Generation of reactive oxygen species in the enzymatic reduction of PbCrO4 and related DNA damage

Free radical reactions are believed to play an important role in the mechanism of Cr(VI)-induced carcinogenesis. Most studies concerning the role of free radical reactions have been limited to soluble Cr(VI). Various studies have shown that solubility is an important factor contributing to the carcinogenic potential of Cr(VI) compounds. Here, we report that reduction of insoluble PbCrO4 by glutathione reductase in the presence of NADPH as a cofactor generated hydroxyl radicals (.OH) and caused DNA damage. The .OH radicals were detected by electron spin resonance (ESR) using 5,5-dimethyl-N-oxide as a spin trap. Addition of catalase, a specific H2O2 scavenger, inhibited the .OH radical generation, indicating the involvement of H2O2 in the mechanism of Cr(VI)-induced .OH generation. Catalase reduced .OH radicals measured by electron spin resonance and reduced DNA strand breaks, indicating .OH radicals are involved in the damage measured. The H2O2 formation was measured by change in fluorescence of scopoletin in the presence of horseradish peroxidase. Molecular oxygen was used in the system as measured by oxygen consumption assay. Chelation of PbCrO4 impaired the generation of .OH radical. The results obtained from this study show that reduction of insoluble PbCrO4 by glutathione reductase/NADPH generates .OH radicals. The mechanism of .OH generation involves reduction of molecular oxygen to H2O2, which generates .OH radicals through a Fenton-like reaction. The .OH radicals generated by PbCrO4 caused DNA strand breakage.     

Deferoxamine inhibition of Cr(V)-mediated radical generation and deoxyguanine hydroxylation: ESR and HPLC evidence.

Electron spin resonance (ESR) and high-performance liquid chromatography (HPLC) techniques were utilized to investigate the effect of deferoxamine on free radical generation in the reaction of Cr(V) with H2O2 and organic hydroperoxides. ESR measurements demonstrated that deferoxamine can efficiently reduce the concentration of the Cr(V) intermediate as formed in the reduction of Cr(VI) by NAD(P)H or a flavoenzyme glutathione reductase/NADH. ESR spin trapping studies showed that deferoxamine also inhibits Cr(V)-mediated .OH radical generation from H2O2, as well as Cr(V)-mediated alkyl and alkoxy radical formation from t-butyl hydroperoxide and cumene hydroperoxide. HPLC measurements showed that .OH radicals generated by the Cr(VI)/flavoenzyme/NAD(P)H enzymatic system react with 2'-deoxyguanine to form 8-hydroxy-2'-deoxyguanine (8-OHdG), a DNA damage marker. Deferoxamine effectly inhibited the formation of 8-OHdG also.     

On the mechanism of the chromate reduction by glutathione: ESR evidence for the glutathionyl radical and an isolable Cr(V) intermediate

With a view of elucidating the role of glutathione (GSH) in the biochemical pathways of the chromate-exposure related carcinogenesis, we carried out electron spin resonance (ESR) spectroscopic investigations of the chromate-GSH redox reactions. The ESR measurements, employing spin-traps, provide evidence for the involvement of the glutathione (GS) radical, as well as an isolable Cr(V)-glutathione intermediate. These results indicate a new mechanism for the reduction of chromate by GSH in in vitro cellular environment and help understand the (unexpected) increase in Cr(VI)-induced DNA strand breaks at elevated GSH levels.     

Synergistic induction of hydroxyl radical-induced DNA single-strand breaks by chromium(VI) compound and cigarette smoke solution

Chromium(VI) compounds and cigarette smoke are known human carcinogens. We found that K2Cr2O7 and cigarette smoke solution synergistically induced DNA single-strand breaks (0.23+/-0.04 breaks per DNA molecule) in pUC118 plasmid DNA. K2Cr2O7 alone or cigarette smoke solution alone induced much less strand breaks (0.03+/-0.01 or 0.07+/-0.02 breaks per DNA molecule, respectively). The synergistic effect was prevented by catalase and by hydroxyl radical scavengers such as deferoxamine, dimethylsulfoxide, d-mannitol, and Tris, but not by superoxide dismutase. Ascorbic acid enhanced the synergism. Glutathione inhibited strand breakage only at high concentrations. Electron spin resonance (ESR) studies using a hydroxyl radical trap demonstrated that hydroxyl radicals were generated when DNA was incubated with K2Cr2O7 and cigarette smoke solution. Hydroxyl radical adduct decreased dose-dependently when strand breakage was prevented by catalase, deferoxamine, dimethylsulfoxide, d-mannitol or Tris, but not significantly by superoxide dismutase. We also used ESR spectroscopy to study the effects of different concentration of ascorbic acid and glutathione. The results showed that hydroxyl radical, which is proposed as a main carcinogenic mechanism for both chromium(VI) compounds and cigarette smoke solution was mainly responsible for the DNA breaks they induced.     

