Formamidopyrimidine-DNA Glycosylase Enhances Arsenic-Induced DNA Strand Breaks in PHA-Stimulated and Unstimulated Human Lymphocytes.To confirm that arsenic (As) induces oxidative DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. damage in phytohemagglutinin phytohemagglutinin /phy·to·hem·ag·glu·ti·nin/ (-hem?ah-glldbomact´in-in) a hemagglutinin of plant origin. phy·to·he·mag·glu·ti·nin n. Abbr. (PHA PHA abbr. phytohemagglutinin PHA phytohemagglutinin, a plant lectin. )-stimulated and unstimulated human lymphocytes, we used the alkaline comet assay combined with specific enzyme [formamidopyrimidine-DNA glycosylase (FPG FPG Fasting plasma glucose, see there )] digestion to measure As-induced base damage. The results showed that the enzyme-sensitive sites were readily detected with the alkaline comet assay after the cells were treated with 10 [micro]M As for 2 hr. The repair patterns observed for FPG-created DNA single strand breaks (SSBs) in As-treated cells were comparable to those in hydrogen peroxide hydrogen peroxide, chemical compound, H2O2, a colorless, syrupy liquid that is a strong oxidizing agent and, in water solution, a weak acid. It is miscible with cold water and is soluble in alcohol and ether. ([H.sub.2][O.sub.2])-treated cells. The enzyme-created SSBs, As-induced base damage, were more significant in PHA-stimulated lymphocytes. About 63% and 68% of SSBs induced by As and [H.sub.2][O.sub.2], respectively, were repaired in PHA-stimulated lymphocytes by 2-hr repair incubation, but about 34% and 43%, respectively, were repaired in unstimulated cells. About 40% and 49% of base damage induced by As and [H.sub.2][O.sub.2], respectively, were repaired in PHA-stimulated lymphocytes, but about 19% and 21%, respectively, were repaired in unstimulated cells. These results indicated that As induced oxidative DNA damage in human lymphocytes at micromolar concentrations. The damaged bases could be chiefly purines or formamidopyrimidines. Like the damage induced by [H.sub.2][O.sub.2], As-induced DNA damage was repaired more slowly in unstimulated lymphocytes. Key wordy, arsenic, comet assay, formamidopyrimidine-DNA glycosylase (FPG), human lymphocytes, oxidative DNA damage. Environ Health Perspect 109:523-526 (2001). [Online 11 May 2001] http://ehpnet1.niebs.nih.gov/docs/2001/109p523-5261i/abstract.html An early study indicated that superoxide dismutase superoxide dismutase n. An enzyme that catalyzes the decomposition of a superoxide into hydrogen peroxide and oxygen. superoxide dismutase (SOD) and catalase catalase /cat·a·lase/ (kat´ah-las) a hemoprotein enzyme that catalyzes the decomposition of hydrogen peroxide to water and oxygen, protecting cells. (CAT) could prevent arsenic (As)-induced sister chromatid exchanges (SCEs) in cultured human lymphocytes (1). Recent studies showed similar results using reactive oxygen species reactive oxygen species, n molecules and ions of oxygen that have an unpaired electron, thus rendering them extremely reactive. Many cellular structures are susceptible to attack by ROS contributing to cancer, heart disease, and cerebrovascular disease. (ROS ROS, n.pr See reactive oxygen species. ) scavengers such as SOD, CAT, and dimethyl sulfoxide dimethyl sulfoxide (DMSO) Colourless, nearly odourless liquid organic compound. It mixes in all proportions with water, ethanol, and most organic solvents and dissolves a wide variety of compounds (but not aliphatic hydrocarbons). (DMSO DMSO dimethyl sulfoxide. DMSO n. Dimethyl sulfoxide; a colorless hygroscopic liquid obtained from lignin, used as a penetrant to convey medications into the tissues. DMSO, n. ) to counteract mutagenicity mutagenicity /mu·ta·ge·nic·i·ty/ (-je-nis´it-e) the property of being able to induce genetic mutation. mutagenicity the property of being able to induce genetic mutation. , DNA fragmentation, and micronuclei (MN) caused by As (2-4). We observed that DMSO and CAT basically abolished most of the As-induced DNA single