Hydroxylation Of Deoxyguanosine Research Articles

Rapid Assessment of Oxidative Damage Potential: A Comparative Study of Engineered Stone Dusts Using a Deoxyguanosine Assay.

The popularity of engineered stone (ES) has been associated with a global increase in occupational lung disease in workers exposed to respirable dust during the fabrication of benchtops and other ES products. In this study, the reactivity and subsequent oxidative reduction potential of freshly generated ES dusts were evaluated by (i) comparing different engineered and natural stones, (ii) comparing settled and respirable stone dust fractions and (iii) assessing the effect of ageing on the reactivity of freshly generated stone dust. An established cell-free deoxyguanosine hydroxylation assay was used to assess the potential for oxidative DNA damage. ES dust exhibited a higher relative reactivity than two of the three natural stones tested. Respirable dust fractions were found to be significantly more reactive than their corresponding settled fraction (ANOVA, p < 0.05) across all stone types and samples. However, settled dust still displayed high relative reactivity. The lower reactivity of the settled dust was not due to decay in reactivity of the respirable dust when it settled but rather a result of the admixture of larger nonrespirable particles. No significant change in respirable dust reactivity was observed for three ES samples over a 21-day time period, whereas a significant decrease in reactivity was observed in the natural stone studied. This study has practical implications for dust control and housekeeping in industry, risk assessment and hazard management.

Contrasting Genome-Wide Distribution of 8-Hydroxyguanine and Acrolein-Modified Adenine during Oxidative Stress-Induced Renal Carcinogenesis

Oxidative stress is a persistent threat to the genome and is associated with major causes of human mortality, including cancer, atherosclerosis, and aging. Here we established a method to generate libraries of genomic DNA fragments containing oxidatively modified bases by using specific monoclonal antibodies to immunoprecipitate enzyme-digested genome DNA. We applied this technique to two different base modifications, 8-hydroxyguanine and 1,N6-propanoadenine (acrotein-Ade), in a ferric nitrilotriacetate-induced murine renal carcinogenesis model. Renal cortical genomic DNA derived from 10- to 12-week-old male C57BL/6 mice, of untreated control or 6 hours after intraperitoneal injection of 3 mg iron/kg ferric nitrilotriacetate, was enzyme digested, immunoprecipitated, cloned, and mapped to each chromosome. The results revealed that distribution of the two modified bases was not random but differed in terms of chromosomes, gene size, and expression, which could be partially explained by chromosomal territory. In the wild-type mice, low GC content areas were more likely to harbor the two modified bases. Knockout of OGG1, a repair enzyme for genomic 8-hydroxyguanine, increased the amounts of acrolein-Ade as determined by quantitative polymerase chain reaction analyses. This versatile technique would introduce a novel research area as a high-throughput screening method for critical genomic loci under oxidative stress.

Hydroxylation of Deoxyguanosine at 5′ Site of GG and GGG Sequences in Double-stranded DNA Induced by Carbamoyl Radicals

Free radicals generated by chemicals can cause sequence-specific DNA damage and play important roles in mutagenesis and carcinogenesis. Carbamoyl group (CONH 2 ) and its derived groups (CONR 2 ) occur as natural products and synthetic chemical compounds. We have investigated the DNA damage by carbamoyl radicals · (CONH 2 ), one of carbon-centered radicals. Electron spin resonance (ESR) spectroscopic study has demonstrated that carbamoyl radicals were generated from formamide by treatment with H 2 O 2 plus Cu(II), and from azodicarbonamide by treatment with Cu(II). We have investigated sequence specificity of DNA damage induced by carbamoyl radicals using 32 P-labeled DNA fragments obtained from the human c-Ha- ras -1 and p 53 genes. Treatment of double-stranded DNA with carbamoyl radicals induced an alteration of guanine residues, and subsequent treatment with piperidine or Fpg protein led to chain cleavages at 5'-G of GG and GGG sequences. Carbamoyl radicals enhanced Cu(II)/H 2 O 2 -mediated formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) in double-stranded DNA more efficiently than that in single-stranded DNA. These results shows that carbamoyl radicals specifically induce hydroxylation of deoxyguanosine at 5' site of GG and GGG sequences in double-stranded DNA.

