Induction of DNA strand breakage and base oxidation by nitroxyl anion through hydroxyl radical production.

Nitroxyl anion (NO-), the one-electron reduction product of nitric oxide (NO*), has been reported to be formed under various physiological conditions and to be cytotoxic, although the mechanism responsible for the toxic effects has not been identified. We have studied the effects of NO- generated from Angeli's salt (sodium trioxodinitrate) or Piloty's acid (N-hydoxybenzenesulfonamide) on DNA strand breakage and DNA base oxidation in vitro. Induction of strand breakage was dose- and time-dependent upon incubation of plasmid pBR322 with Angeli's salt or Piloty's acid. Similarly, 8-oxo-2'-deoxyguanosine and malondialdehyde were formed when calf-thymus DNA or 2'-deoxyribose, respectively, were incubated with Angeli's salt. Electron acceptors (ferricyanide, 4-hydroxy-TEMPO), that convert NO to NO*, inhibited the reactions, indicating that NO , but not NO*, is responsible for the reactions. Furthermore, the reactions were also inhibited by the presence of hydroxyl radical (HO*) scavengers, antioxidants, metal chelators and superoxide dismutase and catalase, implying involvement of free HO*. These results suggest that NO- is a possible endogenous source of HO*, that may be formed either directly from the reaction product of NO- with NO* (N2O2*-) or indirectly through H2O2 formation. Thus NO may play an important role as a cause of diverse pathophysiological conditions such as inflammation and neurodegenerative diseases.     

DNA strand breakage by hydroxyphenyl radicals generated from mutagenic diazoquinone compounds.

The mutagenic diazoquinone compounds p-diazoquinone (p-DQ), o-diazoquinone (o-DQ) and 3-diazo-N-nitrosobamethan (D-BM) cleaved the phosphodiester bond of lambda DNA, phi X174 RFI DNA and M13mp8ss DNA. p-DQ also cleaved the phosphodiester bond of bis(p-nitrophenyl)phosphate. The breakage of the phosphodiester bond was inhibited by the antioxidant butyl hydroxyanisole (BHA), ethanol, the spin trapping agent DMPO, cysteine and 2-mercaptoethanol. While incubation of p-DQ and o-DQ alone gave p-hydroquinone and catechol, respectively, incubation of these compounds in the presence of BHA and ethanol gave phenol in large yields. Incubation of p-DQ and o-DQ with the spin trapping agents DMPO and PBN gave spin adducts assignable as p- and o-hydroxyphenyl adducts, respectively. The breakage of the phosphodiester bond of DNA by the diazoquinone compounds is suggested to be due to the hydroxyphenyl radicals generated during incubation.     

Increased DNA chain breakage by combined action of bleomycin and superoxide radical.

$\text{In vitro}$ DNA chain breakage by bleomycin was enhanced by the addition of xanthine oxidase system. The effect of the xanthine oxidase system disappeared completely when superoxide dismutase was added, but not when catalase was added. From these results it is concluded that superoxide radical is one of the chemical mediators responsible for the enhancement of the DNA chain breakage action of bleomycin.     

Detection of 2-deoxy-D-ribose radicals generated by the reaction with the hydroxyl radical using a rapid flow-ESR method

ESR spectrum of the short-lived radicals derived from 2-deoxy-D-ribose by the reaction with the hydroxyl radical (HO*) was measured using a rapid flow method. A dielectric mixing resonator was used for the measurement, which made it possible to measure the highly sensitive ESR spectra of the radicals with a lifetime of the order of milliseconds. A complex spectrum was obtained and the spectral simulation was done to show that it was the superposition of the signals due to five radicals (I-V). Three of them were those formed by the dehydrogenation with the HO* at C-1 (I), C-3 (II), and C-4 (III) positions of the 2-deoxy-D-ribose molecule. The other two (IV and V) were carbonyl-conjugated radicals formed by the elimination of a water molecule from III and II. The results showed that dehydrogenation occurred randomly at the positions where hydroxyl groups are attached, but the most preferred position was C-3 and the radical position moved from C-3 to C-4 by the elimination of water molecule.     

Clear evidence for the participation of OH in lambda DNA breakage induced by the enzymatic reduction of adriamycin in the presence of iron-ADP. Importance of local OH concentration for DNA strand cleavage

lambda DNA (a double-stranded DNA) was exposed to several adriamycin-mediated active oxygen generating systems (O2- and H2O2 generating, OH generating, and perferryl ion complex generating), extracted, and analyzed by gel electrophoresis on agarose gel. Only the DNA exposed to and subsequently isolated from the adriamycin-mediated OH generating system contained many DNA fragments of low molecular weight, indicating the breakage of DNA strands. Such a breakage was strikingly inhibited by catalase or 50 mM sodium benzoate, but not by superoxide dismutase. The local OH concentration near the DNA strand was considered to be important for DNA strand cleavage.     

Strand breakage in DNA by silicic acid

The alkaline unwinding assay has been used to demonstrate the formation of single-strand breaks in DNA on treatment with silicic acid. Double-stranded DNA, containing no single-strand breaks, when incubated with increasing concentrations of silicic acid, showed the formation of an increasing number of strand breaks per molecule. Experiments on reduction of silicic acid-treated DNA with NaBH4 suggested the possibility of creation of apurinic or apyrimidinic sites. The significance of silicic acid interaction with cellular DNA during asbestos exposure is discussed.     

