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

Chinese hamster ovary (CHO) cells were exposed for 1 h to 60-Hz magnetic fields (0.1 or 2 mT), electric fields (1 or 38 V/m), or to combined magnetic and electric fields (2 mT and 38 V/m, respectively). Following exposure, the cells were lysed, and the DNA was analyzed for the presence of single-strand breaks (SSB), using the alkaline elution technique. No significant differences in numbers of DNA SSB were detected between exposed and sham-exposed cells. A positive control exposed to X-irradiation sustained SSB with a dose-related frequency. Cells exposed to nitrogen mustard (a known cross-linking agent) and X-irradiation demonstrated that the assay could detect cross-linked DNA under our conditions of electric and magnetic field exposures.     

Intermediate frequency magnetic fields do not have mutagenic, co-mutagenic or gene conversion potentials in microbial genotoxicity tests

We used bacterial mutation and yeast genotoxicity tests to evaluate the effects of intermediate frequency (IF; 2 kHz, 20 kHz and 60 kHz) magnetic fields (MFs) on mutagenicity, co-mutagenicity and gene conversion. We constructed a Helmholtz type exposure system that generated vertical and sinusoidal IF MFs, such as 0.91 mT at 2 kHz, 1.1 mT at 20 kHz and 0.11 mT at 60 kHz. Mutagenicity, co-mutagenicity and gene conversion assays were performed for each of the three MF exposure conditions. Mutagenicity testing was performed in four strains of Salmonella typhimurium (TA98, TA100, TA1535 and TA1537) and two strains of Escherichia coli (WP2 uvrA and WP2 uvrA/pKM101) to cover a wide spectrum of point mutations. For co-mutagenicity tests, we used four sensitive test strains (TA98, TA100, WP2 uvrA and WP2 uvrA/pKM101) with five chemical mutagens (t-butyl hydroperoxide (BH, a hydroxyl free radical precursor), 2-(2-furyl)-3-(5-nitro-2-furyl) acrylamide (AF2) and N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG, DNA reactive reagents), benz[a]pyrene (BaP) and 2-aminoanthracene (2AA, DNA reactive promutagens). Gene conversion testing was performed in the yeast test strain, Saccharomyces cerevisiae XD83. We also examined the effects on the repair process of DNA damage by UV irradiation. No statistically significant effects were observed between exposed and control groups in any of the genotoxicity tests, indicating that the IF MFs (0.91 mT at 2 kHz, 1.1 mT at 20 kHz or 0.11 mT at 60 kHz) do not have mutagenic or co-mutagenic potentials for the chemical mutagens tested under these experimental conditions. Our findings also indicate that these IF MFs do not induce gene conversion or affect the repair process of DNA damage in eukaryotic cells.     

Rats are not aversive when exposed to 60-Hz magnetic fields at 3.03 mT.

Thirty-two male rats were tested in two replicates of an experiment to determine whether body currents induced by 60-Hz magnetic fields might lead to avoidance behavior comparable to that which results from exposure to strong 60-Hz electric fields. The test apparatus was a two-compartment Plexiglas shuttlebox enclosed in a sound-attenuating plywood chamber, which in turn was encompassed by two copper bus bars that, when energized, served as a source of 60-Hz magnetic fields. Location of the rat, and traverse activity in the shuttlebox were monitored by nine infra-red photo detectors equally spaced along the length of the apparatus. Rats were divided into 2 groups: 1 group of rats (n = 8 per group per replicate) was sham exposed while rats in the other group (n = 8 per group per replicate) were exposed to a 3.03 mT (30.3 G), 60-Hz magnetic field whenever they traversed to or were located on the side (L or R) predetermined as the exposed side. To control artifact incident to side preference, the side exposed (L or R) was alternated over the exposed rats. Each rat was tested individually in a 1-h session. A 2-factor ANOVA (exposed vs. control, replicate 1 vs. replicate 2) failed to reveal any significant effects due to either factor or to an interaction between factors. These data demonstrate that rats do not avoid exposure to 60-Hz magnetic fields at a flux density of 3.03 mT and further imply that the avoidance by rats of high level 60-Hz electric fields is mediated by something other than the internal body currents induced by the exposure.     

