The in vitro metabolites of 2,4,6-trichlorophenol and their DNA strand breaking properties

The carcinogenic compound 2,4,6-trichlorophenol (2,4,6-TCP) was incubated with rat liver S-9 fraction. Three metabolites were identified: 2,6-dichloro-1,4-hydroquinone (DHQ), and two isomers of hydroxypentachlorodiphenyl ether (OH-Cl5-DPE). The latter are probably products of microsomal .OH radical attack on the trichlorophenol molecule forming phenoxy free radicals. These would undergo dimerizations with other molecules present in solution. The 2,6-dichloro-1,4-semiquinone free radical was identified by ESR spectroscopy. It is formed at physiological conditions in phosphate buffer at pH 7.2 and 7.8, with a more intensive signal at the more alkaline pH. The formation is probably due to the autoxidation of the corresponding hydroquinone. Incubation of a mixture of metabolites with PM2 DNA at pH 7.2 resulted in single strand breaks. Addition of catalase and dimethylsulfoxide (DMSO) inhibited the DNA strand scission. It was concluded that reactive oxygen species (ROS), produced during the formation of the semiquinone radical, were responsible for the observed DNA damage. The significance of the ROS and the semiquinone free radical is discussed in view of the reported tumorgenicity of 2,4,6-TCP in rats and mice.     

The effect of anoxia on anthracycline-induced DNA damage in the RPMI-6410 human lymphoblastoid cell line

The alkaline elution procedure developed by Kohn and co-workers was used with the RPMI-6410 cultured human lymphoblastoid cell line to examine the hypothesis that anthracycline-induced DNA strand scission is mediated by oxygen- or superoxide-derived free radicals. Hypoxia was induced by gassing with nitrogen containing 5% carbon dioxide and less than 4 ppm oxygen. Alkaline elution studies showed hypoxia was induced, as the oxygen enhancement ratios for DNA strand breaks was 2.4 and 2.6 for the 250 R +/- oxygen and the 500 R +/- oxygen (1 R = 2.58 x 10(-4) C/kg) experiments, respectively. The pattern of adriamycin-induced DNA strand breaks and cross-linking was not affected by hypoxia with 1-h adriamycin exposures between 0.05 and 1.0 microgram/ml. Similarly, 1-h exposures of N-trifluoroacetyladriamycin-14-valerate at 3 or 10 micrograms/mL gave essentially identical alkaline elution profiles in the presence or absence of oxygen. These results do not support the hypothesis that oxygen-derived radicals play a primary role in anthracycline-induced DNA strand breakage.     

Free radical formation and DNA strand breakage during metabolism of diaziquone by NAD(P)H quinone-acceptor oxidoreductase (DT-diaphorase) and NADPH cytochrome c reductase.

One-electron reduction of diaziquone (AZQ) by purified rat liver NADPH cytochrome c reductase was associated with formation of AZQ semiquinone, superoxide anions, hydrogen peroxide, and hydroxyl radicals as indicated by ESR spin-trapping studies. Reactive oxygen formation correlated with AZQ-dependent production of single and double PM2 plasmid DNA strand breaks mediated by this system as detected by gel electrophoresis. Direct two-electron reduction of AZQ by purified rat liver NAD(P)H (quinone acceptor) oxidoreductase (QAO) was also associated with formation of AZQ semiquinone, superoxide anions, hydrogen peroxide, and hydroxyl radicals as detected by ESR spin trapping. Furthermore, PM2 plasmid DNA strand breaks were detected in the presence of this system. Plasmid DNA strand breakage was inhibited by dicumarol (49 +/- 5%), catalase (57 +/- 2.3%), SOD (42.2 +/- 3.6%) and ethanol (41.1 +/- 3.9%) showing QAO and reactive oxygen formation was involved in the PM2 plasmid DNA strand breaks observed. These results show that both one- and two-electron enzymatic reduction of AZQ give rise to formation of reactive oxygen species and DNA strand breaks. Autoxidation of the AZQ semiquinone and hydroquinone in the presence of molecular oxygen appears to be responsible for these processes. QAO appears to be involved in the metabolic activation of AZQ to free radical species. The cellular levels and distribution of this enzyme may play an important role in the response of tumor and normal cells to this antitumor agent.     