Induction of repairable DNA damage in Escherichia coli and interaction with DNA in vitro by the radical cation of chlorpromazine

Studies were performed to determine the DNA interactions of and the induction of cytotoxic effects by the radical cation (CPZ+.) formed enzymatically from chlorpromazine (CPZ): in the presence of native DNA the lifetime of CPZ+. is markedly increased. The decreased reactivity of CPZ+. in the presence of native DNA and the concomitant increased viscosity of CPZ+.-DNA complexes strongly support the assumption that CPZ+. does form intercalation complexes with DNA. The relative strong bacteriotoxicity of CPZ+. hindered the accurate determination of mutagenesis in various Salmonella indicator strains, but a test for repairable DNA damage in Escherichia coli using various repair-deficient strains indicated that the cytotoxic action of CPZ+. is in part due to DNA alterations which can be excised in wild-type DNA repair-proficient strains. After activation of CPZ with long wavelength UV light, genetic effects are observed in S. typhimurium strain TA98, as well as in the E. coli tester strains. The possible role of CPZ+. in the photosensitization of CPZ is discussed.     

Possible role of hydroxyl radicals in the oxidation of dichloroacetonitrile by Fenton-like reaction

Dichloroacetonitrile (DCAN), is a member of haloacetonitrile group and detected in drinking water supplies as a by-product of chlorination process. The mechanism of DCAN-induced carcinogenesis is believed to be mediated by oxidative bioactivation of DCAN molecules. The present study was designed to investigate if reactive oxygen species (ROS), similar to that generated in biological systems, are capable of oxidative activation of DCAN. A model ROS generation system (Fenton-like reaction; Fe2+ and H2O2) that predominantly produces hydroxyl radical (OH*) was used. DCAN oxidation was monitored by the extent of cyanide (CN-) release. The results indicate that DCAN was markedly oxidized by this system, and the rate of oxidation was dependent on DCAN concentration. Four-fold increase in H2O2 concentration (50-200 mM) resulted in a 35-fold increase in CN- release. The rates of DACN oxidation in presence of various transition metals were in the following order; iron>copper>titanium. DCAN oxidation was enhanced significantly by the addition of vitamin C and sulfhydryl compounds such as glutathione, N-acetyl-L- cysteine, and dithiothreitol (10 mM) to 140, 130, 145 and 136% of control, respectively. Addition of H2O2 scavenger; catalase or iron chelator; desferrioxamine (DFO) resulted in a significant decrease in CN- release 47 and 41% of control, respectively. Addition of various concentrations of the free radical scavengers, DMSO, or mannitol, to the incubation mixtures caused a significant decrease in DCAN oxidation, 32 and 50% of control, respectively. Michaelis-Menten kinetic analysis of the rates of this reaction, with or without inhibitors, indicated that ROS mediated oxidation of DCAN was inhibited by catalase (Ki = 0.01 mM)>DFO (0.02 mM) > mannitol (0.09 mM) > DMSO (0.12 mM). In conclusion, our results indicate that DCAN is oxidized by a ROS-mediated mechanism. This mechanism may have an important role in DCAN bioactivation and DCAN-induced genotoxicity at target organs where multiple forms of ROS generating systems are abundant.     

Induction of chromosomal breakage in cultured human leucocytes by luteoskyrin

Summary Luteoskyrin, a Polyhydroxy-Bis-Dihydroanthrachinon isolated from Penicillium islandicum Sopp, is known to have strong cytotoxic effects. In long-term cultures of Ehrilich-Ascites-Tumour cells it causes the formation of very long abnormal chromosomes (Schachtschabel). Experiments with short-term cultures of human leucocytes are reported on which have shown Luteoskyrin to induce chromosomal breaks and interchromosomal bridges.

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Zusammenfassung Das Polyhydroxy-Bis-Dihydroanthrachinon Luteoskyrin, ein Stoffwechselprodukt des Schimmelpilzes Penicillium islandicum Sopp, hat eine starke cytotoxische Wirkung. In Langzeitkulturen von Ehrlich-Ascites-Tumorzellen verursacht es die Bildung von abnormal langen Chromosomen (Schachtschabel). Es wird über Versuche mit Kurzzeitkulturen von menschlichen Leukocyten berichtet, in denen durch Luteoskyrin Chromosomenbrüche und interchromosomale Brücken entstehen.

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Supported by a grant from Deutsche Forschungsgemeinschaft (Ke 128/1).     

DNA breakage by uric acid and Cu(II): Binding of uric acid to DNA and biological activity of the reaction

Uric acid is present in human plasma in relatively high concentrations and is considered to be a natural physiological antioxidant. We have earlier shown that in the presence of Cu(II) and molecular oxygen, uric acid causes strand breakage in DNA. In this article, we show that uric acid fluorescence is quenched by addition of DNA, indicating the formation of uric acid-DNA complex. Uric acid-Cu(II)-mediated DNA strand scission is capable of bacteriophage inactivation and such inactivation is mediated through reduction of Cu(II) to Cu(I) and the generation of oxygen-derived radicals. It is indicated that the DNA breakage is repaired in E. coli and involves the repair of DNA polymerase. © 1996 John Wiley & Sons, Inc.