Enhancement of 2'-deoxyguanosine hydroxylation and DNA damage by coal and oil fly ash in relation to particulate metal content and availability.

Epidemiologic studies have shown causal relationships between air pollution particles and adverse health effects in susceptible subpopulations. Fly ash particles (containing water-soluble and insoluble metals) are a component of ambient air particulate pollution and may contribute to particulate-induced health effects. Some of the pathological effects after inhalation of the particles may be due to reactive oxygen species (ROS) produced by metal-catalyzed reactions. In this investigation, we analyzed emission source particulates oil fly ash (OFA) and coal fly ash (CFA) for metal content and solubility in relation to their ability to induce 2'-deoxyguanosine (dG) hydroxylation and DNA damage as measured by 8-oxo-dG formation by HPLC/UV-electrochemical detection (ECD). Water-soluble vanadium and nickel were present at the highest concentrations, and iron was present in trace amounts in OFA (5.1% V, 1.0% Ni, and 0.4% Fe by weight). In contrast, CFA comprised mostly of water-insoluble aluminosilicates and iron (9.2% Al, 12.2% Si, and 2.8% Fe by weight). As a first approach to gain insight into the mode of action of these particulates, we examined metal species-catalyzed kinetics of dG hydroxylation. Metal species at a concentration of 0.1 mM in the incubation mixture containing 0.1 mM dG under ambient air at room temperature catalyzed maximum 8-oxo-dG formation at 15 min with yields ranging from 0.05 to 0.17%, decreasing in the following order: vanadium(IV) > iron(II) > vanadium(V) > iron(III) > or = nickel(II). Insoluble Fe(III) oxide (Fe(2)O(3)) under similar conditions had no effect. Consistent with these results, OFA rich in vanadium and nickel concentrations showed a dose-dependent increase in the level of dG hydroxylation to 8-oxo-dG formation at particulate concentrations of 0.1-1 mg/mL (p < 0.05). In contrast, CFA with high concentrations of aluminosilicates and iron did not result in a significant increase in the level of 8-oxo-dG over that of the control, i.e., dG (p > 0.05). DMSO, a (*)OH scavenger, inhibited OFA-induced 8-oxo-dG formation, and metal ion chelators, deferoxamine (DFX), DTPA, and ferrozine blocked OFA-induced 8-oxo-dG formation. OFA and CFA induced 8-oxo-dG formation in a pattern similar to that observed for dG hydroxylation when calf thymus DNA was used as a substrate. Treatment of OFA particles with DFX before reacting with DNA or addition of a catalase in the incubation mixture significantly suppressed 8-oxo-dG formation (p < 0.05). These results suggest that metal availability, but not the concentration of metals present in CFA and OFA, is critical in mediating molecular oxygen-dependent dG hydroxylation and DNA base damage.

Cr(IV) causes activation of nuclear transcription factor-κB, DNA strand breaks and dG hydroxylation via free radical reactions