DNA Single Strand Breaks by Aromatic Nitroso Compounds in the Presence of Thiols

Aromatic nitroso compounds, nitrosobenzene (NB), N, N-dimethyl-4-nitrosoaniline (DMNA) and 3,5-dibromo-4-nitrosobenzene sulfonate (DBNBS), caused DNA single strand breaks in the presence of thiol compounds. The strand breaking was inhibited completely by free radical scavenger ethanol. Electron spin resonance (ESR) studies showed that hydronitroxyl (or sulfur-substituted nitroxyl) radicals were generated in the early stage of the interactions. Formation of these radicals was not inhibited by ethanol, indicating that these radicals did not directly contribute to the strand breaking. The DNA strand breaking was inhibited partially by superoxide dismutase and catalase under the limited conditions, but not by removal of oxygen from or addition of metal chelators to the reaction mixture. By ESR-spin trapping technique using 5,5-dimethyl-1-pyrroline-N-oxide (DMPO), the DMPO-OH spin adduct was detected. Formation of the spin adduct was inhibited by superoxide dismutase and catalase. The hydronitroxyl (or the sulfur-substituted nitroxyl) radicals may reduce oxygen into active oxygen species and also transformed by themselves into other unidentified free radical species to cause the DNA strand breaks.     

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.     

Enhancement of Nitrogen Dioxide-Induced Lipid Peroxidation and Dna Strand Breaking by Cysteine and Glutathione

Nitrogen dioxide less than 100 ppm in air induced lipid peroxidation of liposome composed of l-palmitoyl-2-arachidonylphosphatidylcholine as assessed by thiobarbituric acid reactivity. The nitrogen dioxide-induced lipid peroxidation was enhanced by cysteine, glutathione and bovine serum albumin. While the activity of nitrogen dioxide in air to induce single strand breaks of supercoiled plasmid DNA was low, the breaking was remarkably enhanced by cysteine, glutathione and bovine serum albumin. ESR spin trapping using 5,5-dimethyl-1-pyrroline N-oxide showed that certain strong oxidant(s) were generated by interaction of nitrogen dioxide and cysteine. The spin trapping using 3,5-dibromo-4-nitrosobenzene-sulfonate suggested that sulfur-containing radicals were generated by interaction of nitrogen dioxide and cysteine or glutathione. Hence, certain sulfur-containing radicals generated by the interaction which could effectively induce lipid peroxidation and DNA strand breaks.     

DNA strand scission by enzymatically reduced mitomycin C: evidence for participation of the hydroxyl radical in the DNA damage

Phage DNA, as well as plasmid and mammalian DNA's, were exposed to a superoxide and hydroxyl radical-generating system containing NADPH-cytochrome P-450 reductase and mitomycin C, both with and without added Fe3+-ADP, in phosphate buffer at pH 7.5. The generation of superoxide (O2-.) and hydroxyl (.OH) radicals in the system was demonstrated by using ESR spectrometry with N-tert -butyl-alpha-phenylnitrone (PBN) as a spin trapping agent. Only the lambda DNA isolated after exposure to the O2-./.OH-generating system containing many lower molecular weight DNA fragments indicating DNA strand breaks. This breakage was completely inhibited by a .OH radical scavenger (sodium benzoate) and by catalase, but only slightly by superoxide dismutase. Thyroid and plasmid DNA's were both cleaved when exposed to the O2-./.OH-generating systems. It is suggested that the mechanism of DNA scission by mitomycin C described here closely resembles that induced by the anthracycline drugs.     

DNA damage induced by catecholestrogens in the presence of copper (II): generation of reactive oxygen species and enhancement by NADH

Certain estrogen metabolites are involved in carcinogenesis and the development of resistance to methotrexate (MTX). In this study, we determined whether these well-established biological effects correlate with the relative efficiency of several estrogen metabolites to induce DNA strand breaks in the presence of copper, and investigated the potential enhancing effect of reduced nicotinamide adenine dinucleotide (NADH). DNA strand breaks induced by estradiol metabolites were measured by the conversion of supercoiled phage phiX-174 RF1 DNA to open circular and linear forms. The most active catecholestrogens were the 4-hydroxy derivatives, which produced about 2.5 times more DNA double strand breaks than the 2-hydroxy derivatives, while estradiol and 16alpha-hydroxyestrone were inactive. In addition, our results show that 4-hydroxyestradiol (4-OHE2) at physiological concentrations was capable of exhibiting DNA cleaving activity. The formation of these catecholestrogen-induced DNA strand breaks was associated with the utilization of oxygen and the generation of H2O2, because catalase inhibited the DNA cleaving activity of 4-OHE2. Interestingly, we also observed that NADH enhanced the induction of DNA strands breaks by 4-OHE2/Cu(II), probably by perpetuating the redox cycle between the quinone and the semiquinone forms of the catecholestrogen. In conclusion, this study demonstrated that the relative efficiency of 2-, and 4-hydroxyestrogen in carcinogenesis and for the enhancement of MTX resistance correlates with their relative capability to induce DNA strand breaks. In order to inhibit these estrogen-mediated biological effects, it may be important to develop different strategies to block the production of reactive oxygen species by the catecholestrogen-redox cycle.     