50-Hz extremely low frequency electromagnetic fields enhance cell proliferation and DNA damage: possible involvement of a redox mechanism

HL-60 leukemia cells, Rat-1 fibroblasts and WI-38 diploid fibroblasts were exposed for 24-72 h to 0.5-1.0-mT 50-Hz extremely low frequency electromagnetic field (ELF-EMF). This treatment induced a dose-dependent increase in the proliferation rate of all cell types, namely about 30% increase of cell proliferation after 72-h exposure to 1.0 mT. This was accompanied by increased percentage of cells in the S-phase after 12- and 48-h exposure. The ability of ELF-EMF to induce DNA damage was also investigated by measuring DNA strand breaks. A dose-dependent increase in DNA damage was observed in all cell lines, with two peaks occurring at 24 and 72 h. A similar pattern of DNA damage was observed by measuring formation of 8-OHdG adducts. The effects of ELF-EMF on cell proliferation and DNA damage were prevented by pretreatment of cells with an antioxidant like alpha-tocopherol, suggesting that redox reactions were involved. Accordingly, Rat-1 fibroblasts that had been exposed to ELF-EMF for 3 or 24 h exhibited a significant increase in dichlorofluorescein-detectable reactive oxygen species, which was blunted by alpha-tocopherol pretreatment. Cells exposed to ELF-EMF and examined as early as 6 h after treatment initiation also exhibited modifications of NF kappa B-related proteins (p65-p50 and I kappa B alpha), which were suggestive of increased formation of p65-p50 or p65-p65 active forms, a process usually attributed to redox reactions. These results suggest that ELF-EMF influence proliferation and DNA damage in both normal and tumor cells through the action of free radical species. This information may be of value for appraising the pathophysiologic consequences of an exposure to ELF-EMF.     

Effects of Extremely Low Frequency (Elf) Electric Fields On Cell Growth and Dna Repair In Human Skin Fibroblasts

Abstract. A number of physical and chemical agents in the environment have been studied for their ability to induce or alter DNA repair mechanisms in human cells. We have investigated the effects of 60 Hz, 1000 V/cm electric fields on DNA repair in normal human fibroblasts in vitro. an examination was done on the ability of electric fields suspected to cause damage which could be repaired by thymine dimer excision and measurable by the bromodeoxyuridine photolysis assay. the thymine dimer assay with enzyme-sensitive site analysis was used to measure the cells' capacity for removing ultraviolet light (u.v.)-induced pyrimidine dimers; (i) during exposure to electric field 24 hr before U.V. irradiation; (ii) 24 hr after U.V. irradiation; and (iii) up to 48 hr continuously after U.V. irradiation. Cell growth and cell survival following electric field exposure were also studied. Within the limits of these experiments, it was found that exposure to such electric fields did not alter cell growth or survival, and no DNA repair or alteration in DNA excision repair capacity was observed as compared with unexposed control cultures.     

Effect of ambient levels of power-line-frequency electric fields on a developing vertebrate

Fertilized eggs of Gallus domesticus were exposed continuously during their 21-day incubation period to either 50- or 60-Hz sinusoidal electric fields at an average intensity of 10 Vrms/m. The exposure apparatus was housed in an environmental room maintained at 37 degrees C and 55-60% relative humidity (RH). Within 1.5 days after hatching, the chickens were removed from the apparatus and tested. The test consisted of examining the effect of 50- or 60-Hz electromagnetic fields at 15.9 Vrms/m and 73 nTrms (in a local geomagnetic field of 38 microT, 85 degrees N) on efflux of calcium ions from the chicken brain. For eggs exposed to 60-Hz electric fields during incubation, the chicken brains demonstrated a significant response to 50-Hz fields but not to 60-Hz fields, in agreement with the results from commercially incubated eggs [Blackman et al., 1985a]. In contrast, the brains from chicks exposed during incubation to 50-Hz fields were not affected by either 50- or 60-Hz fields. These results demonstrate that exposure of a developing organism to ambient power-line-frequency electric fields at levels typically found inside buildings can alter the response of brain tissue to field-induced calcium-ion efflux. The physiological significance of this finding has yet to be established.     

