 Gy gamma rays from (137)Cs, each of which resulted in about 5% clonogenic survival. FT-IRM of control cells indicated that Hoechst binding to nuclear DNA induced subtle changes in DNA conformation, and its excitation under UV illumination induced a dramatic shift of the DNA conformation from A to B as well as major DNA damage as measured by the comet assay. Comparison of the FT-IRM spectra of cells exposed to gamma rays or alpha particles specifically targeted to the nucleus, alpha particles from a broad-beam irradiator revealed spectral changes corresponding to all changes in constitutive bases in nucleic acids, suggesting oxidative damage in these bases, as well as structural damage in the deoxyribose-phosphate backbone of DNA and the osidic structure of nucleic acids. Concomitantly, spectral changes specific to protein suggested structural modifications. Striking differences in IR spectra between targeted microbeam- and nontargeted macrobeam-irradiated cells indicated greater residual unrepaired or misrepaired damage after microbeam irradiation. This was confirmed by the comet assay data. These results show that FT-IRM, together with the comet assay, is useful for assessing direct radiation-induced damage to nucleic acids and proteins in single cells and for investigating the effects of radiation quality. Significantly, FT-IRM revealed that Hoechst 33342 binding to DNA and exposure to UV light induce a dramatic change in DNA conformation as well as DNA damage. These findings suggest that fluorochrome staining should be avoided in studies of ionizing radiation-induced bystander effects based on charged-particle microbeam irradiation. An alternative cell nucleus recognition system that avoids nuclear matrix damage and its possible contribution to propagation of biological effects from irradiated cells to neighboring nontargeted cells needs to be developed.     

A modified neutral comet assay: elimination of lysis at high temperature and validation of the assay with anti-single-stranded DNA antibody

Comet assay under neutral conditions allows the detection of DNA double-strand breaks (DSB), considered to be the biologically relevant radiation-induced lesion. In this report, we describe modifications of the neutral comet method, which simplify and facilitate its use for estimation of DNA DSB in X-irradiated mammalian cells in culture. The analysis carried out according to this protocol takes less time than those most often applied. Also, the use of lysis at 50 degrees C is avoided; this is important in view of the presence of heat-labile sites in the chromatin of irradiated cells, recently reported by Rydberg [Radiation-induced heat-labile sites that convert into DNA double-strand breaks, Radiation Research 153 (2000) 805-812]. The comets have well-defined, sharp limits, suitable for image analysis. The chromatin of the hydrogen peroxide-treated or UV-C-irradiated cell remains condensed similarly to that of the control cells. We checked the neutral comets for the presence of single-stranded DNA by means of a specific antibody. The results point to a satisfactory sensitivity of the modified neutral comet assay and its specificity for DSB. The minimum detection level of the modified neutral comet assay is about 5 Gy.     

Radiosensitization by hypoxic pretreatment with misonidazole: an interaction of damage at the DNA level

Prolonged exposures to misonidazole (MISO) in vitro under hypoxic conditions result in radiosensitization which is characterized by a decrease in the size of the radiation survival curve shoulder for cells irradiated under hypoxic or aerobic conditions after drug removal. Although intracellular glutathione (GSH) was depleted during hypoxic exposures to MISO, this could not account for the dose-additive radiosensitization (decrease in shoulder size) since GSH depletion by diethylmaleate had no effect on the sensitivity of cells irradiated in air. The alkaline elution assay was used to measure DNA strand breaks and their repair after exposure to MISO, graded doses of X rays, and the combination of MISO pretreatment with X rays. The elution rate of DNA from irradiated cells increased linearly with X-ray dose, with and without MISO pretreatment. However, the DNA elution rates measured after MISO pretreatment were greater by a constant amount at all X-ray doses greater than 1 Gy. In terms of both cell survival and DNA elution rate, MISO-pretreated cells behaved as though they had received an extra 1.5 Gy. Although the initial damage after X rays was greater in MISO-pretreated cells, there was no effect of MISO pretreatment on the rate of repair of radiation-induced DNA strand breaks. The agreement between the differences in survival levels and DNA elution rates for irradiated control and MISO-pretreated cells and absence of an effect on DNA repair rates suggest that the pretreatment sensitization is due to an additive interaction of damage at the DNA level.     