Hydroxyl radical scavenging action of capsaicin

We recently reported that capsaicin (CAP) is capable of scavenging peroxyl radicals derived from 2,2'-azobis(2,4-dimethylvaleronitrile) as measured by electron spin resonance (ESR) spectroscopy. The present study describes the hydroxyl radical (HO*) scavenging ability of CAP as measured by DNA strand scission assay and by an ESR spin trapping technique with 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). The Fenton reaction [Fe(II)+ H(2)O(2) --> Fe(III) + HO* + HO(-)] was used as a source of HO*. The incubation of DNA with a mixture of FeSO(4) and H(2)O(2) caused DNA strand scission. The addition of CAP to the incubation mixture decreased the strand scission in a concentration-dependent manner. To understand the antioxidative mechanism of CAP, we used an ESR spin trapping technique. Kinetic competition studies using different concentrations of DMPO indicated that the decrease of the oxidative DNA damage was mainly due to the scavenging of HO* by CAP, not to the inhibition of the HO* generation system itself. We estimated the second order rate constants in the reaction of CAP and common HO* scavengers with HO* by kinetic competition studies. By comparison with the common HO* scavengers, CAP was found to scavenge HO* more effectively than mannitol, deoxyribose and ethanol, and to be equivalent to DMSO and benzoic acid, demonstrating that CAP is a potent HO* scavenger. The results suggest that CAP may act as an effective HO* scavenger as well as a peroxyl radical scavenger in biological systems.     

Vitamin B2-enhancement of sodium chromate (VI)--Induced DNA single strand breaks: ESR study of the action of vitamin B2

Incubation of Chinese hamster V-79 cells with Na2CrO4 plus vitamin B2 resulted in an increase of Na2CrO4-induced DNA single strand breaks. Electron spin resonance (ESR) studies showed that vitamin B2 enhanced the formation of both hydroxyl radical and tetraperoxochromate (V) during the reaction of Na2CrO4 with hydrogen peroxide. Furthermore, ESR studies demonstrated that a chromium (V) species with a g value of 1.977 was formed by the reaction of Na2CrO4 with vitamin B2. These results indicate that chromate reacts with vitamin B2 to form chromium (V) species and also suggest that the enhancement effect of vitamin B2 on chromate-induced DNA single strand breaks may result from an increase of chromium (V)-related hydroxyl radical formation.     

DNA strand scission by iron complexes of meso-tetra(N-methylpyridyl)porphines

The DNA strand scission activities of three positional isomers of Fe(III) meso-tetra(N-methylpyridyl)porphine (Fe(III)TnMPyP, where n = 2, 3 or 4) have been investigated using PM2 DNA as a substrate. A significant degree of strand scission activity was noted in the presence of oxygen without the addition of a reducing agent. This activity was probably due to the presence of reducing agents in the agarose gels used to separate the DNA forms, as higher levels were recorded with reducing agents added to the strand scission mixture. The relative order of strand scission activity in the absence of added reducing agents was found to be Fe(III)T2MPyP greater than Fe(III)T4MPyP greater than Fe(III)T3MPyP. Comparative studies were also made with Fe(II)bleomycin. High concentrations of some reducing agents inhibited strand scission. Oxygen was required to produce optimal strand scission activity for all three porphyrins. It was also noted from spectroscopic measurements that the reduced porphyrins were degraded in the presence of oxygen. Studies with a series of potential strand scission inhibitors suggest that hydrogen peroxide and possibly peroxy radicals are intermediates in the reaction mechanism, while diffusible hydroxyl radicals appear to be excluded. However, superoxide radicals cannot be ruled out.     

