Biochemical Investigations into the Mutagenic Potential of 8-Oxo-2′-deoxyguanosine Using Nucleotide Analogues

Implications of N7-hydrogen and C8-keto on the base pairing, mutagenic potential and repair of 8-oxo-2'-deoxy-adenosine: Investigation by nucleotide analogues

Oxidative lesions, such as 8-oxo-dG and 8-oxo-dA, are continuously generated from exposure to reactive oxygen species. While 8-oxo-dG has been extensively studied, 8-oxo-dA has not received as much attention until recently. Herein, we report the synthesis of duplex DNAs incorporating dA, 8-oxo-dA, 7-deaza-dA, 8-Br-dA, and 8-Br-7-deaza-dA, which have different substitutions at 7- and 8-position, for the investigation into the implications of N7-hydrogen and C8-keto on the base pairing preference, mutagenic potential and repair of 8-oxo-dA. Base pairing study suggested that the polar N7-hydrogen and C8-keto of 8-oxo-dA, rather than the syn-preference, might be essential for 8-oxo-dA to form a stable base pair with dG. Insertion and extension studies using KF-exo^- and human DNA polymerase β indicated that the efficient dGTP insertion opposite 8-oxo-dA and extension past 8-oxo-dA:dG are contingent upon not only the stable base pair with dG, but also the flexibility of the active site in polymerase. The N7-hydrogen in 8-oxo-dA or C7-hydrogen in 7-deaza-dA and 8-Br-7-deaza-dA was suggested to be important for the recognition by hOGG1, although the excision efficiencies of 7-deaza-dA and 8-Br-7-deaza-dA were much lower than 8-oxo-dA. This study provides an insight into the structure-function relationship of 8-oxo-dA by nucleotide analogues.

The importance of Ile716 toward the mutagenicity of 8-Oxo-2'-deoxyguanosine with Bacillus fragment DNA polymerase

8-oxo-2'-deoxyguanosine (OdG) is a prominent DNA lesion that can direct the incorporation of dCTP or dATP during replication. As the latter reaction can lead to mutation, the ratio of dCTP/dATP incorporation can significantly affect the mutagenic potential of OdG. Previous work with the A-family polymerase BF and seven analogues of OdG identified a major groove amino acid, Ile716, which likely influences the dCTP/dATP incorporation ratio opposite OdG. To further probe the importance of this amino acid, dCTP and dATP incorporations opposite the same seven analogues were tested with two BF mutants, I716M and I716A. Results from these studies support the presence of clashing interactions between Ile716 and the C8-oxygen and C2-amine during dCTP and dATP incorporations, respectively. Crystallographic analysis suggests that residue 716 alters the conformation of the template base prior to insertion into the active site, thereby affecting enzymatic efficiency. These results are also consistent with previous work with A-family polymerases, which indicate they have tight, rigid active sites that are sensitive to template perturbations.

Effects of 8-halo-7-deaza-2'-deoxyguanosine triphosphate on DNA synthesis by DNA polymerases and cell proliferation

8-OxodG (8-oxo-2'-deoxyguanosine) is representative of nucleoside damage and shows a genotoxicity. To significantly reveal the contributions of 7-NH and C8-oxygen to the mutagenic effect of 8-oxodG by DNA polymerases, we evaluated the effects of the 8-halo-7-deaza-dG (8-halogenated 7-deaza-2'-deoxyguanosine) derivatives by DNA polymerases. 8-Halo-7-deaza-dGTPs were poorly incorporated by both KF(exo(-)) and human DNA polymerase β opposite dC or dA into the template DNA. Furthermore, it was found that KF(exo(-)) was very sensitive to the introduction of the C8-halogen, while polymerase β can accommodate the C8-halogen resulting in an efficient dCTP insertion opposite the 8-halo-7-deaza-dG in the template DNA. These results indicate that strong hydrogen bonding between 7-NH in the 8-oxo-G nucleobase and 1-N in the adenine at the active site of the DNA polymerase is required for the mutagenic effects. Whereas, I-deaza-dGTP shows an antiproliferative effect for the HeLa cells, suggesting that it could become a candidate as a new antitumor agent.

Insights into the substrate specificity of the MutT pyrophosphohydrolase using structural analogues of 8-oxo-2'-deoxyguanosine nucleotide

The bacterial repair enzyme MutT hydrolyzes the damaged nucleotide OdGTP (the 5'-triphosphate derivative of 8-oxo-2'-deoxyguanosine; OdG), which is a known mutagen and has been linked to antibacterial action. Previous work has indicated important roles for the C8-oxygen, N7-hydrogen, and C2-exocyclic amine during OdGTP recognition by MutT. In order to gain a more nuanced understanding of the contribution of these three sites to the overall activity of MutT, we determined the reaction parameters for dGTP, OdGTP, and nine of their analogues using steady state kinetics. Our results indicate that overall high reaction efficiencies can be achieved despite altering any one of these sites. However, altering two or more sites leads to a significant decrease in efficiency. The data also suggest that, similar to another bacterial OdG repair enzyme, MutM, a specific carbonyl in the enzyme can not only promote activity by forming an active site hydrogen bond with the N7-hydrogen of OdGTP, but can also hinder activity through electrostatic repulsion with the N7-lone pair of dGTP.