DNA damage repair in quiescent murine mammary carcinoma cells in culture

Murine mammary carcinoma cells (line 67) were grown in unfed cultures for up to 9 days. In cultures (day 2-3) in which cells were proliferatively active and in day 3-5 (transition) cells, a large fraction of nuclear DNA was retained on polycarbonate filters when assayed by the alkaline filter elution technique. In contrast, the fraction of DNA retained on filters was significantly reduced for nonproliferating (Q, quiescent) cells from unfed 7-9 day cultures. The increase in endogenous DNA breaks followed both the decrease in proliferative state and clonogenicity in these cells. When day 7 Q cells were refed these endogenous DNA breaks were removed with a half-time of about 2.5 h. When the cells were exposed to X-irradiation and the integrity of their nuclear DNA measured by the alkaline filter elution assay, as much as a 2-fold greater frequency of radiation-induced DNA breaks was produced in Q versus P cells. DNA breaks were also removed from irradiated Q cells at a rate which was 0.23 that observed in P cells. We suggest that the depressed capacity for DNA damage removal in Q cells is responsible for their greater radiosensitivity, and the impaired DNA damage repair is probably due to a reduced level of energy sources in these unfed Q cell cultures.     

DNA damage measured using the alkaline elution assay depends on time between subculturing of cells and irradiation

In experiments utilizing the alkaline filter elution assay for radiation-induced DNA damage we observed an unexpected dependence of hypoxic dose-response curves on the length of time V79 cells were in exponential growth between subculturing and irradiation. Dose-response curves for DNA from cells irradiated in air were identical regardless of whether the exponential-phase cells had been subcultured 24 or 48 h prior to irradiation, but cells irradiated in hypoxia 24 h after subculture displayed a dose-response curve for DNA damage which was two times steeper than that obtained for cells irradiated in hypoxia 48 h after subculture. Possible mechanisms for this effect are discussed.     

Radiation affects binding of Fpg repair protein to an abasic site containing DNA

During the base excision repair of certain DNA lesions, the formamidopyrimidine-DNA glycosylase (Fpg) binds specifically to the DNA region containing an abasic (AP) site. Is this step affected by exposure to ionizing radiation? To answer this question, we studied a complex between a DNA duplex containing an analogue of an abasic site (the 1,3-propanediol site, Pr) and a mutated Lactococcus lactis Fpg (P1G-LlFpg) lacking strand cleavage activity. Upon irradiation of the complex, the ratio of bound/free partners decreased. When the partners were irradiated separately, the irradiated DNA still bound the unirradiated protein, whereas irradiated Fpg no longer bound unirradiated DNA. Thus irradiation hinders Fpg-DNA binding because of the damage to the protein. Using our radiolytic attack simulation procedure RADACK (Begusova et al., J. Biomol. Struct. Dyn. 19, 141-157, 2001), we reveal the potential hot spots for damage in the irradiated protein. Most of them are essential for the interaction of Fpg with DNA, which explains the radiation-induced loss of binding ability of Fpg. The doses necessary to destroy the complex are higher than those inactivating Fpg irradiated separately. As confirmed by our calculations, this can be explained by the partial protection of the protein by the bound DNA.     

Purification of a novel UV-damaged-DNA binding protein highly specific for (6-4) photoproduct.

UV damage-specific binding proteins are considered to play important roles in early responses of cells irradiated with UV, including damage recognition in the DNA repair process. We have surveyed nuclear and cytoplasmic proteins which bind selectively to UV-irradiated DNA using an electrophoretic mobility shift assay. We detected four distinct binding activities with different mobilities in fractions separated from HeLa cells by heparin chromatography. Three of them were found in nuclear extracts and one in cytoplasmic extracts. We purified one of the binding factors from nuclear extracts to homogeneity, which was designated NF-10 (the 10th fraction of nuclear extract on heparin chromatography). It migrated as a 40 kDa polypeptide in SDS-PAGE, and bound to UV-irradiated double- stranded DNA but not to unirradiated DNA. The binding pattern of the NF-10 protein to DNA irradiated with UV corresponded to the induction kinetics of (6-4) photoproduct. Removal of (6-4) photoproducts from UV- irradiated DNA by (6-4) photoproduct-specific photolyase diminished the binding of NF-10 protein. These results suggest that the NF-10 protein binds to UV-damaged DNA through (6-4) photoproduct. Immunoblot analysis using a monoclonal antibody revealed that the NF-10 protein was expressed in cell lines from all complementation groups of xeroderma pigmentosum, indicating that the NF-10 protein is a novel UV-damaged-DNA binding protein.     