strand breaks (SSBs) in human cells with single-cell gel electrophoresis (SCGE SCGE Single Cell Gel Electrophoresis ) assay (5). These observations have provided indirect but powerful evidence indicating that hydrogen peroxide ([H.sub.2][O.sub.2]) and superoxide anion ([O.sub.2-]) are chiefly involved in the genotoxicity Genotoxic substances are a type of carcinogen, specifically those capable of causing genetic mutation and of contributing to the development of tumors. This includes both certain chemical compounds and certain types of radiation. of As. However, it is known that ROS-induced DNA damage consists primarily of single strand breaks (SSBs), double strand breaks (DSBs), sites of base loss [apurinic/apyrimidinic (AP) sites], and base lesions (6). Great attention has been paid to ROS-related base damage. SSBs are repaired quickly by cells and of no biologic importance, and the damage of DSBs is important for understanding the lethal effects on cells, but ROS-induced base damage is believed to be one of the main contributors to carcinogenesis car·ci·no·gen·e·sis n. The production of cancer. carcinogenesis production of cancer. biological carcinogenesis viruses and some parasites are capable of initiating neoplasia. . More significantly, base modifications are potential biomarkers of oxidative DNA damage (7). DNA damage-specific endonucleases from Micrococcus luteus have been used previously in combination with sucrose gradient sedimentation (8), alkaline elution elution /elu·tion/ (e-loo´shun) in chemistry, separation of material by washing; the process of pulverizing substances and mixing them with water in order to separate the heavier constituents, which settle out in solution, from the (9), and alkaline unwinding (10) to reveal base damage inflicted by ionizing radiation. Now the gene for E. coli formamidopyridine-DNA (FPG) has been cloned and the protein purified to available homogeneity. This makes it possible to combine enzyme digestion with the newly developed sensitive alkaline comet assay to measure ROS-related base damage. FPG cleaves purines including 7,8-dihydro-8-oxoguanine (8-oxoG), formamidopyrimidines, and AP sites (11). Using lesion-specific enzymes in the comet assay to reveal DNA base damage has been described in detail by Collins et al. (12). Observations have been made on As-related alterations in base damage with FPG digestion in bovine aortic aortic pertaining to or emanating from the aorta. See also aortic arch. aortic aneurysm occurs most often in dogs, where it is caused by Spirocerca lupi larvae, turkeys and primates, causing dyspnea, cyanosis and coughing. endothelial cells (13) and in human vascular smooth muscle Vascular smooth muscle refers to the particular type of smooth muscle found within, and composing the majority of the wall of blood vessels. Vascular smooth muscle contracts or relaxes to both change the volume of blood vessels and the local blood pressure, a mechanism that cells (14). Detection of 8-hydroxydeoxyguanosine, a biomarker of oxidative DNA damage, was associated with As-related Bowen's disease (15). To clarify further that As induces oxidative DNA damage in human phytohemagglutinin (PHA)-stimulated and unstimulated lymphocytes, we applied the sensitive alkaline comet assay combined with FPG digestion to measure As-induced base lesions. We postulated that if AS produces oxidative DNA damage, this specific enzyme, having both DNA glycosylase and endonuclease endonuclease /en·do·nu·cle·ase/ (-noo´kle-as) any nuclease specifically catalyzing the hydrolysis of interior bonds of ribonucleotide or deoxyribonucleotide chains. activities, will recognize and cleave cleat, cleave claw of any cloven-footed animal. the damaged bases, and that consequently DNA strand breaks will be produced at enzyme-sensitive sites. The breaks, including AP sites, will be converted into comet tail by the alkaline comet assay (SCGE). As a result, the specific enzyme will increase the frequency