ESR Spin Trapping Detection of Hydroxyl Radicals in the Reactions of Cr(V) Complexes with Hydrogen Peroxide

Electron spin resonance (ESR) measurments provide direct evidence for the involvement of Cr(V) in the reduction of Cr(VI) by NAD(P)H. Addition of hydrogen peroxide (H₂O₂) to NAD(P)H-Cr(VI) reaction mixtures suppresses the Cr(V) signal and generates hydroxyl (OH) radicals (as detected via spin trapping), suggesting that Cr(V) reacts with H₂O₂ to generate the OH radicals. Reaction between H₂O₂ and a Cr(V)-glutathione complex. and between H₂O₂ and several Cr(V)-cdrboxylato complexes also produces OH radicals. These results suggest that Cr(V) complexes catalyze the generation of OH radicals from H₂O₂, and that OH radicals might play a significant role in the mechanism of Cr(VI) cytotoxicity.     

The role of hydroxyl radical as a messenger in Cr(VI)-induced p53 activation

The present study investigates whether reactive oxygen species (ROS)are involved in p53 activation, and if they are, which species isresponsible for the activation. Our hypothesis is that hydroxyl radical(·OH) functions as a messenger for the activation of this tumorsuppressor protein. Human lung epithelial cells (A549) were used totest this hypothesis. Cr(VI) was employed as the source of ROS due toits ability to generate a whole spectrum of ROS inside the cell. Cr(VI)is able to activate p53 by increasing the protein levels and enhancingboth the DNA binding activity and transactivation ability of theprotein. Increased cellular levels of superoxide radicals(O₂·), hydrogen peroxide(H₂O₂), and ·OH radicals were detected on theaddition of Cr(VI) to the cells. Superoxide dismutase, by enhancing theproduction of H₂O₂ from O₂·radicals, increased p53 activity. Catalase, anH₂O₂ scavenger, eliminated ·OH radicalgeneration and inhibited p53 activation. Sodium formate and aspirin,·OH radical scavengers, also suppressed p53 activation. Deferoxamine,a metal chelator, inhibited p53 activation by chelating Cr(V) to makeit incapable of generating radicals from H₂O₂.NADPH, which accelerated the one-electron reduction of Cr(VI) to Cr(V)and increased ·OH radical generation, dramatically enhanced p53activation. Thus ·OH radical generated from Cr(VI) reduction in A549cells is responsible for Cr(VI)-induced p53 activation.

     

Role of reactive oxygen species and Cr(VI) in Ras-mediated signal transduction

Previous studies have shown that a constitutively active isoform of Ras is able to produce superoxide radical (O2(-)). The present study investigate the mechanisms by which O2(-) radical mediates signals from Ras protein to the nucleus, leading to cellular responses such as apoptosis in Cr(VI)-stimulated cells. Two human prostate tumor cell lines, Ras(+), which overexpresses Ras, and Ras(-), which has a normal Ras level, were utilized. Compared to Ras(-) cells, Ras(+) cells exhibited higher susceptibility to apoptosis induced by Cr(VI). Catalase, sodium formate, and deferoxamine inhibited Cr(VI)-induced apoptosis. Similar differences were observed in both cellular DNA damage and the activation of p53 protein. The differences in Cr(VI)-induced cell responses in Ras(+) and Ras(-) cells were due to differences in the generation of free radicals between these two cells. ESR spin trapping measurements showed that Ras(+) cells generated more hydroxyl radical ((.)OH), O2(-) radical, and Cr(V) than Ras(-) cells following Cr(VI) stimulation. The generation of the reactive oxygen species (ROS) can be abolished by the addition of superoxide dismutase (SOD) or if the experiment were carried out in an argon atmosphere. Catalase inhibited spin adduct signals but was much less potent than SOD. The mechanism of ROS generation in Cr(VI)-stimulated Ras(+) cells involves the reduction of molecular oxygen to O2(-) radical by a flavoenzyme-containing NADPH oxidase complex as shown by oxygen consumption and diphenylene iodonium (DPI) inhibition. Results shown above support the following conclusions: (a) Ras protein mediates O2(-) radical generation through reduction of molecular oxygen by NADPH oxidase in Cr(VI)-stimulated cells. (b) The O2(-) radical and Cr(VI) produce other reactive species, including H2O2, OH radical, and Cr(V) through O2(-) dismutation and Haber-Weiss type of reactions. (c) Among these reactive species, (.)OH radical is responsible for the further transduction of signals from Ras to the nucleus, leading to various cell responses.     