Opposing effects of the UV lesion repair protein XPA and UV bypass polymerase eta on ATR checkpoint signaling

An essential component of the ATR (ataxia telangiectasia-mutated and Rad3-related)-activating structure is single-stranded DNA. It has been suggested that nucleotide excision repair (NER) can lead to activation of ATR by generating such a signal, and in yeast, DNA damage processing through the NER pathway is necessary for checkpoint activation during G1. We show here that ultraviolet (UV) radiation-induced ATR signaling is compromised in XPA-deficient human cells during S phase, as shown by defects in ATRIP (ATR-interacting protein) translocation to sites of UV damage, UV-induced phosphorylation of Chk1 and UV-induced replication protein A phosphorylation and chromatin binding. However, ATR signaling was not compromised in XPC-, CSB-, XPF- and XPG-deficient cells. These results indicate that damage processing is not necessary for ATR-mediated S-phase checkpoint activation and that the lesion recognition function of XPA may be sufficient. In contrast, XP-V cells deficient in the UV bypass polymerase eta exhibited enhanced ATR signaling. Taken together, these results suggest that lesion bypass and not lesion repair may raise the level of UV damage that can be tolerated before checkpoint activation, and that XPA plays a critical role in this activation.     

Modulation of DNA damage by pentoxifylline and alpha-tocopherol in skin fibroblasts exposed to Gamma rays

Previous in vivo studies showed the combination pentoxifylline (PTX) and alpha-tocopherol was highly efficient in reducing late radiation-induced skin damage. The present work aimed at investigating the molecular and cellular mechanisms involved in the effects of this combination. Primary cultures of confluent dermal fibroblasts were gamma-irradiated in the presence of PTX and trolox (Tx), the water-soluble analogue of alpha-tocopherol. Drugs were added either before or after radiation exposure and were maintained over time. Their antioxidant capacity and their effect on radiation-induced ROS production was assessed together with cell viability and clonogenicity. DNA damage formation was assessed by the alkaline comet assay and by the micronucleus (MN) test. Cell cycle distribution was also determined. The combination of PTX/ Tx was shown to reduce both immediate and late ROS formation observed in cells after irradiation. Surprisingly, decrease in DNA strand breaks measured by the comet assay was observed any time drugs were added. In addition, the micronucleus test revealed that for cells irradiated with 10 Gy, a late significant increase in MN formation occurred. The combination of PTX/Tx was shown to be antioxidant and to decrease radiation-induced ROS production. The observed effects on DNA damage at any time the drugs were added suggest that PTX/Tx could interfere with the DNA repair process.     

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.     

Effect of oxygen on radiation-induced DNA damage in isolated nuclei.

In intact mammalian cells, ionizing radiation causes substantially less damage to DNA in the absence of oxygen than in the presence of oxygen. In contrast, when DNA is isolated (usually from viruses) and irradiated in solution, the absence of oxygen does not lead to a decrease in damage unless low-molecular-weight thiols are also present. We investigated an intermediate condition: that of DNA irradiated in isolated nuclei. Using an HPLC-based assay of thiols with electrochemical detection, we have determined that the nuclear isolation procedure leads to the elimination of virtually all low-molecular-weight thiols (predominantly glutathione and cysteine). Thus it was our expectation that the thiol-depleted state would concurrently eliminate the OER, and thereby mimic the isolated DNA system, while retaining structural characteristics of chromosomal DNA. We evaluated radiation-induced DNA damage in isolated nuclei by measuring single-strand breaks using alkaline elution and by measuring double-strand breaks using neutral elution and pulsed-field gel electrophoresis. Despite the removal of low-molecular-weight thiol compounds, the oxygen dependence of radiation-induced damage more closely paralleled that of whole cells than that of DNA in solution. Thus damage of DNA irradiated in isolated nuclei is dependent on oxygen.     

Base excision repair of ionizing radiation-induced DNA damage in G1 and G2 cell cycle phases

Background

Major genomic surveillance mechanisms regulated in response to DNA damage exist at the G₁/S and G₂/M checkpoints. It is presumed that these delays provide time for the repair of damaged DNA. Cells have developed multiple DNA repair pathways to protect themselves from different types of DNA damage. Oxidative DNA damage is processed by the base excision repair (BER) pathway. Little is known about the BER of ionizing radiation-induced DNA damage and putative heterogeneity of BER in the cell cycle context. We measured the activities of three BER enzymes throughout the cell cycle to investigate the cell cycle-specific repair of ionizing radiation-induced DNA damage. We further examined BER activities in G2 arrested human cells after exposure to ionizing radiation.