The role of hydroxyl radicals in tetrachlorohydroquinone induced DNA strand break formation in PM2 DNA and human fibroblasts

Tetrachlorohydroquinone (TCHQ), which has previously been identified as a metabolite of pentachlorophenol, induces DNA strand breaks in isolated DNA and in human fibroblasts. Strand break formation in PM2 DNA is prevented by the addition of catalase and the hydroxyl radical scavengers DMSO, ethanol and mannitol, whereas addition of SOD reduced SSB only slightly. Oxygen radicals are formed by the autoxidation of TCHQ to the tetrachlorosemiquinone radical. Desferrioxamine (0.2 mM) completely abolished strand break formation, whereas the metal chelator DETAPAC (1 mM) reduced SSB by only 8.5%. The formation of the semiquinone radical at physiological conditions is shown by ESR spectroscopy. Exposure of human fibroblasts to TCHQ also leads to DNA single strand breaks measured by the alkaline elution assay. These were reduced by addition of 5% DMSO. This indicates that at least part of the strand break formation in human cells is also due to the action of hydroxyl radicals.     

Evidence for the formation of strand-break precursors in hydroxy-attacked thymidine 5'-monophosphate by the spin trapping method

A method combining spin trapping, ESR, and HPLC was employed to obtain evidence for the formation of sugar radicals in OH-attacked TMP with special emphasis on the detection of strand-break precursors of DNA. OH radicals were produced by irradiating an N2O-saturated aqueous solution with X-rays. When an N2O-saturated aqueous solution containing TMP and a spin trapping reagent, MNP, was irradiated with X-rays, it was estimated on the basis of theoretical calculations using rate constants that 94% of the TMP radicals were induced by OH radicals. Since several spin adducts between TMP radicals and MNP, as well as the byproducts of the spin trapping reagent itself, were produced, reverse-phase HPLC was used to separate them. The presence of six spin adducts was confirmed by ESR examination. Further examination of these spin adducts by UV absorbance spectrophotometry showed the presence of a chromophore at 260 nm in three adducts. Since a gradual increase in the release of unaltered base from these adducts was observed when they were allowed to stand for 0-22 h at room temperature, they could be regarded as the spin adducts of sugar radicals and MNP. ESR spectra from the spin adducts were consistent with hydrogen abstraction radicals at the C1', C4', and C5' positions of the sugar moiety. These radicals appeared to be precursors of AP sites and strand breaks. In addition to these spin adducts, ESR spectra that were consistent with the spin adducts of base radicals (the C5 and C6 radicals) and MNP were observed.     

Radical formation during the peroxidase catalyzed metabolism of carcinogens and xenobiotics: the reactivity of these radicals with GSH, DNA, and unsaturated lipid

Radicals generated by the peroxidase catalyzed oxidation of a wide variety of substrates oxidize GSH, NADH, or arachidonate with accompanying oxygen activation. Substrates studied include carcinogens, drugs, or xenobiotics. The effectiveness of the various radicals is partly related to their one-electron oxidation potential. High redox potential radicals were particularly effective at oxidizing these biomolecules. Low redox potential radicals did not react with GSH, NADH, or arachidonate, but can directly activate oxygen to form hydroxyl radicals or undergo scission to carbon radicals. The hydroxyl and carbon radicals have a high redox potential and readily oxidize biomolecules. DNA strand breakage also occurs with some high redox potential radicals, but DNA did not react with low redox potential radicals. The extensive binding of xenobiotics to DNA in the peroxidase system was attributed to noncovalent binding by polymeric products or covalent binding by the two electron oxidation product (formed by radical dismutation or oxidation). The latter can cause alkali labile DNA strand breaks. GSH conjugate formation was also attributed to the two electron oxidation product. Radicals have been trapped in intact cells and oxygen activation or lipid peroxidation has been demonstrated but it is still not clear whether the associated GSH oxidation, DNA strand breakage and cytotoxicity is the result of direct action by radicals. Indirect enzymic mechanisms for free radical mediated DNA strand breakage and cytotoxicity are discussed.     

The DNA cleavage induced by a chromium(V) complex and by chromate and glutathione is mediated by activated oxygen species

The number of strand breaks induced by the combination of chromate and glutathione (GSH) in PM2 DNA was effectively reduced upon addition of the hydroxyl radical scavengers dimethyl sulphoxide (DMSO), formate and benzoate. Administration of catalase also led to a depression of DNA degradation whereas superoxide dismutase (SOD) had very little influence. Essentially the same results were obtained in experiments employing a chromium(V) complex Na4(GSH)4Cr.8H20, which is an intermediate chromium species isolated from the reduction of chromate by glutathione. DNA cleavage was dependent on the presence of iron (FeCl3). When compared with the number of breaks produced by FeCl3 and GSH alone, chromate stimulated the generation of single-strand breaks. These findings suggest that hydroxyl radicals are one ultimate DNA cleaving agent in both reactions. A reaction scheme for the production of hydroxyl radicals is proposed.     