ESR Spin Trapping Detection of Hydroxyl Radicals in the Reactions of Cr(V) Complexes with Hydrogen Peroxide

Electron spin resonance (ESR) measurments provide direct evidence for the involvement of Cr(V) in the reduction of Cr(VI) by NAD(P)H. Addition of hydrogen peroxide (H₂O₂) to NAD(P)H-Cr(VI) reaction mixtures suppresses the Cr(V) signal and generates hydroxyl (OH) radicals (as detected via spin trapping), suggesting that Cr(V) reacts with H₂O₂ to generate the OH radicals. Reaction between H₂O₂ and a Cr(V)-glutathione complex. and between H₂O₂ and several Cr(V)-cdrboxylato complexes also produces OH radicals. These results suggest that Cr(V) complexes catalyze the generation of OH radicals from H₂O₂, and that OH radicals might play a significant role in the mechanism of Cr(VI) cytotoxicity.     

Critical role of chromium (Cr)-DNA interactions in the formation of Cr-induced polymerase arresting lesions

The genotoxicity associated with the metabolic reduction of hexavalent chromium [Cr(VI)] is complex and can impede DNA polymerase-mediated replication in vitro. The exact biochemical nature of Cr-induced polymerase arresting lesions (PALs) is not understood, but is believed to involve the formation of Cr-DNA interstrand cross-links (ICLs). The aim of this investigation was to determine the dependence of direct Cr-DNA interactions on the development of PALs in DNA treated with trivalent Cr [Cr(III)] or with Cr(VI) in the presence of ascorbic acid (Asc), a major intracellular reductant, using an in vitro, acellular system. The formation of Cr-DNA adducts, ICLs, and PALs was maximal at Asc:Cr(VI) molar ratios of 0.5-2, but gradually decreased at higher ratios. EDTA, a Cr(III) chelator, significantly decreased Cr-DNA binding and ICL and PAL formation. Co-treatment of DNA with Cr(VI)/Asc and mannitol, a Cr(V) chelator, selectively inhibited the formation of mono/bifunctional DNA adducts and PALs produced by Cr(VI) reduction, but had no effect on Cr(III)-DNA binding or Cr(III)-induced polymerase arrest. Blocking Cr-DNA phosphate interaction by preincubation of DNA with MgCl(2) abrogated DNA binding and ICL and PAL production. DNA strand breaks and abasic sites may lead to the in vitro arrest of DNA polymerases; however, we failed to detect significant increases in the frequency of these lesions following Cr(VI)/Asc treatment. These data indicate that the bifunctional adduction of Cr to DNA phosphates (ICLs) constitutes a major PAL. Furthermore, the generation of DNA strand breaks and abasic sites by Cr(VI) reduction is insufficient to explain PALs observed in vitro.     

Iron chelators modulate the production of DNA strand breaks and 8-hydroxy-2'-deoxyguanosine.

The interaction of chelators and reducing agents is of particular importance in understanding iron-associated pathology since catalytic iron undergoes cyclic reduction and oxidation in vivo. Therefore, we treated plasmid DNA with free or chelated Fe(III) in the presence of biological reductants, and simultaneously measured the number of single strand breaks (SSBs) and oxidative base modification (8-hydroxy-2'-deoxyguanosine; 8-OHdG) by quantitative gel electrophoresis and HPLC with electrochemical detection, respectively. Production of SSBs and 8-OHdG was linearly correlated suggesting that these two different lesions share a common chemical mechanism. The levels of both lesions were enhanced when Fe(III) was chelated to citrate or nitrilotriacetic acid. Reducing agents showed different potency in inducing DNA damage catalyzed by chelated iron (L-ascorbate > L-cysteine > H2O2). Chelation increased SSB formation by approximately 8-fold and 8-OHdG production by approximately 4-fold. The ratio of SSB/8-OHdG catalyzed by chelated iron, which is twice as high as by unchelated iron, indicates that chelation affects iron-catalyzed oxidative DNA damage in a specific way favoring strand breakage over base modification. Since iron is mostly chelated in biological systems, the production of genomic and mitochondrial DNA damage, particularly strand breaks, in diseases involving iron overload is likely to be higher than previously predicted from studies using unchelated iron.     