Results

Using an in vitro incision assay involving radiolabeled oligonucleotides with specific DNA lesions, we examined the activities of several BER enzymes in the whole cell extracts prepared from synchronized human HeLa cells irradiated in G1 and G2 phase of the cell cycle. The activities of human endonuclease III (hNTH1), a glycosylase/lyase that removes several damaged bases from DNA including dihydrouracil (DHU), 8-oxoguanine-DNA glycosylase (hOGG1) that recognizes 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-oxoG) lesion and apurinic/apyrimidinic endonuclease (hAPE1) that acts on abasic sites including synthetic analog furan were examined.

Conclusion

Overall the repair activities of hNTH1 and hAPE1 were higher in the G1 compared to G2 phase of the cell cycle. The percent cleavages of oligonucleotide substrate with furan were greater than substrate with DHU in both G1 and G2 phases. The irradiation of cells enhanced the cleavage of substrates with furan and DHU only in G1 phase. The activity of hOGG1 was much lower and did not vary within the cell cycle. These results demonstrate the cell cycle phase dependence on the BER of ionizing radiation-induced DNA damage. Interestingly no evidence of enhanced BER activities was found in irradiated cells arrested in G2 phase.     

The potential value of the neutral comet assay and the expression of genes associated with DNA damage in assessing the radiosensitivity of tumor cells

The assessment of tumor radiosensitivity would be particularly useful in optimizing the radiation dose during radiotherapy. Therefore, the degree of correlation between radiation-induced DNA damage, as measured by the alkaline and the neutral comet assays, and the clonogenic survival of different human tumor cells was studied. Further, tumor radiosensitivity was compared with the expression of genes associated with the cellular response to radiation damage. Five different human tumor cell lines were chosen and the radiosensitivity of these cells was established by clonogenic assay. Alkaline and neutral comet assays were performed in γ-irradiated cells (2-8Gy; either acute or fractionated). Quantitative PCR was performed to evaluate the expression of DNA damage response genes in control and irradiated cells. The relative radiosensitivity of the cell lines assessed by the extent of DNA damage (neutral comet assay) immediately after irradiation (4Gy or 6Gy) was in agreement with radiosensitivity pattern obtained by the clonogenic assay. The survival fraction of irradiated cells showed a better correlation with the magnitude of DNA damage measured by the neutral comet assay (r=-0.9; P<0.05; 6Gy) than evaluated by alkaline comet assay (r=-0.73; P<0.05; 6Gy). Further, a significant correlation between the clonogenic survival and DNA damage was observed in cells exposed to fractionated doses of radiation. Of 15 genes investigated in the gene expression study, HSP70, KU80 and RAD51 all showed significant positive correlations (r=0.9; P<0.05) with tumor radiosensitivity. Our study clearly demonstrated that the neutral comet assay was better than alkaline comet assay for assessment of radiosensitivities of tumor cells after acute or fractionated doses of irradiation.     

Fusion of influenza hemagglutinin-expressing fibroblasts with glycophorin-bearing liposomes: role of hemagglutinin surface density

Influenza virus gains access to the cytoplasm of its host cell by means of a fusion event between viral and host cell membrane. Fusion is mediated by the envelope glycoprotein hemagglutinin (HA) and is triggered by low pH. To learn how many hemagglutinin trimers are necessary to cause membrane fusion, we have used two NIH 3T3 fibroblast cell lines that express HA protein at different surface densities. On the basis of quantitations of the number of HA trimers per cell and the relative surface areas of the two cell lines, the HAb-2 cells have a 1.9-fold higher plasma membrane surface density than the GP4F cells. The membrane lateral diffusion coefficient and the mobile fraction for HA is the same for both cell lines. A Scatchard analysis of the binding of glycophorin-bearing liposomes to the cells showed 1700 binding sites for the GP4F cells and 3750 binding sites for the HAb-2 cells, with effectively the same liposome-cell binding constant, about 7 x 10(10) M-1. Binding was specific for glycophorin on the liposomes and HA expressed on the cells. A competition experiment employing toxin-containing and empty liposomes allowed us to quantitate the number of liposomes that fused per cell, which was a small constant fraction of the number of bound liposomes. For the HAb-2 cells, about 1 in every 70 bound liposomes fused and for the GP4F cells about 1 in every 300 bound liposomes fused. Hence, the HAb-2 cells showed 4.4 times more fusion per bound liposome, even though the surface density of HA was only 1.9 times greater. We conclude the following: (i) One HA trimer is not sufficient to induce fusion. (ii) The HA bound to glycophorin is not the HA that induces fusion. That is, even though each HA has a binding and a fusion function, those functions are not performed by the same HA trimer.     