and quantity of the tail moment induced by treatment of AS. Materials and Methods Cell treatment. We separated lymphocytes from peripheral blood of a healthy man. Briefly, we mixed 5 mL blood with 5 mL RPMI RPMI Rapid Prototyping & Manufacturing Institute RPMI Roswell Park Memorial Institute RPMI Royal Park Memorial Institute (culture medium) 1640 medium (Nikken, Osaka, Japan) and kept the mixture on ice for 15 min. We separated lymphocytes by centrifugation Centrifugation A mechanical method of separating immiscible liquids or solids from liquids by the application of centrifugal force. This force can be very great, and separations which proceed slowly by gravity can be speeded up enormously in centrifugal over 10 mL Ficoll-Hypaque solution (Amersham, Uppsala, Sweden), at 200 x g for 30 min at 4 [degrees] C. Lymphocytes above the Ficoll-Hypaque layer were washed two times at 200 x g for 5 min at 4 [degrees] C and suspended in RPMI 1640 complete culture medium containing 10% heat-inactivated fetal calf serum, 100 U/mL penicillin, and 100 [micro]g/mL streptomycin streptomycin (strĕp'tōmī`sĭn), antibiotic produced by soil bacteria of the genus Streptomyces and active against both gram-positive and gram-negative bacteria (see Gram's stain), including species resistant to other (Gibco BRL BRL In currencies, this is the abbreviation for the Brazilian Real. Notes: The currency market, also known as the Foreign Exchange market, is the largest financial market in the world, with a daily average volume of over US $1 trillion. , Gaithersburg, MD, USA) with a concentration of 2.5 x [10.sup.6] cells/mL in a 60-mm culture dish. The cells were immediately treated with 10 [micro]M arsenic [[As.sub.2][O.sub.3], prepared in [Ca.sup.2+]/[Mg.sup.2+]-free phosphate-buffered saline (PBS PBS in full Public Broadcasting Service Private, nonprofit U.S. corporation of public television stations. PBS provides its member stations, which are supported by public funds and private contributions rather than by commercials, with educational, cultural, ); Wako Pure Chemical Industries, Ltd., Osaka, Japan] under the conditions of 37 [degrees] C, 5% [CO.sub.2], and 95% air for 2 hr. For PHA stimulation, we cultured the separated lymphocytes (2.5 x [10.sup.6] cells/60-mm dish) in RPMI 1640 complete culture medium containing 2% PHA M (DIFCO, Detroit, MI, USA) for 70 hr in complete darkness and incubated them further with the same concentration of arsenic under the same conditions as in unstimulated cells. To compare the As- and [H.sub.2][O.sub.2]-induced DNA damage, we treated the cells ([10.sup.5] cells/mL) with 50 [micro]M [H.sub.2][O.sub.2] in PBS on ice for 5 min and then allowed to repair under the same conditions as above for As-treated cells. After treatment, the cells were washed twice and suspended in RPMI 1640 complete medium warmed at 37 [degrees] C at concentrations between 5 x [10.sup.5] and 1 x [10.sup.6] cells/mL for the comet assay. For the enzyme digestion experiment, the cells with or without As and [H.sub.2][O.sub.2] treatment were washed twice in PBS and then incubated for another 2 hr under the conditions of 37 [degrees] C, 5% [CO.sub.2], and 95% air in RPMI 1640 containing 20% heat-inactivated fetal calf serum, 100 U/mL penicillin, and 100 [micro]g/mL streptomycin to allow the cells to repair arsenic-induced DNA damage. During hourly intervals, samples of cells were processed for the comet assay combined with specific enzyme digestion. Comet assay (SCGE assay). We used an adaptation of the method introduced by Singh et al. (16). Briefly, cells with or without arsenic treatment were suspended in 0.75% low melting-point agarose agarose more highly purified form of agar with similar uses to agar and widely used in the separation of nucleic acid fragments. (Nusieve GTG (chat) gtg - Got to go. The user is about to stop chatting. , FMC See fixed mobile convergence. BioProducts, Rockland, NY, USA) in phosphate-buffered saline, pH 7.4, at 37 [degrees] C and pipetted onto a frosted glass microscope slide (Matsunami Glass Ind., Ltd., Kishiwata, Japan) precoated with a layer of 0.5% normal melting-point agarose (Sigma, St. Louis, MO, USA). Then the slide was subjected to a temperature of 4 [degrees] C for 10 min to consolidate the gel with a coverslip coverslip /cov·er·slip/ (-slip) coverglass. coverslip see coverglass. . After a third layer of 0.75% low melting-point agarose was applied and consolidated at 4 [degrees] C as described above, the slides were immersed in alkaline lysis solution (100 mM [Na.sub.2]-EDTA, 2.5 mM NaCl, 1% Na sarcosinate, 10 mM Tris, pH 10, 1% Triton X- 100 added fresh) at 4 [degrees] C for 1 hr to remove cellular proteins. After lysis lysis /ly·sis/ (li´sis) 1. destruction or decomposition, as of a cell or other substance, under influence of a specific agent. 2. mobilization of an organ by division of restraining adhesions. 3. , the slides were placed in a horizontal gel electrophoresis tank filled with fresh electrophoresis buffer (300 mM NaOH and 1 mM [Na.sub.2]-EDTA, pH 13) to a level of 0.25-0.5 cm above the slides to allow DNA to unwind for 20 min. Electrophoresis was conducted for next 20 min at 25 V and 300 mA using an electrophoresis compact power supply (ATTO Quintillionth (10 to the -18th power). See space/time. Corporation, Tokyo, Japan). Electrophoresis was performed in darkness and ice-cold surroundings to avoid further damage to DNA. After electrophoresis, slides were drained and flooded with three changes of neutralization neutralization, chemical reaction, according to the Arrhenius theory of acids and bases, in which a water solution of acid is mixed with a water solution of base to form a salt and water; this reaction is complete only if the resulting solution has neither acidic nor buffer (400 mM Tris-HCl, pH 7.5) for 5 min each. The slides were then stained with 50 [micro]L ethidium bromide (20[micro]g/mL; Sigma) and covered with a coverslip for image analysis. For specific enzyme digestion, we adapted the procedures introduced by Collins et al. (6). Briefly, cells were embedded in 0.75% low melting-point agarose at 37 [degrees] C and immediately processed for lysis after consolidation of the gel at 4 [degrees] C for 10 min without the third layer of agarose. After lysis, the slides were washed three times for 5 rain each in enzyme buffer (40 mM Hepes-KOH, 0.1 M KCl, 0.5 mM EDTA EDTA: see chelating agents. , 0.2 mg/mL bovine serum albumin fraction V, pH 8.0) and drained. The agarose was then covered with 50 [micro]L of either enzyme buffer or FPG (Trevigen, Gaithersburg, MD, USA, stored at -20 [degrees] C before use) in buffer (0.5 U/[micro]L), sealed with a coverslip, and incubated at 37 [degrees] C for 30 min. A third layer of agarose was applied as before, with 37 [degrees] C-warmed 0.75% low melting-point agarose after a swift wash with PBS. The next steps (alkaline unwinding, electrophoresis, neutralization, and staining) were as described above. Observation and DNA migration analysis. We made observations at a magnification of 200x under a fluorescence microscope (Olympus BX50, Tokyo, Japan) connected with an HCC-600 color camera system and SCG SCG Serbia and Montenegro SCG Srbija I Crna Gora (Servian: Serbia and Montenegro) SCG Sydney Cricket Ground SCG Service Canadien des Glaces (Canadian Ice Service) SCG superior cervical ganglion image analysis software (DHS-SCG, version 1.0, 1998, KEIO Electronic Ind., Co., Ltd., Ibaraki, Japan). We measured 100 cellular nuclei at random for tail moment, a parameter of the percentage of DNA in the tail (tail length x tail intensity). To show the number of As-induced DNA SSBs, we subtracted the tail moment for background damage (control without FPG digestion). To show the number of FPG-created SSBs at sensitive sites or arsenic-induced base damage converted into SSBs by FPG, we subtracted the tail moment for As-induced SSBs from the tail moment for As-induced SSBs plus