Homologous recombination is involved in repair of chromium-induced DNA damage in mammalian cells

Chromium is a potent human carcinogen, probably because of its well-documented genotoxic effects. Chromate (Cr[VI]) causes a wide range of DNA lesions, including DNA crosslinks and strand breaks, presumably due to the direct and indirect effects of DNA oxidation. Homologous recombination repair (HRR) is important for error-free repair of lesions occurring at replication forks. Here, we show that HR deficient cell lines irs1SF and V-C8, deficient in XRCC3 and BRCA2, respectively, are hypersensitive to Cr[VI], implicating this repair pathway in repair of Cr[VI] damage. Furthermore, we find that Cr[VI] causes DNA double-strand breaks and triggers both Rad51 foci formation and induction of HRR. Collectively, these data suggest that HRR is important in repair of Cr[VI]-induced DNA damage. In addition, we find that ERCC1, XRCC1 and DNA-PKcs defective cells are hypersensitive to Cr[VI], indicating that several repair pathways cooperate in repairing Cr[VI]-induced DNA damage.     

Deficient repair of particulate hexavalent chromium-induced DNA double strand breaks leads to neoplastic transformation

Hexavalent chromium (Cr(VI)) is a potent respiratory toxicant and carcinogen. The most carcinogenic forms of Cr(VI) are the particulate salts such as lead chromate, which deposit and persist in the respiratory tract after inhalation. We demonstrate here that particulate chromate induces DNA double strand breaks in human lung cells with 0.1, 0.5, and 1 microg/cm(2) lead chromate inducing 1.5, 2, and 5 relative increases in the percent of DNA in the comet tail, respectively. These lesions are repaired within 24 h and require Mre11 expression for their repair. Particulate chromate also caused Mre11 to co-localize with gamma-H2A.X and ATM. Failure to repair these breaks with Mre11-induced neoplastic transformation including loss of cell contact inhibition and anchorage-independent growth. A 5-day exposure to lead chromate induced loss of cell contact inhibition in a concentration-dependent manner with 0, 0.1, 0.5, and 1 microg/cm(2) lead chromate inducing 1, 78, and 103 foci in 20 dishes, respectively. These data indicate that Mre11 is critical to repairing particulate Cr(VI)-induced double strand breaks and preventing Cr(VI)-induced neoplastic transformation.     

Soluble metals as well as the insoluble particle fraction are involved in cellular DNA damage induced by particulate matter

Exposure to ambient particulate matter has been reported to be associated with increased rates of lung cancer. Previously we showed that total suspended particulate matter (PM) induces oxidative DNA damage in epithelial lung cells. The aim of the present study was to further investigate the mechanism of PM-induced DNA damage, in which soluble iron-mediated hydroxyl radical (.OH) formation is thought to play a crucial role. Using electron spin resonance (ESR) we showed that PM suspensions as well as their particle-free, water-soluble fractions can generate .OH in the presence of hydrogen peroxide (H2O2), an effect which was abrogated by both deferoxamine and catalase. In addition, PM was also found to induce the .OH-specific DNA lesion 8-hydroxydeoxyguanosine (8-OHdG) in the presence of H2O2 as assessed by dot-blot analysis of calf thymus DNA using an 8-OHdG antibody. In human alveolar epithelial cells (A549), both PM suspensions and the particle-free soluble fraction elicited formation of DNA strand breaks (comet-assay). Unlike the acellular DNA assay, in epithelial cells the DNA-damaging capacity of the particle suspensions appeared to be stronger than that of their corresponding particle-free filtrates. In conclusion, our findings demonstrate that the water-soluble fraction of PM elicits DNA damage via transition metal-dependent .OH formation, implicating an important role of H2O2. Moreover, our data indicate that direct 'particle' effects contribute to the genotoxic hazard of ambient particulate matter in lung target cells.     

The role of superoxide radical in chromium (VI)-generated hydroxyl radical: the Cr(VI) Haber-Weiss cycle.

To understand the role of the superoxide (O-2) radical in chromate-related genotoxicity, we investigated whether Cr(VI) can catalyze the Haber-Weiss cycle in vitro: O-2 + Cr(VI)----Cr(V) + O2 Cr(V) + H2O2----Cr(VI) + .OH + OH-. ESR and spin trapping techniques were utilized to monitor the O-2 (produced using xanthine/xanthine oxidase), .OH, and Cr(V) species. Superoxide dismutase as well as catalase inhibited the .OH radical radical formation, attesting to the direct involvement of O-2 and H2O2 in the process. ESR measurements also provided direct evidence for the formation of Cr(V). Kinetic measurements were consistent with the role of Cr(V) and H2O2 as intermediates in .OH formation. These results indicate that in cellular media, especially during chromate phagocytosis, the O-2 radical can become a significant source of .OH radicals and hence a significant factor in the biochemical mechanism of cellular damage due to Cr(VI) exposure.     

