DNA Sequence Context as a Determinant of the Quantity and Chemistry of Guanine Oxidation Produced by Hydroxyl Radicals and One-electron Oxidants

Yelena Margolin,Vladimir Shafirovich,Nicholas E Geacintov,Michael S Demott,Peter C Dedon

doi:10.1074/jbc.m806809200

Yelena Margolin, Vladimir Shafirovich + Show 3 more

Open Access

https://doi.org/10.1074/jbc.m806809200

Copy DOI

Abstract

DNA sequence context has emerged as a critical determinant of the location and quantity of nucleobase damage caused by many oxidizing agents. However, the complexity of nucleobase and 2-deoxyribose damage caused by strong oxidants such as ionizing radiation and the Fenton chemistry of Fe2+-EDTA/H2O2 poses a challenge to defining the location of nucleobase damage and the effects of sequence context on damage chemistry in DNA. To address this problem, we developed a gel-based method that allows quantification of nucleobase damage in oxidized DNA by exploiting Escherichia coli exonuclease III to remove fragments containing direct strand breaks and abasic sites. The rigor of the method was verified in studies of guanine oxidation by photooxidized riboflavin and nitrosoperoxycarbonate, for which different effects of sequence context have been demonstrated by other approaches (Margolin, Y., Cloutier, J. F., Shafirovich, V., Geacintov, N. E., and Dedon, P. C. (2006) Nat. Chem. Biol. 2, 365-366). Using duplex oligodeoxynucleotides containing all possible three-nucleotide sequence contexts for guanine, the method was used to assess the role of DNA sequence context in hydroxyl radical-induced guanine oxidation associated with gamma-radiation and Fe2+-EDTA/H2O2. The results revealed both differences and similarities for G oxidation by hydroxyl radicals and by one-electron oxidation by riboflavin-mediated photooxidation, which is consistent with the predominance of oxidation pathways for hydroxyl radicals other than one-electron oxidation to form guanine radical cations. Although the relative quantities of G oxidation produced by hydroxyl radicals were more weakly correlated with sequence-specific ionization potential than G oxidation produced by riboflavin, damage produced by both hydroxyl radical generators and riboflavin within two- and three-base runs of G showed biases in location that are consistent with a role for electron transfer in defining the location of the damage products. Furthermore, both gamma-radiation and Fe2+-EDTA/H2O2 showed relatively modest effects of sequence context on the proportions of different damage products sensitive to E. coli formamidopyrimidine DNA glycosylase and hot piperidine, although GT-containing sequence contexts displayed subtle biases in damage chemistry (formamidopyrimidine DNA glycosylase/piperidine ratio). Overall, the results are consistent with the known chemistry of guanine oxidation by hydroxyl radical and demonstrate that charge migration plays a relatively minor role in determining the location and chemistry of hydroxyl radical-mediated oxidative damage to guanine in DNA.

Highlights

With implications for mutagenesis and carcinogenesis, DNA damage caused by strong oxidizing agents such as ionizing radiation and Fenton chemistry (e.g. Fe2ϩ-EDTA, Cuϩ/H2O2) affects both the base and sugar moieties (1, 2)
The indirect pathway is mediated mainly by products of water radiolysis such as hydroxyl radicals that react with DNA by hydrogen atom abstraction from the 2-deoxyribose moiety to produce strand breaks and abasic sites, and by addition to nucleobases to form a variety of damage products (5–7)
The direct effect of ␥-radiation entails energy deposition that leads to ionization of the DNA nucleobases and the sugar-phosphate backbone, again leading to base damage and strand breaks (5). This complicated mixture of sugar and base damage produced by strong oxidants in DNA has hampered studies of the sequence selectivity of nucleobase oxidation, which is critical for defining the contributions of charge transfer to the spectrum of DNA lesions and for quantifying influences of local DNA structure on the final spectrum of damage products

Summary

The abbreviations used are

Gϩ. , guanine radical cation; NHE, normal hydrogen electrode; Ox, oxazolone, 2,2-diamino-4-[(2-deoxy-␤-D-erythro-pentofuranosyl)-amino]-5(2H)-oxazolone; CO31⁄7Ϫ, carbonate radical anion; 8-oxo-G, 7,8-dihydro-8-oxoguanine; Fpg, E. coli formamidopyrimidine DNA glycosylase; ExoIII, E. coli exonuclease III; Fapy-G, 2,6-diamino-5-formamido-4-hydroxypyrimidine; G, guanine; G(ϪH)1⁄7, guanine neutral radical; 4-OH-G1⁄7, 4-hydroxyguanine neutral radical; 8-OH-G1⁄7, 8-hydroxyguanine neutral radical; IP, ionization potential; NO21⁄7 , nitrogen dioxide radical; ONOOCO2Ϫ, nitrosoperoxycarbonate; ONOOϪ, peroxynitrite. Guanine radical cation; NHE, normal hydrogen electrode; Ox, oxazolone, 2,2-diamino-4-[(2-deoxy-␤-D-erythro-pentofuranosyl)-amino]-5(2H)-oxazolone; CO31⁄7Ϫ, carbonate radical anion; 8-oxo-G, 7,8-dihydro-8-oxoguanine; Fpg, E. coli formamidopyrimidine DNA glycosylase; ExoIII, E. coli exonuclease III; Fapy-G, 2,6-diamino-5-formamido-4-hydroxypyrimidine; G, guanine; G(ϪH)1⁄7, guanine neutral radical; 4-OH-G1⁄7, 4-hydroxyguanine neutral radical; 8-OH-G1⁄7, 8-hydroxyguanine neutral radical; IP, ionization potential; NO21⁄7 , nitrogen dioxide radical; ONOOCO2Ϫ, nitrosoperoxycarbonate; ONOOϪ, peroxynitrite. Ate (ONOOCO2Ϫ), for which dramatically different effects of sequence context have been demonstrated by other approaches (12, 28). Using ␥-radiation and Fe2ϩ-EDTA, the method was applied to test the hypothesis that hydroxyl radical-induced guanine oxidation would not be affected by sequence context because of the predominance of oxidation pathways other than one-electron oxidation to form Gϩ. Using ␥-radiation and Fe2ϩ-EDTA, the method was applied to test the hypothesis that hydroxyl radical-induced guanine oxidation would not be affected by sequence context because of the predominance of oxidation pathways other than one-electron oxidation to form Gϩ. radical cations

EXPERIMENTAL PROCEDURES

Digestion Method for Quantifying

DISCUSSION