enzyme-sensitive sites. The background damage (control with FPG digestion) was also subtracted. Statistics. The results were from three independent experiments. Each experiment was performed in duplicate. The SCGE data were transferred into Microsoft Excel (Japanese Windows 98 version; Microsoft Corporation, Tokyo, Japan) and pooled from the repeated experiments. Tukey multiple analysis of variance comparisons were done with SPSS A statistical package from SPSS, Inc., Chicago (www.spss.com) that runs on PCs, most mainframes and minis and is used extensively in marketing research. It provides over 50 statistical processes, including regression analysis, correlation and analysis of variance. (Japanese Windows version 7.5). The results are expressed as means [+ or -] SD. Results The tail moment for As-induced SSBs and FPG-created SSBs in PHA-stimulated and unstimulated lymphocytes are shown in Figure 1. It is clearly seen from Figure 1 that FPG created a significant number of SSBs at sensitive sites at each sampling interval of repair incubation in both PHA-stimulated and unstimulated lymphocytes compared with the background levels (p [is less than] 0.001). [GRAPH OMITTED] As-induced SSBs in PHA-stimulated lymphocytes at the repair incubation time of 1 and 2 hr were significantly lower compared with the incubation time of zero (p [is less than] 0.001). The damage induced in unstimulated cells showed no difference between hourly sampling intervals (p [is greater than] 0.05). Similarly, FPG-created SSBs did not show significant reduction in unstimulated lymphocytes over the 2-hr repair incubation, but significantly decreased at the end of 2-hr incubation in PHA-stimulated cells (p [is less than] 0.01). To demonstrate further evidence, we show the curves of SSBs and base damage caused by [H.sub.2][O.sub.2] in PHA-stimulated and unstimulated lymphocytes in Figure 2. The kinetics shown were similar to the curves from the cells treated with arsenic shown in Figure 1. FPG-created SSBs for [H.sub.2][O.sub.2]-induced base damage were significant at each sampling interval of repair incubation (p [is less than] 0.001). The tail moment for both SSBs and base damage in PHA-stimulated lymphocytes descended more significantly than those in unstimulated cells (10 [is less than] 0.001 compared at the incubation time of zero). [GRAPH OMITTED] Both SSBs and base damage induced by the two agents in PHA-stimulated and unstimulated lymphocytes did not recover to the background levels at the end of 2-hr repair incubation, indicating that both SSBs and base damage were not completely repaired over 2-hr incubation. Statistical analyses of the FPG-created SSBs induced by the two agents also showed significant differences between PHA-stimulated and unstimulated cells at sampling interval of zero (p [is less than] 0.001). To show clearly the different cellular repair capacities of both SSBs and base damage induced by the two agents in PHA-stimulated and unstimulated lymphocytes, we calculated the percent repair using the equation 100 [([D.sub.0] - [D.sub.t])/[D.sub.0]], after background damage was subtracted. Do is defined as DNA damage at the incubation time of zero, and Dr as that at the sampling interval of 1- or 2-hr incubation. The results are plotted in Figure 3. [GRAPH OMITTED] Figure 3 clearly shows that the repair capacities of both SSBs and base damage induced by the two agents are also comparable in stimulated and unstimulated lymphocytes. In PHA-stimulated lymphocytes, 63.3% and 68.3% of the SSBs induced by As and [H.sub.2][O.sub.2], respectively, were repaired by 2-hr incubation, but about 34.2% and 43.6%, respectively, were repaired in unstimulated cells. In PHA-stimulated lymphocytes, 40.6% and 49.4% of base damage induced by both agents were repaired by 2-hr incubation, and 19% and 20.8% were repaired in unstimulated cells. Discussion Application of FPG protein significantly increased the arsenic-induced tail moment in the present study. The