Effects of homogeneous and inhomogeneous static magnetic fields combined with gamma radiation on DNA and DNA repair

The aim of this study was to reveal whether static magnetic fields (SMFs) influence the repair of radiation‐damaged DNA on leukocytes or has any effect on DNA. After 4 Gy of ⁶⁰Co‐γ irradiation, some of the samples were exposed to inhomogeneous SMFs with a lateral magnetic flux density gradient of 47.7, 1.2, or 0.3 T/m by 10 mm lateral periodicity, while other samples were exposed to homogeneous SMF of 159.2 ± 13.4 mT magnetic flux density for a time period of 0.5 min, 1, 2, 4, 6, 18, 20, or 24 h. Another set of samples was exposed to the aforementioned SMFs before gamma irradiation. The following three groups were examined: (i) exposed to SMF only, (ii) exposed to SMF following irradiation by ⁶⁰Co‐γ, and (iii) exposed to SMF before ⁶⁰Co‐γ irradiation. The analysis of the DNA damage was made by single‐cell gel electrophoresis technique (comet assay). Statistically significant differences were found at 1 h (iSMF), 4 h (hSMF), and 18 h (hSMF) if samples were exposed to only SMF, compared to control. When the SMF exposure followed the ⁶⁰Co‐γ irradiation, statistically significant differences were found at 1 h (iSMF) and 4 h (hSMF). If exposure to SMF preceded ⁶⁰Co‐γ irradiation, no statistically significant difference was found compared to 4 Gy gamma‐irradiated group. Bioelectromagnetics 31:488–494, 2010. © 2010 Wiley‐Liss, Inc.     

Effects of extremely low frequency (ELF) electric fields on cell growth and DNA repair in human skin fibroblasts

A number of physical and chemical agents in the environment have been studied for their ability to induce or alter DNA repair mechanisms in human cells. We have investigated the effects of 60 Hz, 1000 V/cm electric fields on DNA repair in normal human fibroblasts in vitro. An examination was done on the ability of electric fields suspected to cause damage which could be repaired by thymine dimer excision and measurable by the bromodeoxyuridine photolysis assay. The thymine dimer assay with enzyme-sensitive site analysis was used to measure the cells' capacity for removing ultraviolet light (u.v.)-induced pyrimidine dimers; during exposure to electric field 24 hr before u.v. irradiation; 24 hr after u.v. irradiation; and up to 48 hr continuously after u.v. irradiation. Cell growth and cell survival following electric field exposure were also studied. Within the limits of these experiments, it was found that exposure to such electric fields did not alter cell growth or survival, and no DNA repair or alteration in DNA excision repair capacity was observed as compared with unexposed control cultures.     

Chronic exposure of primates to 60-Hz electric and magnetic fields: III. Neurophysiologic effects

The neurophysiologic effects of combined 60-Hz electric (E) and magnetic (B) fields, of magnitudes comparable to those produced by high-voltage powerlines, were investigated in 10 monkeys (Macaca nemestrina). Six animals (experimental group) were each exposed to three different levels of E and B fields: 3 kV/m and 0.1 G, 10 kV/m and 0.3 G, and 30 kV/m and 0.9 G. Field exposures were preceded and followed by sham exposures, during which factors of field generation were present (e.g., heat, vibration, noise, etc.) without E and B fields. Each of the five segments (i.e., the three exposure segments and the initial and final sham exposure segments) lasted 3 weeks. Animals were exposed for 18 h/day (fields on at 1600 h, off at 1000 h). Four other animals (external control group) were given sham exposure for the entire 15-week period. Auditory, visual, and somatosensory evoked potentials were recorded twice a week, during the daily 6-h field-off period. E- and B-field exposure had no effect on the early or mid-latency evoked potential components, suggesting that exposure at these levels has no effect on peripheral or central sensory afferent pathways. However, there was a statistically significant decrease in the amplitudes of late components of the somatosensory evoked potential during the 10kV/m and 0.3 G, and 30 kV/m and 0.9 G exposure levels. This result is possibly related to the opiate antagonist effect of electromagnetic field exposure reported by others.     