Electrophoretic mobility shift, DNA strand breakage assays and electron spin resonance (ESR) spin trapping were used to investigate the activation of nuclear transcription factor (NF)- κB, DNA strand breakage and 2′-deoxyguanosine hydroxylation induced by Cr(IV), as well the role of free radical reactions in these processes. Incubation of synthesized Cr(IV)-glutathione complex with cultured Jurkat cells resulted in activation of DNA binding activity of NF- κB. Cr(VI) is also able to induce NF- κB activation through Cr(V) and Cr(IV) intermediates generated during the reduction of Cr(VI) by the cells. Cr(III) did not cause observable NF- κB activation due to its inability to cross cell membranes. Cr(IV)-induced NF- κB activation is dose-dependent. Catalase inhibited the activation while superoxide dismutase enhanced it. The metal chelator, deferoxamine, and hydroxyl (OH) radical scavengers, sodium formate and aspirin, also inhibited the NF- κB activation. Electrophoretic assays using λ Hind III linear DNA showed that, in the presence of H 2O 2, Cr(IV) is capable of causing DNA strand breaks. Deferoxamine, sodium formate and aspirin inhibited the DNA strand breaks. HPLC measurements also show that OH radical generated by the Cr(IV)-mediated reaction with H 2O 2 was capable of causing 2′-deoxyguanosine (dG) hydroxylation to generate 8-hydroxyguanosine (8-OHdG). The relative magnitude of 8-OHdG formation correlated with the generation of OH radicals. ESR spin trapping measurements showed that reaction of Cr(IV) with H 2O 2 generated OH radicals, which were inhibited by deferoxamine, sodium formate and aspirin. The results show that Cr(IV) can cause NF- κB activation, DNA strand breaks and dG hydroxylation through OH radical-initiated reactions. This reactive chromium intermediate may play an important role in the mechanism of Cr(VI)-induced carcinogenesis. The results also suggest that the Cr(IV)-glutathione complex may be used as a model compound to study the role of Cr(IV) in Cr(VI) carcinogenicity.

Photoinduced hydroxylation of deoxyguanosine in DNA by pterins: sequence specificity and mechanism.

Pterin-sensitized DNA photodamage has been characterized by a DNA sequencing technique. Exposure of double-stranded DNA to 365-nm light in the presence of pterin, 6-carboxypterin, biopterin, neopterin, and folic acid produced sequence-specific DNA lesions, whereas photoinduced DNA lesions were not observed in the presence of xanthopterin or isoxanthopterin. The DNA photodamage induced by these pterin derivatives occurred specifically at the guanine located 5' to guanine. High-pressure liquid chromatography (HPLC) analysis revealed that the pterin-sensitized DNA photodamage was predominantly due to the formation of 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-oxo-dG). The DNA photodamage with pterin was not enhanced in D2O, suggesting that lO2 is not the main active species. Electron spin resonance (ESR) spin destruction experiments demonstrated that the photoexcited pterins reacted specifically with dGMP to produce pterin anion radicals. In addition, the reactivities of the photoexcited pterin derivatives with dGMP were found to correlate well with their efficiencies of DNA photodamage induction. These results indicate that the photoexcited pterins specifically oxidize deoxyguanosine in DNA to produce 8-oxo-dG through an electron transfer reaction. With denatured single-stranded DNA, the extent of pterin-sensitized photodamage was decreased and the damage occurred at most guanine residues without specificity for those located 5' to guanine. The mechanism of pterin-induced sequence-specific guanine photodamage could be explained on the basis of a recent theoretical study [Sugiyama. H., & Saito, I. (1996) J. Am. Chem. Soc. 118, 7063-7068] concerning the ionization potentials of stacked dinucleotide base pairs. Sepiapterin, a model compound for the dihydropterins, induced similar sequence-specific photolesions in double-stranded DNA. However, DNA photodamage by sepiapterin was more extensive in the presence of Cu(II), and the sites of the photolesions were different from those induced in the absence of Cu(II). These data may provide a basis for the elucidation of the molecular mechanism of solar UV carcinogenesis.

A sensitive method to screen for hydroxyl radical scavenging activity in natural food extracts using competitive inhibition ELISA for 8-hydroxy deoxyguanosine

Representative endogenous antioxidants and natural food extracts were screened for hydroxyl radical scavenging activity by an ELISA. Whereas conventional assays for hydroxyl radical scavenging activity use either spin traps following the induction of Fenton reaction or measure thiobarbituric acid-reactive substances, this assay measures 8-hydroxy deoxyguanosine liberated from the hydroxylation of deoxyguanosine by Cu2+/ascorbate system.