Metal-induced DNA damage and repair in human diploid fibroblasts and Chinese hamster ovary cells

Cloning efficiency and DNA strand breaks induction were compared in human diploid fibroblasts (HSBP) and chinese hamster ovary (CHO) cells treated with various metal salts. Cadmium (Cd2+), nickel (Ni2+) and chromate (Cr2O7) reduced the cloning efficiency of HSBP cells more than that of CHO cells whereas the reverse was true after treatment with mercury (Hg2+), manganese (Mn2+) and cobalt (Co2+). The effects on cloning efficiency did not consistently correlate with DNA strand breaking activity as all metals except Cr(VI) were more effective at producing DNA strand breaks in CHO cells than in human cells. The differential responses of the two cell types was shown to be only partially due to differences in cellular uptake of metals. DNA breaks induced in human cells by Hg2+ and Cr2O7 were shown most likely to be alkaline labile sites rather than true strand breaks since no damage was detected in a nick translation assay which measures the amount of free 3'-OH terminals. Damage induced by Mn2+ and Co2+, however, appeared to be comprised at least in part by true DNA strand breaks. DNA damage was also induced in HSBP cells following treatment with selenium but only in the presence of reduced glutathione. These studies indicate that DNA damage is not as major a consequence following some metal treatments in human cells as it appears to be in rodent cells. This suggests that rodent models for risk estimation of metal-induced tumorigenesis may not always be appropriate for extrapolation to humans.     

Direct evidence for in vivo hydroxyl radical generation in blood of mice after acute chromium (VI) intake

Although it is assumed from in vitro experiments that the hydroxyl radical (*OH) may be responsible for chromium(VI) toxicity/carcinogenicity, no electron spin resonance (ESR) evidence for the generation of *OH in vivo has been reported. In this study, we have employed an ESR spin-trapping technique with 5,5-dimethylpyrroline-N-oxide (DMPO), a selective *OH trap, to detect *OH in blood. The ESR spectrum of spin adduct observed in the blood of mice given 4.8 mmol Cr(VI)/kg body weight exhibited the 1:2:2:1 intensity pattern of a quartet with a hyperfine coupling constant A(N) = A(H) = 14.81 G and g-value = 2.0067. The concentration of the spin adduct detected in the blood was 7.37 microM. The adduct production was inhibited by the addition of specific *OH scavengers such as sodium benzoate and methional to the blood. The results indicate that the spin adduct is nitroxide produced by the reaction of *OH with DMPO. This is the first report of ESR evidence for the in vivo generation of *OH in mammals by Cr(VI).     

DNA and 2'-deoxyguanosine damage in the horseradish-peroxidase-catalyzed autoxidation of aldehydes: the search for the oxidizing species

The horseradish-peroxidase(HRP)-catalyzed aerobic oxidation of aldehydes, in particular isobutanal, was used for the oxidative damage of DNA. In isolated calf-thymus DNA, the enzymatic oxidation of isobutanal led to 7,8-dihydro-8-oxoguanine (8-oxoGua) in up to 1.3% yield and appreciable single-strand breaks in supercoiled pBR 322 DNA. For the nucleoside dG, significant amounts of the guanidine-releasing products oxazolone and oxoimidazolidine have been detected, but 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-oxodG) was not obtained. Only enolizable aldehydes are effective, molecular oxygen is essential, and radical scavengers inhibit efficiently the oxidation. Comparative experiments with 3,3,4,4-tetramethyl-1,2-dioxetane (TMD) revealed that triplet-excited acetone does not play a significant role in this enzymatic DNA oxidation. 2-Hydroperoxy-2-methylpropanal, an intermediate in the HRP-catalyzed aerobic oxidation of isobutanal, does not contribute directly in the observed dG conversion. However, the peroxyl radical derived from the 2-hydroperoxy-2-methylpropanal appears to be active as oxidant because model studies with a structurally related peroxyl radical, produced by HRP-catalyzed one-electron oxidation of 3-hydroperoxy-3-methyl-2-butanone, causes both dG conversion and DNA strand breaks, but to a moderate extent. The active oxidant, as established by control experiments, is the peroxyisobutyric acid, that is efficiently formed through the HRP-catalyzed autoxidation of isobutanal. Still more effective is the acylperoxyl radical, conveniently generated from the peracid by one-electron oxidation by HRP.