Visualization of DNA loops in nucleoids from HeLa cells: assays for DNA damage and repair

An assay for visualization of DNA loops undergoing supercoiling changes has been developed. The assay utilizes the fluorescent dye, propidium iodide (PI), which intercalates into the DNA and under the proper conditions causes the supercoiling status of the DNA to change. Thus, the DNA can be seen as a fluorescent halo that changes diameter with PI concentration. At low PI concentrations (0-7.5 micrograms/ml) the supercoils are relaxed with increasing PI, while at higher PI concentrations (7.50-50 micrograms/ml) supercoils in the opposite winding sense are rewound with increasing PI. When HeLa cells were irradiated with 1-20 Gy of 137Cs gamma-rays, the ability to rewind the DNA supercoils was inhibited in a dose-dependent manner, presumably because of the presence of radiation-induced DNA strand breakage, which removed the topological constraints on the DNA loops. These lesions were repaired rapidly during post-irradiation incubation. The ability of the DNA loops to be rewound was restored within 8 min after 10 Gy of gamma-irradiation, such that no difference from control cells could be detected. The half-time for repair of the radiation-induced lesions that inhibit DNA rewinding was similar to that for repair of DNA single strand breaks. The assay has certain advantages over current methods for assaying DNA damage in that it involves measurement of single cells and it does not require the DNA to be labeled with radioactive precursors.     

NADPH oxidase 4 mediates ROS production in radiation-induced senescent cells and promotes migration of inflammatory cells

Excessive DNA damage induced by ionising radiation (IR) to normal tissue cells is known to trigger cellular senescence, a process termed stress-induced premature senescence (SIPS). SIPS is often accompanied by the production of reactive oxygen species (ROS), and this is reported to be important for the initiation and maintenance of SIPS. However, the source of ROS during SIPS after IR and their significance in radiation-induced normal tissue damage remain elusive. In the present study, we tested the hypothesis that the NADPH oxidase (NOX) family of proteins mediates ROS production in SIPS-induced cells after IR and plays a role in SIPS-associated biological events. X-irradiation of primary mouse embryonic fibroblasts (MEFs) resulted in cellular senescence and the concomitant increase of intracellular ROS. Among all six murine NOX isoforms (NOX1–4 and DUOX1/2), only NOX4 was detectable under basal conditions and was upregulated following IR. In addition, radiation-induced ROS production was diminished by genetic or pharmacological inhibition of NOX4. Meanwhile, NOX4 deficiency did not affect the induction of cellular senescence after IR. Furthermore, the migration of human monocytic U937 cells to the culture medium collected from irradiated MEFs was significantly reduced by NOX4 inhibition, suggesting that NOX4 promotes the recruitment of inflammatory cells. Collectively, our findings imply that NOX4 mediates ROS production in radiation-induced senescent cells and contributes to normal tissue damage after IR via the recruitment of inflammatory cells and the exacerbation of tissue inflammation.     

Processing of clustered DNA damage generates additional double-strand breaks in mammalian cells post-irradiation

Clustered DNA damage sites, in which two or more lesions are formed within a few helical turns of the DNA after passage of a single radiation track, are signatures of DNA modifications induced by ionizing radiation in mammalian cells. Mutant hamster cells (xrs-5), deficient in non-homologous end joining (NHEJ), were irradiated at 37 degrees C to determine whether any additional double-strand breaks (DSBs) are formed during processing of gamma-radiation-induced DNA clustered damage sites. A class of non-DSB clustered DNA damage, corresponding to approximately 30% of the initial yield of DSBs, is converted into DSBs reflecting an artefact of preparation of genomic DNA for pulsed field gel electrophoresis. These clusters are removed within 4 min in both NHEJ-deficient and wild-type CHO cells. In xrs-5 cells, a proportion of non-DSB clustered DNA damage, representing approximately 10% of the total yield of non-DSB clustered DNA damage sites, are also converted into DSBs within approximately 30 min post-gamma but not post-alpha irradiation through cellular processing at 37 degrees C. That the majority of radiation-induced non-DSB clustered DNA damage sites are resistant to conversion into DSBs may be biologically significant at environmental levels of radiation exposure, as a non-DSB clustered damage site rather than a DSB, which only constitutes a minor proportion, is more likely to be induced in irradiated cells.