Vanadium(IV)-mediated free radical generation and related 2′-deoxyguanosine hydroxylation and DNA damage

Free radical generation, 2′-deoxyguanosine (dG) hydroxylation and DNA damage by vanadium(IV) reactions were investigated. Vanadium(IV) caused molecular oxygen dependent dG hydroxylation to form 8-hydroxyl-2′-deoxyguanosine (8-OHdG). During a 15 min incubation of 1.0 mM dG and 1.0 mM VOSO 4 in phosphate buffer solution (pH 7.4) at room temperature under ambient air, dG was converted to 8-OHdG with a yield of about 0.31%. Catalase and formate inhibited the 8-OHdG formation while Superoxide dismutase enhanced it. Metal ion chelators, DTPA and deferoxamine, blocked the 8-OHdG formation. Incubation of vanadium(IV) with dG in argon did not generate any significant amount of 8-OHdG, indicating the role of molecular oxygen in the mechanism of vanadium(IV)-induced dG hydroxylation. Vanadium(IV) also caused molecular oxygen-dependent DNA strand breaks in a pattern similar to that observed for dG hydroxylation. ESR spin trapping measurements demonstrated that the reaction of vanadium(IV) with H 2O 2 generated OH radicals, which were inhibited by DTPA and deferoxamine. Incubation of vanadium(IV) with dG or with DNA in the presence of H 2O 2 resulted in an enhanced 8-OHdG formation and substantial DNA double strand breaks. Sodium formate inhibited 8-OHdG formation while DTPA had no significant effect. Deferoxamine enhanced the 8-OHdG generation by 2.5-fold. ESR and UV measurements provided evidence for the complex formation between vanadium(IV) and deferoxamine. UV-visible measurements indicate that dG, vanadium(IV) and deferoxamine are able to form a complex, thereby, facilitating site-specific 8-OHdG formation. Reaction of vanadium(IV) with t-butyl hydroperoxide generated hydroperoxide-derived free radicals, which caused 8-OHdG formation from dG and DNA strand breaks. DTPA and deferoxamine attenuated vanadium(IV)/r-butyl-OOH-induced DNA strand breaks.

Iron bound to the lipophilic iron chelator, 8-hydroxyquinoline, causes DNA strand breakage in cultured lung cells.

The formation of DNA-strand breaks was studied in cultured human lung cells (A 549) subjected to iron, either in the form of iron(III) citrate or in combination with the metal chelators ethylene diamine tetra-acetic acid (EDTA), nitrilo triacetic acid (NTA), or 8-hydroxyquinoline (8HQ). After 15 min exposure to 5 microM iron(III) citrate or iron chelate, the cellular levels of iron were found to be three times higher in cells subjected to iron-8HQ than in cells subjected to iron(III) citrate, iron-EDTA or iron-NTA. Exposure to iron-8HQ caused extensive DNA-strand breakage, whereas no such breakage was found in cells exposed to iron-EDTA or iron-NTA. The DNA damage caused by iron-8HQ increased with time and dose, and DNA-strand breakage was clearly demonstrable in cells after 15 min exposure to as little as 0.1 microM iron-8HQ. Moreover, iron-8HQ was strongly toxic to the cells and inhibited their growth after exposure. Along with the formation of DNA-strand breaks, the concentration of cellular malondialdehyde increased four-fold after exposure to iron-8HQ and two-fold after exposure to iron-EDTA or iron-NTA, suggesting that reactive oxygen metabolites might be involved in the toxic action. Moreover, both iron-EDTA and iron-NTA caused a considerable hydroxylation of deoxyguanosine (dG) residues in DNA in vitro, whereas iron(III) citrate and iron-8HQ only caused a minor hydroxylation of dG. This points to the possibility that iron-8HQ-mediated DNA-strand breakage in cells might be due to the action of a metal-bound oxyl radical formed from the iron-8HQ complex rather than to the formation of hydroxyl radicals. Altogether, these findings indicate that iron bound to the lipophilic chelator, 8HQ, has strong toxic properties and that it may cause substantial DNA-strand breakage and lipid peroxidation in living cells.