Sinusoidal 60 Hz electromagnetic fields failed to induce changes in protein synthesis in Escherichia coli

Escherichia coli JM83 {F^? ara Δ(lac-proAB) rpsL [?80dΔ(lacZ)M15]} in midlog growth phase at 30 °C were exposed to 60 Hz sinusoidal magnetic field of 3 mT of nonuniform diverging flux, inducing a nonuniform electric field with a maximum intensity of 32 μV/cm using an inductor coil. Exposed and unexposed control cells were maintained at 30.8 ± 0.1 °C and 30.5 ± 0.1 °C, respectively. Quadruplicate samples of exposed and unexposed E. coli cells were simultaneously radiolabeled with ³⁵S-L-methionine at 10 min intervals over 2 hr. Radiochemical incorporation into proteins was analyzed via liquid scintillation counting and by denaturing 12.5% polyacrylamide gel electrophoresis. The results showed that E. coli exposed to a 60 Hz magnetic field of 3 mT exhibited no qualitative or quantitative changes in protein synthesis compared to unexposed cells. Thus small prokaryotic cells (less than 2 μm × 0.5 μm) under constant-temperature conditions do not alter their protein synthesis following exposure to 60 Hz magnetic fields at levels at 3 mT. © 1994 Wiley-Liss, Inc.     

Cyclic AMP response in cells exposed to electric fields of different frequencies and intensities

The action on intracellular cyclic AMP (cAMP) of therapeutically used 4000-Hz electric fields was investigated and compared with 50-Hz data. Cultured mouse fibroblasts were exposed for 5 minutes to 4000-Hz sine wave internal electric fields between 3 mV/m and 30 V/m applied within culture medium. A statistically significant decrease in cellular cAMP concentration relative to unexposed cells was observed for fields higher than 10 mV/m. The drop in cAMP was most pronounced at lower field strengths (71 % of controls at 30 mV/m) and tended to disappear at higher field strengths. An increase of cAMP content was observed with 50-Hz electric fields, as was also the case when 4000-Hz fields were modulated with certain low frequencies.     

Repair of X-ray induced DNA strand damage by isolated rat splenic lymphocytes.

Although a number of chemicals can alter DNA repair function, little is known about the effect of chronic, low dose exposure to environmental agents on DNA repair capacity. Lymphocytes provide a potential target population to study the effects of chronic exposures to low doses of toxic chemicals since they are an easily obtainable cell population. Prior to investigating the repair capacity of chemically exposed lymphocytes, the repair by chemically naive lymphocytes has been characterized. In the present study, the DNA repair capacity of isolated rat lymphocytes was characterized. The capacity of these cells to repair single-strand DNA breaks (SSB) was determined after in vitro treatments with X-rays. The effect of in vitro exposure to 3-aminobenzamide (3-AB) on DNA repair capacity was also assessed. The levels of induced SSB and their repair were determined using the alkaline elution technique. Splenic lymphocytes were isolated and placed in culture medium 18 h prior to assessment of repair capacity, but were not stimulated with mitogens. A dose-dependent increase in SSB was observed following exposure of lymphocytes to 300 or 600 rad. The rate of SSB repair was analyzed after a dose of 400 rad. Approximately 80% of the DNA strand break repair was completed within 60 min. The half-time for repair of these lesions by lymphocytes was determined to be 21.3 min. Exposure to 3-AB resulted in a decrease in the rate of repair of the X-ray-induced strand breakage. Although no SSB were detected at the end of a 1-h 3-AB treatment of non-irradiated cells, significant accumulation of SSB was observed after a 2-h treatment. The characterization of DNA repair in rat lymphocytes following in vitro exposure to X-rays will allow us to investigate the effects of chronic, in vivo toxicant exposure on the capacity of isolated lymphocytes to repair DNA damage produced by X-rays.     