High yield of endoreduplication induced by ICRF-193: a topoisomerase II catalytic inhibitor

Previous studies have demonstrated that phenolic compounds, including genistein (4',5,7-trihydroxyisoflavone) and resveratrol (3,4',5-trihydroxystilbene), are able to protect against carcinogenesis in animal models. This study was undertaken to examine the ability of genistein and resveratrol to inhibit reactive oxygen species (ROS)-mediated strand breaks in phi X-174 plasmid DNA. H(2)O(2)/Cu(II) and hydroquinone/Cu(II) were used to cause oxidative DNA strand breaks in the plasmid DNA. We demonstrated that the presence of genistein at micromolar concentrations resulted in a marked inhibition of DNA strand breaks induced by either H(2)O(2)/Cu(II) or hydroquinone/Cu(II). Genistein neither affected the Cu(II)/Cu(I) redox cycle nor reacted with H(2)O(2) suggest that genistein may directly scavenge the ROS that participate in the induction of DNA strand breaks. In contrast to the inhibitory effects of genistein, the presence of resveratrol at similar concentrations led to increased DNA strand breaks induced by H(2)O(2)/Cu(II). Further studies showed that in the presence of Cu(II), resveratrol, but not genistein was able to cause DNA strand breaks. Moreover, both Cu(II)/Cu(I) redox cycle and H(2)O(2) were shown to be critically involved in resveratrol/copper-mediated DNA strand breaks. The above results indicate that despite their similar in vivo anticarcinogenic effects, genistein and resveratrol appear to exert different effects on oxidative DNA damage in vitro.     

DNA strand scission and ADP-ribosyltransferase activity during murine erythroleukemia cell differentiation

The accumulation of DNA strand breaks and activation of ADP-ribosyltransferase (ADPRT) have recently been associated with cellular differentiation. Murine erythroleukemia (MEL) cells undergo erythropoietic differentiation when exposed to dimethyl sulfoxide (Me2SO) and several studies have suggested that DNA strand scission induced by this agent is a prerequisite for expression of the differentiated phenotype. Me2SO induction of MEL cells has also been associated with increases in ADPRT activity in one study, but not in another. We have monitored the effects of Me2SO on DNA strand breaks in preformed and replicating MEL cell DNA. The results clearly demonstrate that DNA fragmentation is not detectable during Me2SO induction of MEL differentiation, even in the presence of 3-aminobenzamide, an inhibitor of ADPRT. Further, these results are consistent with an absence of detectable changes in both endogenous and total potential ADPRT activity during Me2SO-induced MEL differentiation. These findings would argue against Me2SO induction of DNA strand scission and ADPRT in MEL cells undergoing differentiation.     

Mapping of peroxyl radical induced damage on genomic DNA

We have examined the DNA damage produced by reaction of peroxyl radicals with human fibroblast DNA. DNA damage consisted of both strand breaks and base modifications. The extent of strand breaks and base modifications induced as a function of peroxyl radical concentration was determined by quantitation of fragment size distributions using denaturing glyoxal-agarose gel electrophoresis. Both strand breaks and base modifications increased in a log linear fashion with respect to peroxyl radical concentration. Oxidative base modifications were observed to occur to a greater extent than strand breaks at every concentration measured. The sequence-specific distribution of peroxyl radical induced base damage was mapped for 803 nucleotide positions using the method of ligation mediated PCR. A total of 87% of all guanine positions in the examined sequences was found to be significantly oxidized. The order of reactivity of DNA bases toward oxidation by peroxyl radicals was found to be G > C > T. Adenine is essentially unreactive. The yield of oxidative base modifications at guanines and cytosines by peroxyl radicals depends on the exact specification of 5' and 3' flanking bases in a polarity dependent manner. Every guanine in the 5'XGC3' motif was found to be oxidized, where X is any 5' neighbor. In contrast, 5' and 3' purine flanks drastically reduced the extent of peroxyl radical G oxidation. The pattern of base modification and the influence of nearest neighbors differs substantially from that previously reported for hydrogen peroxide damage mediated by low valent transition metal ions for the identical DNA sequences.     

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.