GENERATION OF REACTIVE OXYGEN SPECIES BY Co(II) FROM H2O2 IN THE PRESENCE OF CHELATORS IN RELATION TO DNA DAMAGE AND 2'-DEOXYGUANOSINE HYDROXYLATION

The generation of reactive oxygen species by Co(II) from H2O2 in the presence of chelators and related DNA damage was investigated by electron spin resonance (ESR), electrophoretic assays, and high-performance liquid chromatography (HPLC). Incubation of Co(II) with beta-alanyl-3-methyl-L-histidine (anserine) and H2O2 generated .OH radicals. Omission of any one component sharply reduced the amount of .OH radicals generated, indicating that anserine modulated the oxidation potential of Co(II) to enhance its capability to generate .OH radicals from H2O2. Formate only moderately decreased the .OH radical generation, while ethanol had no observable effect, indicating that the generation of .OH radical is site specific. The metal ion chelator 1,10-phenanthroline reduced the .OH radical generation, and deferoxamine suppressed it with the formation of deferoxamine nitroxide radical. Electrophoretic assays using both lambda Hind III linear DNA and PM2 supercoiled DNA showed that .OH radicals generated from a mixture of Co(II), H2O2, and anserine caused DNA strand breaks. A mixture of Co(II), H2O2, and 1,10-phenanthroline also caused DNA strand breaks, which were inhibited by sodium azide, indicating that 1O2 was involved in DNA damage. HPLC measurements showed that .OH radicals and 1O2 generated by Co(II) reactions caused 2'-deoxyguanosine hydroxylation to form 8-hydroxy-2'-deoxyguanosine. ESR spin trapping measurements provided evidence for 1O2 generation by Co(II) from H2O2 in the presence of 1,10-phenanthroline. The results indicate that the oxidation potential of Co(II) can be modulated by chelators to facilitate its generation of reactive oxygen species from H2O2. These species may be involved in Co(II)-induced cellular damage.

Hydroxylation of Deoxyguanosine in DNA by Copper and Thiols

DNA was incubated with glutathione (GSH) and copper and then assayed for 8-hydroxydeoxyguanosine (8-OHdG) in order to better understand the antioxidant and prooxidant characteristics of GSH in copper-dependent DNA damage. Ratios of GSH to Cu(II) less than 3 resulted in 8-OHdG production; however, higher ratios did not generate 8-OHdG. A combination of GSH and Cu(I) (10:1) was used to determine if DNA oxidation occurred upon the addition of H 2O 2. No increase in 8-OHdG was noted until the concentration of H 2O 2 was almost half that of GSH, and then a substantial increase of 8-OHdG was detected. The stoichiometry of thiol oxidation by H 2O 2 was 2 mol GSH oxidized per 1 mol H 2O 2. Oxidation of Cu(I) was not detected until most of the thiol had been oxidized. When cysteine and Cu(I) was used instead of GSH and Cu(I), there was considerable hydroxylation of deoxyguanosine. The glycyl carboxyl, the γ-glutamate carboxyl, and the amine of GSH were altered to determine their role in the peptide′s ability to inhibit Cu-dependent damage. In the presence of Cu(I), H 2O 2, and DNA, these GSH analogs behaved similarly to GSH. However, when S-methylglutathione was used in this system, it was very effective at promoting oxidative damage to DNA. This indicated that the thiol ligand of GSH was essential for inhibition of Cu-dependent damage, while the carboxyl groups and the amine were not essential ligands. In conclusion, GSH can catalyze the in vitro hydroxylation of deoxyguanosine when the ratio of GSH to Cu is low, however, when the ratio is high GSH is an effective antioxidant.

Hydroxylation of Deoxyguanosine at the C-8 Position in the Thiosulfate-Hydrogen Peroxide Reaction System. Evidence of Hydroxyl Radical Generation in the System

Abstract The thiosulfate-hydrogen peroxide reaction system generates thiosulfate radical anion and hydroxyl radical. When 2′-deoxyguanosine (dG) was included in the system, it was hydroxylated at the C-8 position, and the hydroxylation was markedly enhanced by addition of a trace amount of iron ion.

Rapid and sensitive detection of hydroxyl radicals formed by activated neutrophils in the presence of chelated iron: hydroxylation of deoxyguanosine to 8-hydroxydeoxyguanosine.