The influence of electric field exposure on bone growth and fracture repair in rats

Rats were exposed to a 60-Hz electric field at an unperturbed field strength of 100 kV/m to determine its affect on bone growth and fracture repair. Exposure of immature male and female rats for 20 h/day for 30 days did not alter growth rate, cortical bone area, or medullary cavity area of the tibia. In another experiment, midfibular osteotomies were performed and the juvenile rats were exposed at 100 kV/m for 14 days. Evaluation by resistance to deformation and breaking strength indicated that fracture repair was not as advanced in the exposed animals as in the sham-exposed animals. In another experiment measurements of resistance to deformation were made in adult rats at 16, 20, and 26 days after osteotomy. Fracture repair was slower in exposed compared to control animals at day 20 and, to a lesser extent, at day 16, but not at day 26.     

Endocrinological effects of strong 60-Hz electric fields on rats

Adult male rats were exposed or sham-exposed to 60-Hz electric fields without spark discharges, ozone, or significant levels of other secondary variables. No effects were observed on body weights or plasma hormone levels after 30 days of exposure at an effective field strength of 68 kV/m. After 120 days of exposure (effective field strength = 64 kV/m), effects were inconsistent, with significant reductions in body weight and plasma levels of follicle-stimulating hormone and corticosterone occurring in one replicate experiment but not in the other. Plasma testosterone levels were significantly reduced after 120 days of exposure in one experiment, with a similar but not statistically significant reduction in a replicate experiment. Weanling rats, exposed or sham-exposed in electric fields with an effective field strength of 80 kV/m from 20 to 56 days of age, exhibited identical or closely similar growth trends in body and organ weights. Hormone levels in exposed and sham-exposed groups were also similar. However, there was an apparent phase shift between the two groups in the cyclic variations of concentrations of hormones at different stages of development, particularly with respect to follicle-stimulating hormone and corticosterone. We concluded that 60-Hz electric fields may bring about subtle changes in the endocrine system of rats, and that these changes may be related to alterations in episodic rhythms.     

Growth inhibition and DNA damage induced by benzo[a]pyrene and formaldehyde in primary cultures of rat tracheal epithelial cells

The effects of benzo[a]pyrene (BAP) and formaldehyde (HCHO), alone and combined, on cell growth and DNA damage were determined in primary cultures of rat tracheal epithelial cells dissociated from rat tracheas. Cell cultures treated with 25 microM BAP for 24 h or 200 microM HCHO for 90 min did not have a marked reduction in cell growth. However, their combined treatment reduced cell growth by 60% of control when cultures were exposed to BAP followed by HCHO as well as the reverse order. None of these treatments significantly decreased cell viability as judged by dye exclusion, nor did they enhance cell terminal differentiation as measured by cornified envelope formation. Alkaline elution analysis of DNA damage detected both DNA-protein crosslinks (DPC) and DNA single-strand breaks (SSB) as a result of HCHO treatment, whereas BAP treatment caused only SSB. While HCHO-induced SSB were repaired within 2 h, BAP-induced SSB were detected 3 days after treatment. Combined treatment of cell cultures with BAP followed by HCHO resulted in more SSB than was obtained from either agent alone, but less DPC than was detected from HCHO alone. The increased number of SSB obtained from this combined treatment may be related to the marked enhancement of carcinogenesis observed in earlier in vivo-in vitro studies.     

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.     

Analysis of the excision repair of nondimer DNA damage induced by solar ultraviolet radiation in ICR 2A frog cells

The excision repair of solar uv-induced nondimer DNA damage was examined in ICR 2A frog cells through the use of the bromodeoxyuridine (BrdUrd) photolysis assay. A relatively pure population of nondimer DNA photoproducts was induced by irradiation of ICR 2A cells with the Mylar-filtered solar ultraviolet (uv) wavelengths produced by a fluorescent sunlamp followed by exposure to photoreactivating light (PRL) which removes most of the small yield of pyrimidine dimers induced by this treatment. Cultures of cells were also exposed to 254 nm uv, which induces primarily dimers, and 60Co gamma rays. Through use of a modification of the BrdUrd photolysis assay possessing enhanced sensitivity, it was found that the solar uv-induced nondimer DNA damage was repaired by a short patch repair mechanism in which less than approximately 20 nucleotides are inserted into a repaired region. Similar results were also obtained for gamma-irradiated cells. In contrast, excision repair of 254-nm-induced dimers was accomplished by a long-patch process in which an average of about 180 nucleotides are inserted into the repaired sites.     