enzyme-sensitive sites were easily detected with the alkaline comet assay after the cells were treated with 10 [micro]M arsenic for 2 hr. In addition, the repair patterns derived from FPG-created SSBs for arsenic were comparable to those for [H.sub.2][O.sub.2]. It is known that FPG specifically recognizes and excises the oxidative bases (17). Thus, our results indicate that arsenic induces oxidative DNA damage in human cells. The most common primary oxidative base lesion is a ring-saturated base derivative (11). The key purine lesion is 8-hydroxyguanine (8-OHgua) or 8-oxoG. The 8-OHgua lesion has attracted special attention because it is a premutagenic lesion and forms an 8-oxoG: A mispair during DNA replication, which induces G: C to T: A transversions because of its mispairing properties in bacterial and mammalian cells. The induction of mutations is one of the critical events in carcinogenic carcinogenic having a capacity for carcinogenesis. transformation, and it has been suggested that ROS-induced 8-OHgua is directly involved in the process of carcinogenesis. FPG is a distinct repair enzyme for formamidopyrimidine and 8-oxoG (18). In the present study, we showed that FPG digestion significantly enhanced arsenic-induced DNA tail moment, suggesting that arsenic induced modifications of purines and formamidopyrimidines, and that possibly 8-oxoG was incurred. Generally, SSBs are repaired rapidly in normal human cells with a half-time of a few minutes. DSB DSB Dispute Settlement Body (World Trade Organization) DSB Double Strand Break DSB Defense Science Board (US DoD) DSB Deep Sand Bed DSB Deutscher Sportbund rejoining is relatively slow, with a half-time of more than 1 hr (19). Repair of oxidized oxidized having been modified by the process of oxidation. oxidized cellulose see absorbable cellulose. DNA base is generally slow, with a half-time of more than 90 min (20). Therefore, theoretically, after strand breaks are rejoined, base damage would become evident. We have shown that as arsenic-induced tail moment decreased with repair incubation, enzyme-created SSBs at enzyme-sensitive sites were more obviously revealed, persisting over 2-hr incubation, providing further evidence indicating that arsenic induced base damage. We have confirmed that arsenic induces oxidative DNA damage in human lymphocytes. However, the exact mechanisms by which arsenic causes oxidative DNA damage are still not clear. Studies indicate that arsenic might inhibit the activities of CAT and glutathione peroxidase, leading to accumulation of [H.sub.2][O.sub.2] (21,22). As may stimulate SOD to produce [O.sub.2-] and increase the activity of heme oxygenase to release reactive ions (22). It was reported that arsenic could stimulate cell signaling and activate transcription factors to enhance production of [H.sub.2][O.sub.2] and [O.sub.2-] (23). Other recent studies have suggested that arsenite activates NADH NADH the reduced form of NAD. NADH n. The reduced form of NAD. NADH, n.pr a coenzyme that incorporates niacin and involved in the Krebs cycle. oxidase oxidase /ox·i·dase/ (ok´si-das) any enzyme of the class of oxidoreductases in which molecular oxygen is the hydrogen acceptor. ox·i·dase n. to produce [O.sub.2-], which then causes oxidative DNA damage (13,24). These studies suggest that arsenic may trigger oxidative stress through multiple pathways, but [H.sub.2][O.sub.2] and [O.sub.2-] are the main ROS involved in arsenic-induced DNA damage, as shown in our previous study (5). ROS not only cause oxidative DNA damage but also influence DNA repair (25). Oxidative DNA damage is one of the main mechanisms of carcinogenesis (26,22). It is postulated that oxidative DNA damage is one of the mechanisms by which arsenic causes multiple cancers in humans. We have shown that enzyme-created SSBs are more evidently revealed by FPG digestion in PHA-stimulated lymphocytes, indicating that stimulated proliferating cells are more susceptible to arsenic-induced DNA