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    Mapping Structurally Defined Guanine Oxidation Products along DNA Duplexes: Influence of Local Sequence Context and Endogenous Cytosine Methylation

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    DNA oxidation by reactive oxygen species is nonrandom, potentially leading to accumulation of nucleobase damage and mutations at specific sites within the genome. We now present the first quantitative data for sequence-dependent formation of structurally defined oxidative nucleobase adducts along <i>p53</i> gene-derived DNA duplexes using a novel isotope labeling-based approach. Our results reveal that local nucleobase sequence context differentially alters the yields of 2,2,4-triamino-2<i>H</i>-oxal-5-one (Z) and 8-oxo-7,8-dihydro-2′-deoxyguanosine (OG) in double stranded DNA. While both lesions are overproduced within endogenously methylated <sup>Me</sup>CG dinucleotides and at 5′ Gs in runs of several guanines, the formation of Z (but not OG) is strongly preferred at solvent-exposed guanine nucleobases at duplex ends. Targeted oxidation of <sup>Me</sup>CG sequences may be caused by a lowered ionization potential of guanine bases paired with <sup>Me</sup>C and the preferential intercalation of riboflavin photosensitizer adjacent to <sup>Me</sup>C:G base pairs. Importantly, some of the most frequently oxidized positions coincide with the known <i>p53</i> lung cancer mutational “hotspots” at codons 245 (GGC), 248 (CGG), and 158 (CGC) respectively, supporting a possible role of oxidative degradation of DNA in the initiation of lung cancer
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