Integrator3, a Partner of Single-stranded DNA-binding Protein 1, Participates in the DNA Damage Response

Single-stranded DNA-binding protein 1 (SSB1) plays an important role in the DNA damage response and maintenance of genomic stability. Here, by using protein affinity purification, we have identified Integrator3 (INT3) as a novel partner of SSB1. INT3 forms a complex with SSB1 by constitutively interacting with SSB1 regardless of DNA damage. However, following DNA damage, along with SSB1, INT3 relocates to the DNA damage sites and regulates the accumulation of TopBP1 and BRCA1 there. Moreover, INT3 controls DNA damage-induced Chk1 activation and G₂/M checkpoint activation. In addition, INT3 is involved in homologous recombination repair by regulating Rad51 foci formation following DNA damage. Taken together, these results demonstrate that INT3 plays a key role in the DNA damage response.The DNA damage response, including DNA damage checkpoint activation and DNA damage repair, ensures genomic stability under genotoxic stress. Among various types of DNA damage, DNA double-strand breaks (DSBs)³ are the most deleterious, easily causing chromosomal loss, fusion, and translocation. However, cells can sense and repair DNA DSBs by activating evolutionarily conserved pathways (1–3). Following DNA DSBs, ATM, ATR, and DNAPK, a family homologous to phosphoinositide 3-kinases (4, 5), are activated and phosphorylate histone H2AX at the DNA damage sites (6). Subsequently, phospho-H2AX (γH2AX) provides the platform for accumulation of a larger group of DNA damage response factors, such as MDC1, BRCA1, 53BP1, and TopBP1 (2, 7–9), at the DNA damage sites. Translocalization of these proteins to the DNA DSBs facilitates DNA damage checkpoint activation by activating downstream Chk1/Chk2 kinases, which arrest the cell cycle at G₁, S, or G₂ phase (10). In addition, it also enhances the efficiency of DNA damage repair by recruiting and stabilizing the DNA repair machinery at the DNA damage sites (11).Among these important mediators, single-stranded DNA (ssDNA)-binding proteins play important roles during the DNA damage response. For example, following DNA damage, the MRN complex recognizes DNA DSB ends and processes the blunt ends into ssDNA overhangs (12). The replication protein A (RPA) complex, a group of ssDNA-binding proteins, immediately coats these ssDNA overhangs and loads and activates the ATR·ATRIP complex at the DNA damage sites (13). Meanwhile, the RPA complex protects ssDNA from nucleolytic resection and facilitates Rad51 filament formation along ssDNA overhangs, which is a key step for homologous recombination repair (14). Moreover, RPA70 and RPA32 subunits in the complex could recruit several DNA damage response factors to the DNA damage sites that enhance the efficacy of DNA damage repair (15).Besides the RPA complex, several other ssDNA-binding proteins have been identified to participate in the DNA damage response recently. One of them is ssDNA-binding protein 1 (SSB1) (16). Human SSB1 is a 211-amino acid polypeptide with an N-terminal oligosaccharide/oligonucleotide-binding (OB) domain. It has been shown that SSB1 is phosphorylated by ATM and relocates to the DNA damage site following DNA DSBs. Loss of SSB1 impairs DNA damage-induced checkpoint activation and induces genomic instability. Like the RPA complex, SSB1 participates in homologous recombination by facilitating Rad51·ssDNA filament formation and stabilizing Rad51 at the DNA damage sites. Interestingly, SSB1 has a homolog SSB2 that contains an almost identical OB domain at the N terminus. However, the function of SSB2 in the DNA damage response is not clear yet.To examine the molecular mechanism and functional pathway of SSB1 and SSB2 in the DNA damage response, we have searched for functional partners of SSB1 and SSB2 by using protein affinity purification. We have found Integrator3 (INT3) to be a common partner of both SSB1 and SSB2. Like SSB1, following DNA damage, INT3 relocates to the DNA damage sites and regulates ATR activation. Moreover, INT3 not only participates in DNA damage checkpoint activation but also regulates homologous recombination repair. Taken together, we have found a novel mediator in the DNA damage response.     

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.