damage. We observed a similar response to [H.sub.2][O.sub.2]-induced base damage. Different amount or activities of DNA repair enzymes in proliferating and nonproliferating cells (28) could be the explanation for the diversity in DNA repair capacities between stimulated and unstimulated tymphocytes observed in the present study. REFERENCES AND NOTES (1.) Norderson I, Beckman L. Is the genotoxic genotoxic /ge·no·tox·ic/ (je´no-tok?sik) damaging to DNA: pertaining to agents known to damage DNA, thereby causing mutations, which can result in cancer. ge·no·tox·ic adj. effect of arsenic mediated by oxygen free radicals? Hum Hered 41:71-73 (1991). (2.) Hei TK, Liu SX, Waldren C. Mutagenicity of arsenic in mammalian cells: role of reactive oxygen species. Proc Natl Acad Sci USA 95:8103-8107 (1998). (3.) 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Review of repair kinetics for DNA damage induced in eukaryotic cells in vitro by ionizing radiation. Radiother Oncol 14:307-320 (1989). (20.) Banath JP, Wallace SS, Thompson J, Olive PL. Radiation-induced DNA base damage detected in individual aerobic and hypoxic hypoxic a state of hypoxia. hypoxic cell sensitizers compounds that selectively sensitize hypoxic tumor cells to the effects of radiation. cells with endonuclease III and formamidopyrimidine-glycosylase. Radiat Res 151:550-558 (1999). (21). Jing Y, Dai J, Chalmers Redman RM, Tatton WG, Waxman S. Arsenic trioxide selectively induces acute promyelocytic leukemia cell apoptosis via a hydrogen peroxide-dependent pathway. Blood 94:2102-2113 (1999). (22.) Lee TC, Ho IC. Modulation of cellular antioxidant antioxidant, substance that prevents or slows the breakdown of another substance by oxygen. Synthetic and natural antioxidants are used to slow the deterioration of gasoline and rubber, and such antioxidants as vitamin C (ascorbic acid), butylated hydroxytoluene defense activities by sodium arsenite in human fibroblast fibroblast /fi·bro·blast/ (fi´bro-blast) 1. an immature fiber-producing cell of connective tissue capable of differentiating into chondroblast, collagenoblast, or osteoblast. 2. . Arch Toxicol 69:498-514 (1995). (23). Barchowsky A, Kiel LR, Dudek E J, Swarts HM, James PE. Stimulation of reactive oxygen, but not reactive nitrogen species, in vascular endothelial cells exposed to low levels of arsenite. Free Radic Biol Med 27:1405-1417 (1999). (24.)Chen YC, Lin-Shiau SY, Lin JK. Involvement of reactive oxygen species and caspase 3 activation in arsenite-induced apoptosis. J Cell Physiol 177:324-333 (1998). (25.) Hu JJ, Dubin N, Kurland D, Ma BL, Roush GC. The effects of hydrogen peroxide on DNA repair activities. Mutat Res 336:193-200 (1995). (26.) Vallyathan V, Shi X, Castranova V. Reactive oxygen species: their relation to pneumoconiosis pneumoconiosis (n  'məkō'nēō`sĭs), chronic disease of the lungs. and carcinogenesis. Environ Health Perspect 106(suppl 5):1151-1154 (1998). (27.) Toyokuni S. Reactive oxygen species-induced molecular damage and its application in pathology. Pathol Int 49:91-93 (1999). (28.) Kaminskas E, Li JC. Repair of DNA damage induced by oxygen radicals in human non-proliferating and proliferating lymphocytes. Mutat Res 274:101-107 (1992). Dasheng Li, Kanehisa Morimoto, Tatsuya Takeshita, and Yuquan Lu Department of Preventive Medicine, Osaka University Graduate School of Medicine, Osaka, Japan Address correspondence to K. Morimoto, Department of Social and Environmental Medicine, Osaka University Graduate School of Medicine F1, 2-2 Yamada-oka, Suita, Osaka 565-6879, Japan. Telephone: +81 (06) 6879-3920. Fax: +81 (06) 68793929. E-mail: morimoto@envi.med.osaka-u.ac.jp D. Li is a visiting researcher from the Health and Antiepidemic Station of Guizhou Province, 40# Ba Ge Yan Road, Guiyang 550004, China. This study was supported in part from China Scholarship Council (CSC), no. 98952010. Received 13 October 2000; accepted 6 December 2000. |
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