Hydroxyl radicals (OH) can react with deoxyguanosine (dG) leading to the formation of 8-hydroxydeoxyguanosine (8OHdG). In this study, this has been used to detect the hydroxyl radicals formed when human polymorphonuclear leukocytes (PMNL) are stimulated with phorbol myristate acetate (PMA) in the presence of chelated iron. Reaction mixtures containing PMNL, PMA, dG and Fe-EDTA were incubated at 37 degrees C, and the formation of 8OHdG was analysed with high-performance liquid chromatography and electrochemical detection. 8OHdG formation was detected at PMA concentrations of 2 nM or higher, and half-maximal 8OHdG formation was found at around 6 nM PMA. Stimulation of 500,000 cells with 10 nM PMA for 20 min resulted in a 500 to 1000-fold increase in 8OHdG formation as compared to unstimulated cells. The 8OHdG formation decreased after addition of hydroxyl radical scavengers (sodium benzoate, dimethylsulfoxide, and mannitol) and increased after addition of platelet-activating factor (PAF), an agent known to stimulate the generation of reactive oxygen metabolites in neutrophils. These results demonstrate that hydroxylation of dG to 8OHdG can be used to determine neutrophil-generated hydroxyl radicals in different experimental systems. Since the analysis of 8OHdG is rapid, sensitive and easy, this may have wide applications in inflammation and cancer research.

Antioxidant activity of carnosine, homocarnosine, and anserine present in muscle and brain.

Carnosine, homocarnosine, and anserine are present in high concentrations in the muscle and brain of many animals and humans. However, their exact function is not clear. The antioxidant activity of these compounds has been examined by testing their peroxyl radical-trapping ability at physiological concentrations. Carnosine, homocarnosine, anserine, and other histidine derivatives all showed antioxidant activity. All of these compounds showing peroxyl radical-trapping activity were also electrochemically active as reducing agents in cyclic voltammetric measurements. Furthermore, carnosine inhibited the oxidative hydroxylation of deoxyguanosine induced by ascorbic acid and copper ions. Other roles of carnosine, such as chelation of metal ions, quenching of singlet oxygen, and binding of hydroperoxides, are also discussed. The data suggest a role for these histidine-related compounds as endogenous antioxidants in brain and muscle.

Hydroxylation of deoxyguanosine at the C-8 position by mutagens and carcinogens

Hydroxylation of deoxyguanosine at the C-8 position by mutagens and carcinogens

Hydroxylation of deoxy guanosine at the C-8 position by polyphenols and aminophenols in the presence of hydrogen peroxide and ferric ion.

Various polyphenols and aminophenols were tested for reactivity with deoxyguanosine and DNA in the presence of hydrogen peroxide and ferric ion. Deoxyguanosine was efficiently hydroxylated at the C-8 position by these treatments. In the case of DNA, strand scission was observed in addition to the hydroxylation of guanine residues.

Hydroxylation of deoxyguanosine at the C-8 position by ascorbic acid and other reducing agents.

The C-8 position of deoxyguanosine (dGuo) was hydroxylated by ascorbic acid in the presence of oxygen (O2) in 0.1 M phosphate buffer (pH 6.8) at 37 degrees C. Addition of hydrogen peroxide (H2O2) remarkably enhanced this hydroxylation. The Udenfriend system [ascorbic acid, FeII, ethylenediaminetetraacetic acid (EDTA) and O2] was also effective for hydroxylation of dGuo in high yield. Guanine residues in DNA were also hydroxylated by ascorbic acid. Other reducing agents, such as hydroxylamine, hydrazine, dihydroxymaleic acid, sodium bisulfite and acetol, were also effective for the hydroxylation reaction, as were metal-EDTA complexes (FeII-, SnII-, TiIII-, CuI-EDTA). An OH radical seemed to be involved in this hydroxylation reaction in most of the above hydroxylating systems, but another reaction mechanism may also be involved, particularly when dGuo is hydroxylated by ascorbic acid alone or ascorbic acid plus H2O2. The possible biological significance of the hydroxylation of guanine residues in DNA in relation to mutagenesis and carcinogenesis is discussed.